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Bibliography on: Symbiosis

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ESP: PubMed Auto Bibliography 07 Jun 2025 at 01:58 Created: 

Symbiosis

Symbiosis refers to an interaction between two or more different organisms living in close physical association, typically to the advantage of both. Symbiotic relationships were once thought to be exceptional situations. Recent studies, however, have shown that every multicellular eukaryote exists in a tight symbiotic relationship with billions of microbes. The associated microbial ecosystems are referred to as microbiome and the combination of a multicellular organism and its microbiota has been described as a holobiont. It seems "we are all lichens now."

Created with PubMed® Query: ( symbiosis[tiab] OR symbiotic[tiab] ) NOT pmcbook NOT ispreviousversion

Citations The Papers (from PubMed®)

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RevDate: 2025-06-04
CmpDate: 2025-06-04

Nakayama T, Harada R, Yabuki A, et al (2025)

Marked Genome Reduction Driven by a Parasitic Lifestyle: Two Complete Genomes of Endosymbiotic Bacteria Possibly Hosted by a Dinoflagellate.

Microbes and environments, 40(2):.

Bacteria with endosymbiotic lifestyles often show marked genome reduction. While the shrinkage of genomes in intracellular symbionts of animals, including parasitic bacteria, has been extensively exami-ned, less is known about symbiotic bacteria associated with single-celled eukaryotes. We herein report the genomes of two novel gammaproteobacterial lineages, RS3 and XS4, identified as putative parasitic endosymbionts of the dinoflagellate Citharistes regius. Phylogenetic ana-lyses suggest that RS3 and XS4 belong to the family Fastidiosibacteraceae within the order Beggiatoales, forming independent lineages therein. The genomes of RS3 and XS4 are 529 and 436‍ ‍kbp in size, respectively, revealing marked reductions from related bacterial genomes. XS4, which has a very reduced genome with a low GC content, uses a different genetic code, in which UGA assigned tryptophan. The small genomes of RS3 and XS4 encode a limited number of proteins, retaining only approximately 20% of the predicted ancestral proteome. Metabolic reconstruction suggests that RS3 and XS4 are parasitic symbionts that are heavily dependent on their host for essential metabolites. Furthermore, we found that the ancestor of both genomes likely acquired an ADP:ATP antiporter gene via horizontal gene transfer, an event that may have enabled their evolution as energy parasites by facilitating the acquisition of ATP from their host. These results on novel bacteria with highly reduced genomes expand our understanding of the phylogenetic and genomic diversities of endosymbiotic bacteria in protists.

RevDate: 2025-06-04

Sands DZ, NB Finn (2025)

From Internet to Artificial Intelligence (Al) Bots: Symbiotic Evolutions of Digital Technologies and e-Patients.

Journal of participatory medicine, 17:e68911 pii:v17i1e68911.

This paper will view the rise of the e-patient, who is "equipped, enabled, empowered, and engaged" through the lens of the evolution of successive digital technology innovations, each building on its predecessors, creating new tools for patient empowerment. We begin with the dawn of the web and the proliferation of health websites and discuss the use of digital communication tools. We then discuss the adoption of electronic health records, which enabled the rise of patient portals. This digitization of health data, along with the rapid adoption of mobile internet access and the proliferation of health-related smartphone apps, in turn, provided a platform for patients to coproduce health care by contributing their own health data to their self-care and health care. The exchange of health information between patients and providers has also been facilitated by telehealth or telemedicine technology, which enables direct care delivery. The use of social networks in health, in use since the early days of the web, has expanded since COVID-19, when public health authorities worldwide, as well as patients, sought the use of social media channels to get connected and share information. Most recently, artificial intelligence and large language models have emerged with yet untapped potential to provide patients with the information that could improve their understanding of their conditions and treatment options. We conclude that innovations in digital health technology have symbiotically evolved with the ascendance of the e-patient, enabling improved communication, collaboration, and coordination between patients and clinicians and forging a health care system that is safer and more responsive to patient needs.

RevDate: 2025-06-04

Marzari T, Villette J, Roudaire T, et al (2025)

The short chitooligosaccharide CO4 inhibits chitin-triggered immunity in grapevine and promotes the infection by Botrytis cinerea but not Plasmopara viticola.

Journal of experimental botany pii:8156574 [Epub ahead of print].

Plants have developed strategies to detect different microorganisms and specifically modulate their immune responses. A primary recognition involves the perception of highly conserved molecular signatures, also known as microbe-associated molecular patterns (MAMPs). Among them, chitin, the main component of the fungal cell wall, is well known to be particularly active in triggering immunity in many plant species, including grapevine. While chitin is a well-known elicitor of plant defenses, other MAMPs such as short chitooligosaccharides (e.g. chitotetraose: CO4) and lipo-chitooligosaccharides (LCOs) have been described to promote symbiotic interactions and inhibit plant immunity in several plant species. Here, we analyzed the molecular signaling triggered by these MAMPs in grapevine focusing on two key immune responses: MAPKs phosphorylation and defense genes expression. Our results revealed that CO4 is the most active MAMP to inhibit some immune responses normally triggered by chitin. In addition, CO4 pre-treatment of grapevine leaves resulted in the repression of immune responses and increased susceptibility to the fungal pathogen Botrytis cinerea while showing no effect on Plasmopara viticola infection. These results suggest that grapevine can regulate its immune signaling pathways differently to either block or promote microbial colonization, depending on the MAMP perceived.

RevDate: 2025-06-04

Imes AM, Pavelsky MN, Badal K, et al (2025)

Euprymna berryi as a comparative model host for Vibrio fischeri light organ symbiosis.

bioRxiv : the preprint server for biology pii:2025.01.10.632448.

UNLABELLED: Functional studies of host-microbe interactions benefit from natural model systems that enable exploration of molecular mechanisms at the host-microbe interface. Bioluminescent Vibrio fischeri colonize the light organ of the Hawaiian bobtail squid, Euprymna scolopes , and this binary model has enabled advances in understanding host-microbe communication, colonization specificity, in vivo biofilms, intraspecific competition, and quorum sensing. The hummingbird bobtail squid, Euprymna berryi, can be generationally bred and maintained in lab settings and has had multiple genes deleted by CRISPR approaches. The prospect of expanding the utility of the light organ model system by producing multigenerational host lines led us to determine the extent to which the E. berryi light organ symbiosis parallels known processes in E. scolopes . However, the nature of the E. berryi light organ, including its microbial constituency and specificity for microbial partners, have not been examined. In this report, we isolate bacteria from E. berryi animals and tank water. Assays of bacterial behaviors required in the host, as well as host responses to bacterial colonization, illustrate largely parallel phenotypes in E. berryi and E. scolopes hatchlings. This study reveals E. berryi to be a valuable comparative model to complement studies in E. scolopes .

IMPORTANCE: Microbiome studies have been substantially advanced by model systems that enable functional interrogation of the roles of the partners and the molecular communication between those partners. The Euprymna scolopes-Vibrio fischeri system has contributed foundational knowledge, revealing key roles for bacterial quorum sensing broadly and in animal hosts, for bacteria in stimulating animal development, for bacterial motility in accessing host sites, and for in vivo biofilm formation in development and specificity of an animal's microbiome. Euprymna berryi is a second bobtail squid host, and one that has recently been shown to be robust to laboratory husbandry and amenable to gene knockout. This study identifies E. berryi as a strong symbiosis model host due to features that are conserved with those of E. scolopes , which will enable extension of functional studies in bobtail squid symbioses.

RevDate: 2025-06-04

Frew A (2025)

What does colonisation tell us? Revisiting the functional outcomes of root colonisation by arbuscular mycorrhizal fungi.

The New phytologist [Epub ahead of print].

RevDate: 2025-06-03
CmpDate: 2025-06-04

Nzepang DT, Cissoko M, Gully D, et al (2025)

Transcriptomic analysis reveals genetic factors underlying impaired symbiotic nitrogen fixation in lines derived from crosses between cultivated peanut (Arachis hypogaea L.) and its wild ancestors.

BMC genomics, 26(1):556.

BACKGROUND: Symbiotic nitrogen fixation (SNF) is a complex process regulated by numerous genes extensively studied in legumes that undergo intracellular infection, such as Lotus japonicus, Medicago truncatula, and Glycine max. However, the molecular and genetic mechanisms of SNF in legumes that rely on the intercellular infection pathway, such as peanut (Arachis hypogaea L.), remain poorly understood. In a previous study, we identified two chromosome segment substitution lines (CSSLs), 12CS_051 and 12CS_044, each contains a wild segment on homeologous regions of chromosomes A02 and B02 respectively, that are severely impaired in nitrogen fixation. In this study, we have compared the transcriptomes of those lines with that of their recurrent parent, Fleur11, in roots inoculated with the effective Bradyrhizobium vignae strain ISRA400 to identify candidate genes associated with the reduced nitrogen fixation observed in these CSSLs.

RESULTS: A comparative analysis of the transcriptome profiles of the CSSLs and Fleur11 revealed significant changes in the expression of genes involved in plant immune signaling and key symbiotic genes, such as NIN, EFD, FEN1 or SNF-related transporters. These results align with the phenotypic differences observed during the symbiotic process in the CSSLs. When focusing on each QTL region, we found that only the orthologs of the symbiotic gene FEN1, which is responsible for the failure in the enlargement of infected cells in L. japonicus, exhibited a lack of expression in the two CSSLs compared to Fleur11. FEN1 encodes a homocitrate synthase that is essential for the nitrogenase activity. We hypothesize that changes in the expression of FEN1 could affect the nitrogenase activity, potentially leading to the unfair SNF observed in these lines.

CONCLUSIONS: In this study, we analyzed the expression profiles of two ineffective nitrogen-fixing chromosome segment substitution lines and identified FEN1 as a suitable candidate gene involved in peanut symbiosis. This research provides valuable insights into understanding and improving SNF in peanut.

RevDate: 2025-06-03
CmpDate: 2025-06-03

Esser SP, Turzynski V, Plewka J, et al (2025)

Differential Expression of Core Metabolic Functions in Candidatus Altiarchaeum Inhabiting Distinct Subsurface Ecosystems.

Environmental microbiology reports, 17(3):e70096.

Candidatus Altiarchaea are widespread across aquatic subsurface ecosystems and possess a highly conserved core genome, yet adaptations of this core genome to different biotic and abiotic factors based on gene expression remain unknown. Here, we investigated the metatranscriptome of two Ca. Altiarchaeum populations that thrive in two substantially different subsurface ecosystems. In Crystal Geyser, a high-CO2 groundwater system in the USA, Ca. Altiarchaeum crystalense co-occurs with the symbiont Ca. Huberiarchaeum crystalense, while in the Muehlbacher sulfidic spring in Germany, an artesian spring high in sulfide concentration, Ca. A. hamiconexum is heavily infected with viruses. We here mapped metatranscriptome reads against their genomes to analyse the in situ expression profile of their core genomes. Out of 537 shared gene clusters, 331 were functionally annotated and 130 differed significantly in expression between the two sites. Main differences were related to genes involved in cell defence like CRISPR-Cas, virus defence, replication, transcription and energy and carbon metabolism. Our results demonstrate that altiarchaeal populations in the subsurface are likely adapted to their environment while influenced by other biological entities that tamper with their core metabolism. We consequently posit that viruses and symbiotic interactions can be major energy sinks for organisms in the deep biosphere.

RevDate: 2025-06-03

Sasabe J, Taniguchi S, Adachi K, et al (2025)

Mammalian Tolerance to Amino Acid Heterochirality.

Chembiochem : a European journal of chemical biology [Epub ahead of print].

Organisms use amino acids predominantly in l-configuration. On the other hand, a series of studies show that a variety of d-amino acids also occur in mammals and amino acid homochirality is not complete. Mammals de novo synthesize most amino acids with l-configuration, but serine and aspartate are converted from l- to d-configuration by endogenous enzymes. In addition to endogenous syntheses of d-amino acids, symbiotic bacteria in mammals chiral-convert amino acids, including alanine, glutamate, proline, and leucine in the intestine, creating a heterochiral inner environment. d-amino acids are distributed in distinctive patterns among organs and have physiological roles in the central nervous, endocrine, and immune systems. Mammals manage such diverse d-amino acids with catabolism and excretion into urine at individual levels. On the other hand, at cellular levels, enantio-selection mechanism to regulate chiral homeostasis of amino acids has remained unclear. In the protein synthesis, ribosome has a sophisticated system to eliminate d-amino acids, whereas non-ribosomal synthesis also utilizes d-amino acids. Furthermore, amino acid residues in proteins/peptides can be isomerized post-translationally through enzymatic or spontanelus processes. This manuscript overviews how chiral balance of free amino acids or residues in proteins is maintained in mammals at the individual and cellular levels.

RevDate: 2025-06-03

Paulenová E, Dobeš P, Melicher F, et al (2025)

The insight into the biology of five homologous lectins produced by the entomopathogenic bacterium and nematode symbiont Photorhabdus laumondii.

Glycobiology pii:8155770 [Epub ahead of print].

Photorhabdus laumondii is a well-known bacterium with a complex life cycle involving mutualism with nematodes of the genus Heterorhabditis and pathogenicity towards insect hosts. It provides an excellent model for studying the diverse roles of lectins, saccharide-binding proteins, in both symbiosis and pathogenicity. This study focuses on the seven-bladed β-propeller lectins of P. laumondii (PLLs), examining their biochemical properties (structure and saccharide specificity) and biological functions (gene expression, interactions with the nematode symbiont, and the host immune system response). Structural analyses revealed diverse oligomeric states among PLLs and a unique organisation of binding sites not described outside the PLL lectin family. Lectins exhibited high specificity for fucosylated and O-methylated saccharides with a significant avidity effect for multivalent ligands. Gene expression analysis across bacterial growth phases revealed that PLLs are predominantly expressed during the exponential phase. Interaction studies with the host immune system demonstrated that PLL5 uniquely induced melanisation in Galleria mellonella hemolymph. Furthermore, PLL2, PLL3, and PLL5 interfered with reactive oxygen species production in human blood cells, indicating their potential role in modulating host immune responses. Biofilm formation assays and binding studies with nematode life stages showed no significant involvement of PLLs in nematode colonization. Our findings highlight the primary role of PLLs in Photorhabdus pathogenicity rather than in symbiosis and offer valuable insight into the fascinating dynamics within the Photorhabdus-nematode-insect triparted system.

RevDate: 2025-06-03

Jiang Q, Jia L, Chen W, et al (2025)

Complementary foraging of roots and mycorrhizal fungi among nutrient patch types in four subtropical monospecific broadleaved tree plantations.

The New phytologist [Epub ahead of print].

Foraging in soil nutrient-rich patches is a key nutrient acquisition strategy for plants. However, how arbuscular mycorrhizal (AM) and ectomycorrhizal (EM) trees integrate root and mycorrhizal fungal responses in exploring different nutrient patches is poorly understood, especially in generally phosphorus-limited subtropical forests. We established five nutrient patch treatments (control; nitrogen addition; phosphorus addition; nitrogen + phosphorus addition; and organic residue addition) using ingrowth root bags in monoculture plantations of four subtropical tree species (two AM and two EM (Castanopsis)) to investigate the foraging responses of absorptive roots and mycorrhizal fungi. Compared to control patches, neither roots nor mycorrhizal fungi of AM and EM trees showed significant proliferative responses in nitrogen addition patches. In phosphorus addition and nitrogen + phosphorus addition patches, AM trees showed significant proliferation for mycorrhizal fungi only, while EM trees showed significant proliferation for roots only. In organic residue addition patches, however, AM trees showed significant proliferation only for roots, while EM trees showed significant proliferation only for mycorrhizal fungi. Our results highlight that foraging strategies of roots and mycorrhizal fungi are complementary among nutrient patch types and between AM and EM trees. Predicting belowground nutrient foraging strategies requires integrating information on mycorrhizal and nutrient patch types, including potential limiting nutrients.

RevDate: 2025-06-05

Qush A, Assaad N, Alkhayat FA, et al (2025)

Insects in agricultural greenhouses: a metagenomic analysis of microbes in Trialeurodes vaporariorum infesting tomato and cucumber crops.

Frontiers in plant science, 16:1581707.

INTRODUCTION: With the predicted 9-10 billion world population increase by 2050 and its accompanying need for sustainable food production, and with the harsh climate conditions challenging agriculture and food security in many countries world-wide, employing "horticultural protected cultivation practices" in farming for seasonal and off-seasonal crop production is on the rise, among which is the use of agricultural greenhouses. The importance of greenhouse farming has been, indeed, evident by the perceived increase in year-round crops production, curtail in production risks, upsurge in agricultural profits, outreaching food stability and security in many countries globally. Yet, and despite this acknowledged success of employing greenhouses in farming, many constraints, including the presence of insect pests, still chaperoned this practice over the years, significantly impacting crop quality and production.

METHODS: As such, we assessed in this study the status of "insect pests" in the greenhouse model by collecting insects from different greenhouse sectors grown with tomatoes and cucumbers and identified the collected insects using relevant identification keys. To further explore the pest paradigm in greenhouses, we then focused on particularly studying Trialeurodes vaporariorum (TRIAVA), a key insect species among the collected and identified insects in the studied greenhouse model and a significant pest with an impactful effect on many crops worldwide. To do so, we traced the abundance of TRIAVA in the tomato and cucumber grown greenhouse sectors over the period of the study, analyzed its metagenome and associated its abundance with crop yield.

RESULTS AND DISCUSSION: Our findings revealed TRIAVA hosted microbes with aptitudes to either serve as symbiotic microorganisms and protect TRIAVA against pathogens or to potentially cause damage to crops. This work provides additional insight into the insect pests paradigm in greenhouses, an upshot that could serve integrated insect pest management strategies in greenhouses for optimal agricultural practices.

RevDate: 2025-06-05
CmpDate: 2025-06-02

Guo HB, Zhao JC, Liu WY, et al (2025)

Microbiome analysis for artificially establishing the symbiotic relationship between Hebeloma hiemale and Quercus mongolica.

Scientific reports, 15(1):19273.

Ectomycorrhizae (ECM) play a critical role in enhancing plant growth and health. However, the influence of artificially established ectomycorrhizal symbioses on the structure and function of rhizosphere microbial communities remains inadequately understood. In this study, a symbiotic relationship between Hebeloma hiemale and Quercus mongolica was established to investigate the influence of ECM on soil microbial communities in the rhizosphere of the host plant. High-throughput sequencing revealed that H. hiemale inoculation altered the evenness of both the fungal and bacterial communities and reduced the diversity of the bacterial community relative to the blank control. In particular, several bacterial genera with an enhanced capacity for nutrient cycling, contaminant degradation, and host plant protection were enriched following H. hiemale inoculation. Shifts in fungal community structure suggest potential benefits for the host plant, including reduced cadmium uptake, enhanced mercury remediation, and increased protection against pathogens. Our results highlight the complex interactions between ECM and rhizosphere microbial communities to enable a better understanding of the importance of multi-species relationships in plant-microbe symbioses and their ecological implications.

RevDate: 2025-06-02
CmpDate: 2025-06-02

Wang ZY, Zhong YJ, Wang YF, et al (2025)

Ecological functions of plant-beneficial microbiomes and their application prospects in sustainable agriculture.

Ying yong sheng tai xue bao = The journal of applied ecology, 36(5):1553-1566.

Soil microbial communities form dynamic interaction networks with plants, which influence growth, development, stress tolerance, and ecological adaptability of plants. In recent years, the roles of beneficial micro-biomes, including plant growth-promoting rhizobacteria (PGPR), arbuscular mycorrhizal fungi (AMF), and plant-associated bacteriophages, in agricultural ecosystems have received increasing attention. Beneficial microorganisms can facilitate soil nutrient release, secrete plant hormones, and regulate signaling pathways, thereby establishing symbiotic relationships with plant for healthy host growth. They also play crucial roles in enhancing plant tolerance to salinity, drought, and pest-related stresses. Bacteriophages, as integral components of plant microbiomes, exhibit potential ecological functions, such as modulating host metabolism, boosting plant resistance, and maintaining microbial community balance. However, the mechanisms through which plant-associated microbiomes influence plant physiological traits remain less understood. The application of exogenous microorganisms in agriculture faces many challenges, such as competition from native microbiomes, environmental adaptability, and functional stabi-lity. We summarized the ecological functions of plant-beneficial microbiomes, including bacteriophages, in agricultural systems, highlighting their synergistic roles in soil health maintenance, nutrient cycling optimization, biodiversity conservation, and reducing reliance on chemical inputs. Furthermore, we discussed the complex mechanisms underlying plant-microbiome-environment interactions and proposed strategies for optimizing microbiome functions to promote sustainable development of agriculture and ensuring food security and ecological balance.

RevDate: 2025-06-05
CmpDate: 2025-06-02

Lemoine MM, Wöhner T, M Kaltenpoth (2025)

Microbial Community Dynamics in Natural Drosophila melanogaster Populations Across Seasons.

Environmental microbiology, 27(6):e70104.

Many insects benefit from gut microbes that contribute to digestion, detoxification, nutrient supplementation or defence. Although abiotic and biotic factors are known to shape insect-associated microbial communities, the seasonal dynamics and their potential impact on host fitness remain poorly studied. Here we investigated the temporal changes in bacterial and fungal communities associated with the model organism Drosophila melanogaster over 5 months. Our results reveal high inter-individual variation, but also consistent changes in microbial communities of three wild D. melanogaster populations from early spring to late summer. These changes were driven by specific indicator species, particularly Acetobacteraceae bacteria (Gluconobacter and Komagataeibacter) and Saccharomycetales yeasts (Pichia, Starmerella, Kregervanrija, Hanseniaspora, Saccharomycopsis, Priceomyces and Dipodascopsis). The temporal dynamics were not accompanied by differences in the total bacterial or fungal abundance, and alpha-diversity only changed across sampling months for the fungal but not the bacterial communities. While the changes in D. melanogaster-associated microbial communities are likely driven by the exposure to seasonally changing microbial environments and diets, they may have important impacts on host fitness. Elucidating the potential adaptive value of seasonally changing microbial communities will enhance our understanding of how symbiotic microbes may contribute to ecological niche shifts and geographic range expansions in insects.

RevDate: 2025-06-03

Han X, Zhou Y, Feng X, et al (2025)

Potassium uptake function of LbKT1 and LbSKOR from Lycium barbarum and their influence on the arbuscular mycorrhizal symbiosis.

Plant science : an international journal of experimental plant biology, 359:112587 pii:S0168-9452(25)00205-5 [Epub ahead of print].

Potassium participates in a variety of plant physiological processes and has great impact on plant growth and stress adaptation. The absorption of potassium by Plant is mediated by potassium channels and transporters, and the Shaker potassium channel gene family plays an important role in potassium uptake. Arbuscular mycorrhizal (AM) fungi form ubiquitous symbioses with plants and increase plants' potassium uptake. However, few studies have focused on the interaction of plant potassium channels from the Shaker gene family with AM fungi. In this study, the potassium uptake function of LbKT1 and LbSKOR (homologs of AKT1 and SKOR in Arabidopsis) from the Shaker gene family in Lycium barbarum was verified by the complementary assay using a yeast potassium uptake mutant. LbKT1 and LbSKOR were also overexpressed in tobacco to assess their influence on AM fungi under low and normal potassium conditions in a pot experiment. LbKT1 could rescue the phenotype of the yeast mutant, while LbSKOR could not. Overexpression of LbKT1 increased tobacco plant growth and potassium uptake and promoted the colonization of AM fungi. Meanwhile, overexpression of LbSKOR promoted potassium translocation from root to shoot and showed no obvious influence on the colonization of AM fungi. Our results suggested that the AM fungi could promote tobacco growth and potassium uptake, while the plant potassium status and the AM fungal colonization may form positive feedback in promoting tobacco potassium uptake and growth.

RevDate: 2025-06-04

Liu Z, Du Y, Yang R, et al (2025)

Response of extracellular polymeric substances in algal-bacterial granular sludge under salinity stress: Secretion behavior, structural properties, and protective roles.

Bioresource technology, 433:132754 pii:S0960-8524(25)00720-5 [Epub ahead of print].

The algal-bacterial granular sludge (ABGS) technology exhibits the advantages of low energy consumption and high shock load resistance. While ABGS regulates extracellular polymeric substances (EPS) secretion to cope with adverse conditions, the role of EPS in resisting salinity stress remains uncertain. This study investigated the response ofEPS in ABGS to salinity stress (0-5 %) by examining secretion behavior, structural properties, and protective roles. The results showed that high salinity (≥3%) led to changes in the components and content of EPS. Additionally, analysis of the adhesion in EPS indicated that the frequency of tightly bound EPS (TB-EPS) decreased sharply from -10 Hz (0 %) to -45 Hz (1 %). According to the extended Derjaguin-Landau-Verwey-Overbeek theory and the rheological properties, TB-EPS significantly influences sludge flocculation and stability at low salinity. This study provided a scientific foundation for revealing the role mechanism of EPS in ABGS for saline wastewater treatment.

RevDate: 2025-06-02
CmpDate: 2025-06-02

Yamanouchi K, Nagai T, Tsujiguchi T, et al (2025)

Environmentally derived Balamuthia mandrillaris contains endosymbiotic bacteria.

Parasitology research, 124(6):57.

Balamuthia mandrillaris is an environmentally derived, free-living amoeba that causes fatal meningoencephalitis. We previously isolated B. mandrillaris from soil in the Aomori Prefecture and attempted to culture the cell-free amoeba using liquid medium; however, this was difficult to achieve because of contamination of the medium with endogenous bacteria. The aim of this study was to determine the presence of endogenous bacteria in environmentally derived B. mandrillaris and identify bacteria. Two new environmentally derived B. mandrillaris strains were isolated from soil samples collected throughout Japan. Environmentally derived B. mandrillaris was cultured under nutrient-free conditions for 60 days, and the induced cysts contained large amounts of viable bacteria. The sequence of the endophytic bacteria revealed that the genus Chitinophaga was common between the two strains of B. mandrillaris. The opportunistic pathogens Inquilinus and Brevundimonas were also detected. All of these bacteria were pigment-producing species. Bacterial pigment production helps protect organisms from extremes of heat and cold, increases the virulence of pathogenic strains, and protects organisms from protein and DNA damage caused by UV light and ionizing radiation. This suggests that B. mandrillaris preserving bacteria in a viable state for a long time under severe conditions with no nutrition may be the ability of the bacteria to produce pigments.

RevDate: 2025-06-02

Pfister CA, Berlinghof J, Bogan M, et al (2025)

Evolutionary history and association with seaweeds shape the genomes and metabolisms of marine bacteria.

mSphere [Epub ahead of print].

UNLABELLED: Seaweeds harbor a rich diversity of bacteria, providing them with metabolic resources and a surface for attachment and biofilm development. The host's unique environment potentially shapes the bacterial genomes and promotes adaptations for a symbiotic lifestyle. To investigate whether the genomes of seaweed-associated bacteria are genetically and metabolically distinct from their close free-living relatives in seawater, we compared both the seaweed-associated and free-living counterparts of 72 bacterial genera across 16 seaweed hosts using whole-genome sequences or high-quality metagenome-assembled genomes. While taxonomic affiliation strongly influenced genome characteristics such as GC content, gene number, and size, host association had a lower effect overall. A reduced genome size was suggested only in Nereocystis luetkeana-associated microbes, while only Ascophyllum nodosum-associated bacteria had an increased GC content. Metabolic adaptations were indicated from the genomes of seaweed-associated bacteria, including enriched pathways for B vitamin production, complex carbohydrate utilization, and amino acid biosynthesis. In particular, Flavobacteriia showed the most pronounced differences between host-associated and free-living strains. We further hypothesized that bacteria associated with seaweed might have evolved to complement their host's metabolism and tested this inference by analyzing the genomes of both the seaweed Ectocarpus subulatus and its 28 bacterial associates but found no evidence for such complementarity. Our analyses of 72 paired bacterial genomes highlighted significant metabolic differences in seaweed-associated strains with implications for carbon, nitrogen, and sulfur cycling in the coastal ocean.

IMPORTANCE: We hypothesized that the unique environment of seaweeds in coastal oceans shapes bacterial genomes and promotes a symbiotic lifestyle. We compared the genomes of bacteria isolated from seaweed with bacteria from the same genus found free-living in seawater. For genome features that included the number of genes, the size of the genome, and the GC content, taxonomy was of greater importance than bacterial lifestyle. When we compared metabolic abilities, we again found a strong effect of taxonomy in determining metabolism. Although several metabolic pathways differed between free-living and host-associated bacteria, this was especially prominent for Flavobacteriia in the phylum Bacteroidota. Notably, bacteria living on seaweeds had an increased occurrence of genes for B vitamin synthesis, complex carbohydrate use, and nitrogen uptake, indicating that bacterial genomes reflect both their evolutionary history and the current environment they inhabit.

RevDate: 2025-06-03

Yamato M, Ohmae M, Orihara T, et al (2025)

Molecular phylogeny, morphology, mycorrhizal symbiosis, and putative distribution of the arbuscular mycorrhizal fungus Epigeocarpum japonicum (Glomeraceae).

Mycoscience, 65(6):270-277.

We collected in Japan five sporocarpic specimens morphologically identical to those of Epigeocarpum japonicum, a recently described Glomeromycota species. Although 18S-ITS-28S nuc rDNA sequences obtained from these sporocarps showed high sequence variability, phylogenetic analyses based on 18S-ITS-28S, the largest subunit of the RNA polymerase II (rpb1) gene, and concatenated sequences of the two loci convincingly demonstrated the identity of these sporocarps to E. japonicum. Importantly, the 18S-ITS-28S+rpb1 analyses highlighted the key role of rpb1 sequences in reconstructing the phylogenies of Glomeromycota taxa with strongly divergent rDNA sequences. Upon inoculation with sporocarpic spores, E. japonicum formed mycorrhiza with arbuscules and vesicles, which was not confirmed in the original description of the species. Comparisons of E. japonicum 18S sequences with Glomeromycota DNA sequences available in a public database indicated that E. japonicum is a cosmopolitan species and is mainly associated with plants in natural habitats such as grasslands, shrublands, and forests. Phylogenetic analyses also confirmed the autonomy of E. crypticum, another known species of the genus Epigeocarpum whose sporocarps were originally found in Brazil.

RevDate: 2025-06-04
CmpDate: 2025-06-01

Yue X, Yang J, Qi J, et al (2025)

Loss of Pathogenicity and Evidence of Horizontal Gene Transfer in Colletotrichum gloeosporioides From a Medicinal Plant.

Molecular plant pathology, 26(6):e70098.

Colletotrichum gloeosporioides is a major agricultural pathogen of crops that has also been identified as an endophyte of the medicinal plant Huperzia serrata. Both H. serrata and C. gloeosporioides produce huperzine A, a potential treatment for Alzheimer's disease. In this study, a nonpathogenic C. gloeosporioides strain (NWUHS001) was isolated and its genome sequenced. Gene structure prediction identified 15,413 protein-coding genes and 879 noncoding RNAs. Through PHI-base database prediction, we found that NWUHS001 lacks two key pathogenicity genes CgDN3 and cap20, which may be the cause of its nonpathogenicity. Comparative genomic analysis showed that the number of genes encoding pectin lyase B (pelB), pectin lyase (pnl) and polygalacturonase (pg) in NWUHS001 was significantly lower than that in pathogenic strains during the expansion of mycelium into host tissues. This caused slow growth and incapability to penetrate host cells. In contrast, in NWUHS001, genes involved in carbon acquisition such as ribose and amino sugar metabolic pathways were enriched, indicating active metabolite exchange with the host. In addition, by comparing the genome of NWUHS001 with that of the host H. serrata, we found that polyketosynthetase (pksIII), a key gene in the host huperzine A biosynthetic pathway, may possibly have been acquired from the fungus by horizontal gene transfer (HGT). This study explained the possible genetic evolution mechanism of C. gloeosporioides from pathogenicity to nonpathogenicity, which is of value for studying the interaction between microorganisms and plants. It also provided clues to the genetic evolution of the biosynthetic pathway of huperzine A.

RevDate: 2025-06-03

Bouwman T, Higa L, Lee C, et al (2025)

Biochemical and molecular characterization of fungal isolates from California annual grassland soil.

Biotechnology for biofuels and bioproducts, 18(1):56.

Fungi play a pivotal role in ecosystem functionality, driving processes such as decomposition, nutrient cycling, and symbiotic interactions. Their wide enzymatic strategies enable the breakdown of complex organic materials and the valorization of organic waste streams, providing sustainable pathways for bioproduct development. Fungi also exhibit significant potential in industrial applications, particularly in biofuel and nutraceutical production, owing to their high lipid content and adaptability to diverse feedstocks. Genera such as Aspergillus, Mortierella, and Linnemannia have demonstrated exceptional lipid production capabilities and unique fatty acid profiles, including high yields of nutraceuticals like arachidonic acid (ARA) and oleic acid. This study explored uncharacterized fungal strains isolated from California grassland soils, analyzing their phylogeny, morphology, growth rates, lipid content, and fatty acid profiles. Results revealed notable genetic and physiological diversity among the isolates, with Mortierella strains emerging as the most promising for industrial applications due to their superior lipid content and productivity of ARA and oleic acid. Confocal microscopy confirmed consistent lipid droplet morphology, while phylogenetic analysis uncovered novel species-level diversity. Key strains were identified for biofuel and nutraceutical production, highlighting their industrial potential. These findings underscore the versatility of fungi as biotechnological tools and provide a foundation for further exploration and utilization of these promising strains in industrial processes.

RevDate: 2025-06-03
CmpDate: 2025-06-01

Alizadeh Z, Heidari P, HR Asghari (2025)

Exploring the influence of symbiosis between arbuscular mycorrhizal fungi and beans on potassium uptake and the activity of AKT and HKT genes.

Scientific reports, 15(1):19169.

In plants, potassium (K[+]) serves multiple functions, despite being scarce due to strong soil adsorption. This study examined how the presence of arbuscular mycorrhiza fungi (AMF) like Rhizophagus irregularis and Funneliformis mosseae influenced the absorption and transport of K[+] in bean roots through symbiotic interactions. In a symbiotic relationship, AMF had the potential to enhance potassium absorption and storage in various tissues of bean seedlings. Under symbiotic conditions, the concentration of potassium in stem tissues was observed to increase almost four times more than control conditions. The genome of beans was shown to contain a total of nineteen PvAKT genes and two PvHKT genes. Based on phylogeny analysis, PvAKT family members and their corresponding orthologs were categorized into four distinct groups. Subfamily 3 of the PvAKT phylogeny tree exhibited distinct variations from other subfamilies in terms of gene structure, conserved domains, and potential phosphorylation sites. The presence of cis-regulatory element related to ABA responsiveness in the upstream region led to the division of PvAKT and PvHKT genes into two specific groups. Gene expression analysis disclosed that PvAKT and PvHKT genes are induced by AMF and have tissue specific expression. PvAKT6 and PvAKT11 genes and both PvHKT genes showed differential expression in root and shoot tissues, while PvAKT3 gene increased expression in both root and shoot tissues. The results suggest that AMF had a significant impact on increasing the solubility of K[+] and ultimately enhancing the function of K[+] transporters.

RevDate: 2025-06-03
CmpDate: 2025-06-01

Kong L, Feng Y, Zheng R, et al (2025)

Interspecies hydrogen transfer between cyanobacteria and symbiotic bacteria drives nitrogen loss.

Nature communications, 16(1):5078.

The trace concentration of H2 in most ecosystems after the Earth's oxidation has long caused the neglect of hydrogenotrophic denitrification for nitrogen loss. Here, we find that the interspecies hydrogen transfer between cyanobacteria and symbiotic bacteria within cyanobacterial aggregates is an undiscovered pathway for nitrogen loss. Cyanobacteria in aggregates can actively generate H2 under the diel cycle as an electron donor for neighboring hydrogenotrophic denitrifiers. The hydrogenotrophic denitrification in engineered cyanobacterial aggregates accounts for a nitrogen removal rate of 3.47 ± 0.42 mmol l[-1] day[-1]. This value is nearly 50% of the heterotrophic denitrification rate, which far exceeds the general concept of the trace role. We find that H2-evolving cyanobacteria and hydrogenotrophic denitrifiers coexist in 84% of the 63 globally distributed cyanobacterial aggregates, where bloom colonies and phototrophic mats from hot springs are identified as potential hotspots. We suggest that interspecies hydrogen transfer within cyanobacterial aggregates is possibly responsible for the excessive nitrogen loss rate during cyanobacterial blooms where cyanobacterial aggregates persist.

RevDate: 2025-05-31

Ding H, Zhu X, Liu J, et al (2025)

Plant endophytic fungal polysaccharides and their activities: A review.

International journal of biological macromolecules pii:S0141-8130(25)05302-4 [Epub ahead of print].

Endophytic fungi, essential constituents of plant microecosystems, have attracted considerable scientific interest due to their remarkable biodiversity, ecological adaptability, and capacity to synthesize a wide range of bioactive metabolites. Among these, polysaccharides produced by endophytic fungi represent a promising yet insufficiently investigated class of macromolecules with significant pharmacological and biotechnological applications. However, research on these polysaccharides remains constrained by limited exploration. This review systematically consolidates current advances in the classification, extraction, purification, structural elucidation, and biological functions of endophytic fungal polysaccharides (EFPs), while also examining their interactions with host plants. The potential of polysaccharide-producing endophytic fungi remains largely underexplored. Furthermore, inherent polysaccharide complexity, combined with technical limitations, has confined most studies to extracellular polysaccharides, leaving comprehensive structural analyses scarce. EFPs demonstrate antioxidant, antibacterial, immunomodulatory, and antitumor activities, and contribute substantially to the symbiotic dynamics between fungi and host plants, yet systematic activity profiling is insufficient. This review proposes establishing a targeted resource development framework to enhance the diversity of polysaccharide compounds and advocates for the integration of conventional and advanced methodologies to advance pharmacological investigations and functional analyses of EFPs, thereby offering strategic insights for future applications and facilitating deeper exploration and utilization.

RevDate: 2025-05-31

Ou Z, Wang Z, Duan C, et al (2025)

Simultaneously disinfection of amoebae, endosymbiotic bacteria, and resistance genes using a novel two-electron water oxidation strategy.

Water research, 284:123894 pii:S0043-1354(25)00802-4 [Epub ahead of print].

Amoebae, which serve as important vectors for various pathogenic bacteria, are ubiquitous in natural and artificial water systems. Their robust survival capabilities and protective characteristics render conventional disinfection methods largely ineffective. Moreover, amoeba cells provide an ideal environment for the replication and transfer of antibiotic resistance genes, posing a significant threat to human health and safety. In this study, an in-situ activation system for electrocatalytic water oxidation was developed. This system effectively inactivates amoeba spores and their intracellular symbiotic bacteria while simultaneously reducing the abundance of resistance genes through the generation of hydroxyl radicals (•OH) and carbonate free radicals (•CO3[-]). The results demonstrated a 99.9 % inactivation rate for amoeba spores and a 99.999 % inactivation rate for intracellular bacteria. In addition, the prevalence of resistant genes in bacteria within amoebae, specifically including sul1 (sulfonamide resistance), tetA (tetracycline resistance), blaFOX (cefoxitin resistance), arsB (arsenic resistance), czcA (cadmium resistance), and copA (copper resistance), was significantly reduced by approximately 16 %-62.6 %. Therefore, this study introduces a new technology capable of simultaneously treating amoeba spores, intracellular bacteria, and resistance genes, which holds significant importance for reducing the spread of resistant genes and enhancing public health safety.

RevDate: 2025-05-31

Xia Z, Ng HY, S Bae (2025)

Synergistic microalgal-bacterial interactions enhance nitrogen removal in membrane-aerated biofilm photoreactors treating aquaculture wastewater under salt stress: Insights from metagenomic analysis.

Water research, 283:123878 pii:S0043-1354(25)00786-9 [Epub ahead of print].

This study investigates the membrane-aerated biofilm photoreactor (MABPR) for treating aquaculture effluents with low C/N ratio and elevated salinity (0.5%-3.2%). The MABPR integrated biofilm reactors with microalgal-bacterial consortia, achieving superior total inorganic nitrogen (TIN) removal by leveraging counter-diffusional biofilm properties, bubbleless aeration, and enhanced microalgal productivity. The system consistently outperformed conventional reactors, achieving 84.7 ± 1.9% TIN removal at 3.2% salinity with TIN removal flux increasing from 0.82 ± 0.04 to 1.22 ± 0.07 g/m[2] d. The MABPR promoted microalgal proliferation (Chl-a/VSS: 8.08-15.04 mg/g) and higher biomass productivity (1.83 g/m[2] d) compared to SBBPR and MABR. Elevated salinity stimulated extracellular polymeric substance (EPS) production, reinforcing biofilm stability and microbial resilience. The MABPR demonstrated 22%-65% higher nitrogen removal efficiency than controls at the highest salinity. Canonical nitrification-denitrification remained the primary nitrogen removal pathway, with short-cut nitrification-denitrification contributing under salt stress. Metagenomic analysis revealed bidirectional adaptation between microalgae and bacteria, with enriched nitrogen assimilation (GS/GOGAT pathway) compensating for bacterial deficits. Microalgae facilitated pollutant removal through ammonia uptake and dissolved organic matter release, supporting denitrification. At 3.2% salinity, Nitrosomonas and Nitrobacter abundance increased by 42.6% and 35.8%, while denitrifiers Denitromonas and Hoeflea dominated, comprising 59.4% and 35.9% of the population. The MABPR further promoted the synthesis of growth cofactors (vitamins, phytohormones), enhancing microalgal productivity and stress resilience. These synergistic microalgal-bacterial interactions supported pollutant removal, showcasing the MABPR as a robust, sustainable solution for aquaculture wastewater treatment and resource recovery under salt stress.

RevDate: 2025-05-30

Moreira GRM, De Lima Júnior JM, Nomura CS, et al (2025)

Enhancing coral photosynthesis: The power of manganese-alginate gels.

Journal of trace elements in medicine and biology : organ of the Society for Minerals and Trace Elements (GMS), 89:127675 pii:S0946-672X(25)00088-4 [Epub ahead of print].

INTRODUCTION: Scleractinian corals rely on symbiosis with Symbiodiniaceae, a family of marine dinoflagellates, for photosynthetic products, which sustains their growth in nutrient-poor environments. Manganese (Mn) is a critical element for photosynthesis as an essential cofactor for the oxygen-evolving complex of the photosynthetic machinery. Also, Mn is an essential metal involved in antioxidant mechanisms that maintain normal cellular function in heat stressed corals.

OBJECTIVES: This study aims to investigate the effects of different Mn species on photosynthetic efficiency in the coral Stylophora pistillata under thermal stress. A Mn-alginate device for controlled Mn supplementation was developed for this purpose.

METHODS: Coral nubbins were exposed to the following Mn species: manganese(II) chloride (MnCl₂), manganese(II) ethylenediamine-N,N'-disuccinate (MnEDDS), manganese(II) desferrioxamine (MnDFO), and manganese(III) citrate (MnCIT). Photosynthetic parameters were measured using fluorometry. Mn-alginate gel dishes were prepared for controlled release, and their impacts on coral health indicators were evaluated at 26 °C and 31 °C, including photosynthetic efficiency, oxygen production, and symbiont density.

RESULTS: Free Mn(II) (MnCl2) and MnEDDS significantly enhanced photosynthetic efficiency. Mn-alginate effectively delivered Mn in controlled bursts. Under thermal stress, Mn supplementation improved photosynthetic activity and favored symbiont density. Mn-alginate dishes were stable in seawater and biocompatible, releasing Mn optimally at elevated temperatures.

CONCLUSION: Mn-alginate gel dishes are an efficient and safe method for improving coral photosynthesis and mitigating thermal stress impacts, supporting reef conservation efforts in a changing climate.

RevDate: 2025-06-02

Martín-Cardoso H, Castillo L, Busturia I, et al (2025)

Arbuscular Mycorrhizal Fungi Increase Blast Resistance and Grain Yield in Japonica Rice Cultivars in Flooded Fields.

Rice (New York, N.Y.), 18(1):47.

Arbuscular mycorrhizal (AM) fungi establish symbiotic associations with a wide range of plant species. Root colonization by AM fungi improves the uptake of mineral nutrients in the host plant, mainly phosphorus, in exchange for photosynthetically fixed carbon. Rice is one of the most important cereal crops in the world that is cultivated in diverse ecosystems, mainly in flooded fields. Although rice is a host for AM fungi, flooding depresses colonization of rice roots by AM fungi. However, once fungal penetration into the rice root has occurred, the functional capacities of the AM fungus are not affected by flooding. In this study, we investigated mycorrhizal responsiveness in a panel of temperate japonica rice varieties in low fertility soil collected from rice fields. We show that inoculation with an AM fungus, either Rhizophagus irregularis or Funneliformis mosseae, stimulates seedling growth, improves Pi nutrition and enhances resistance to infection by the fungus Magnaporthe oryzae in aerobically grown rice plants in low fertility soil. The fungus M. oryzae is the causal agent of the rice blast disease, one of the most devastating diseases in cultivated rice worldwide. Field trials were conducted in flooded paddy fields of eastern Spain (mediterranean region) in 2023 and 2024. Three elite rice varieties were inoculated with R. irregularis and grown in nurseries under aerobic conditions during early vegetative stage. The AM-inoculated seedlings were then transplanted to flooded fields. We show that inoculation with R. irregularis increases grain yield and blast resistance, namely leaf blast, neck blast, node blast and panicle blast, in flooded field conditions. Although all the japonica rice varieties here examined benefited from the AM symbiosis, its effects varied depending on the rice variety and the geographical location. These findings demonstrated that the application of AM fungi in nurseries may be integrated with conventional rice cultivation systems in paddy fields for the development of sustainable rice production systems less dependent on chemical fertilizers and pesticides.

RevDate: 2025-06-01

Sarti G, Traini C, Magni G, et al (2025)

Chronic administration of prebiotics and probiotics prevent pathophysiological hallmarks of Alzheimer's disease in the cortex of APP/PS1 mice.

Frontiers in pharmacology, 16:1596469.

INTRODUCTION: Dysbiosis is a characteristic of patients with Alzheimer's disease (AD). The disbalance between Gram-negative and Gram-positive bacteria causes increased production of beta-amyloid (Aβ) in the gut, which can contribute to brain accumulation of Aβ. Recovering microbiota composition with symbiotic administration of prebiotics and probiotics may be a strategy to prevent or reduce AD symptomathology. The aim of this research was to study whether chronic administration of pre- and probiotics modifies the histopathological signs of neurodegeneration in the cortex of APP/PS1 mice, a transgenic mouse model of AD. We focused on neuritic plaques deposition, neuronal degeneration and glia activation.

METHODS: Transgenic (TG) mice and Wild type (WT) littermates were fed daily with a diet supplemented with prebiotics (a multi-extract of fibers and plant complexes, containing inulin/fruit-oligosaccharides) and probiotics (a 50%-50% mixture of Lactobacillus rhamnosus and Lactobacillus paracasei). The treatment started at 2 months of age and lasted for 6 months. Controls were WT and TG mice fed with a standard diet. All groups were evaluated qualitatively and quantitatively by immunofluorescence, confocal microscopy and digital imaging. Cortical sections were immunostained for neuritic plaques, neurons, astrocytes, microglia, and inflammatory proteins. Qualitative and quantitative analyses were carried out by immunofluorescence, confocal microscopy and digital imaging with ImageJ software.

RESULTS: Quantitative analyses in TG mice demonstrated intense Aβ load and accumulation of neurofilament heavy polypeptide (NHP) in neuritic plaques, neuronal degeneration, shrinkage of the cortex, increase of GFAP expression, and microglia and astrocytes activation. All these effects were mainly evident in cortical Layer 5. The symbiotic treatment with pre- and probiotics decreased Aβ deposition and neuritic plaques in the frontoparietal cortex. In addition, the treatment decreased the degeneration of neurons, the cortical shrinkage, increased GFAP expression, and modified microglia phenomic, decreasing significantly microglia activation. The abovementioned effects of the treatment were mostly evident in cortical Layer 5.

DISCUSSION: These data confirm that prolonged dietary regimen enriched with pre- and probiotics counteracts many of the histopathological hallmarks of AD, and poses the bases for a simple, affordable treatment that may help prevent AD.

RevDate: 2025-06-01

Düşen S, Kaska Y, Yilmaz M, et al (2025)

Endoparasites and epibionts of loggerhead and green sea turtles from the eastern Mediterranean, Turkey: A detailed assessment.

Helminthologia, 62(1):40-49.

Two species of sea turtles, the loggerhead (Caretta caretta) and the green turtle (Chelonia mydas), use Turkey's Mediterranean and rarely Aegean Sea coasts for nesting and foraging. The injured sea turtles are regularly transferred for treatment to the Sea Turtle Research, Rescue and Rehabilitation Center (DEKAMER) Muğla Ortaca-Dalyan (Turkey) from the different coasts of the these two seasthese include Çanakkale, Balıkesir, İzmir and Aydın (Aegean Sea); Antalya and Mersin (Mediterranean Sea) and also Muğla (it has two coasts both Aegean Sea and Mediterranean Sea). In this study, both internal and external parasites and epibiont species of turtles that died during treatment were examined. This is the first detailed parasitological and epibiont study on these sea turtles in the Turkish coast. Twenty-two adult Caretta caretta and twelve green turtles were examined and these symbiotic groups were recorded: endoparasitic digeneans and nematodes, and epibiotic annelids and cirripeds (barnacles). The observed three digenean species (Pyelosomum renicapite, Learedius learedi and Deuterobaris proteus) are recorded in Turkey for the first time. Also, Ch. mydas and C. caretta represent new host records for these digenean species in Turkey. Ch. mydas represents a new host record for two cirriped species (Chelonibia testudinaria and Lepas hillii) from Turkey and C. caretta also represent a new host record for Ozobranchus margoi from Turkey. Based on the available literature, the implications of these symbionts on sea turtle health are discussed, highlighting the importance of recording parasitic data of sea turtles. The study of internal and external parasites is very important, especially for the treatment of sea turtles under rehabilitation.

RevDate: 2025-05-30
CmpDate: 2025-05-30

Ding Q, Zhou Z, Cui L, et al (2025)

Study on the treatment of livestock and poultry wastewater using algae-bacteria symbiotic system: effect of inoculation proportion and performance.

Environmental technology, 46(14):2597-2614.

In order to solve the problems of poor tolerance of traditional algal-bacterial symbiosis system to high ammonia wastewater and biomass recovery, a new symbiosis system combining biological agents of nitrifying bacteria and ordinary Chlorella vulgaris was proposed. The results showed that adjusting the volume ratio of algae and bacteria had an effect on the wastewater treatment performance, microalgae growth and flocculation effect. At the optimal algal-bacterial volume ratio of 1:3, the TN, NH4+-N and COD removal rates were 50%, 70%and 83%, respectively. The high concentration of ammonia nitrogen would have some inhibitory effect on microalgal photosynthesis, but the appropriate inoculation ratio could alleviate this pressure and improve the growth rate of microalgae. Under the optimal inoculation ratio, the PN and PS contents of extracellular polymers were 125.16 and 73 mg/L, respectively, which induced a stronger protective mechanism and enhanced the synergistic effect between algae-bacteria. In addition, the flocculation efficiency of the algal-bacterial system increased from 15% to 30% with the decrease of the initial inoculum of microalgae. The results provided a theoretical basis for the construction of an efficient algal-bacterial symbiosis system for the treatment of livestock and poultry wastewater as well as the efficient flocculation of the algal-bacterial system.

RevDate: 2025-05-30

Sun B, Liu P, Wang P, et al (2025)

Efficient Construction of Heterogeneous Oxides as Robust Bifunctional Electrocatalysts for Zinc-Air Batteries.

Small (Weinheim an der Bergstrasse, Germany) [Epub ahead of print].

Metal-air batteries (MABs) have attracted considerable attention. However, the sluggish oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) of air cathode is severe which has obstructed the more extensively application. Here, this study proposes a facile method to obtain heterogeneous oxides catalyst for enhancing the oxygen electrode catalysis where multiple nanosize Co3O4, Mn3O4 and MnCo2O4 (CMMCO) are symbiotic. In this case, the concomitant mono-metal oxide can contribute to atomic ratio modulation effect on MnCo2O4 spinel such as Mn[2+] to Mn[3+],Co[3+] to Co[2+], resulting in Mn high-spin state transformation into low-spin state and oxygen vacancies, further optimizing the adsorption of intermediates. Obviously, built-in electric field at heterojunction interface dramatically facilitates electron transfer. Also, band-gap change determined by orbital overlap indicates the affinity with reactant. For the resulting CMMCO catalyst, an excellent half-wave potential of E1/2 = 0.82 V for the ORR and low polarization potential (360 mV) for OER at 10 mA cm[-2] are achieved. Based on CMMCO cathodes, the assembled zinc air batteries demonstrate an impressive peak power density of 179 mW cm[-2] and cycling stability. The successful combination between heterogeneous interface regulation and efficient ORR/OER catalysis may provide a pivotal guideline for metal air batteries investigation with low-cost bifunctional catalyst.

RevDate: 2025-05-30

Choi J, Palanichamy P, Tanaka H, et al (2025)

Accelerated pseudogenization in the ancient endosymbionts of giant scale insects.

Molecular biology and evolution pii:8153089 [Epub ahead of print].

Symbiotic microorganisms are subject to a complex interplay of environmental and population-genetic pressures that drive their gene loss. Despite the widely held perception that ancient symbionts have stable genomes, even tiny genomes experience ongoing pseudogenization. Whether these tiny genomes also experience bursts of rapid gene loss is, however, less understood. Giant scale insects (Monophlebidae) feed on plant sap and rely on the symbiotic bacterium Walczuchella, which provides them with essential nutrients. When compared to other ancient symbionts with similar genome sizes, such as Karelsulcia, Walczuchella's genome was previously reported as unusually pseudogene-rich (10 % of coding sequences). However, this result was based on only one genome assembly, raising questions about the assembly quality or a recent ecological shift such as co-symbiont acquisition driving the gene loss. Here, we generated six complete genomes of Walczuchella from three genera of giant scales, each with distinct co-symbiotic partners. We show that all the genomes are highly degraded, and particularly genes related to the cellular envelope and energy metabolism seem to be undergoing pseudogenization. Apart from general mechanisms driving genome reduction, such as the long-term intracellular lifestyle with transmission bottlenecks, we hypothesize that a more profound loss of DNA replication and repair genes, together with recent co-obligate symbiont acquisitions, likely contribute to the accelerated degradation of Walczuchella genomes. Our results highlight that even ancient symbionts with small genomes can experience significant bursts of gene loss when stochastic processes erase a gene that accelerates gene loss or when the selection pressure changes such as after co-symbiont acquisition.

RevDate: 2025-05-29

Huffmyer AS, Wong KH, Becker DM, et al (2025)

Shifts and critical periods in coral metabolism reveal energetic vulnerability during development.

Current biology : CB pii:S0960-9822(25)00588-3 [Epub ahead of print].

Climate change accelerates coral reef decline and jeopardizes recruitment essential for ecosystem recovery. Adult corals rely on a vital nutritional exchange with their symbiotic algae (Symbiodiniaceae), but the dynamics of reliance from fertilization to recruitment are understudied. We investigated the physiological, metabolomic, and transcriptomic changes across 13 developmental stages of Montipora capitata, a coral in Hawai'i that inherits symbionts from parent to egg. We found that embryonic development depends on maternally provisioned mRNAs and lipids, with a rapid shift to symbiont-derived nutrition in late developmental stages. Symbiont density and photosynthesis peak in swimming larvae to fuel pelagic dispersal. By contrast, respiratory demand increases significantly during metamorphosis and settlement, reflecting this energy-intensive morphological reorganization. Symbiont proliferation is driven by symbiont ammonium assimilation in larval stages with little evidence of nitrogen metabolism in the coral host. As development progresses, the host enhances nitrogen sequestration, regulating symbiont populations, and ensuring the transfer of fixed carbon to support metamorphosis, with both metabolomic and transcriptomic indicators of increased carbohydrate availability. Although algal symbiont community composition remained stable, bacterial communities shifted with ontogeny, associated with holobiont metabolic reorganization. Our study reveals extensive metabolic changes during development with increasing reliance on symbiont nutrition. Metamorphosis and settlement emerge as critical periods of energetic vulnerability to projected climate scenarios that destabilize symbiosis. This highly detailed characterization of symbiotic nutritional exchange during sensitive early life stages provides essential knowledge for understanding and forecasting the function of nutritional symbioses and, specifically, coral survival and recruitment in a future of climate change.

RevDate: 2025-06-01
CmpDate: 2025-05-29

Wang H, Zhang J, Liu R, et al (2025)

An insect symbiotic virus promotes the transmission of a phytoarbovirus via inhibiting E3 ubiquitin ligase Sina.

PLoS pathogens, 21(5):e1013178.

Co-infection with symbiotic viruses and arboviruses with synergistic effects in insect vectors are common in nature, but the underlying mechanism remains elusive. Here, we identify a novel symbiotic virus, leafhopper Recilia dorsalis bunyavirus (RdBV), which enhances the transmission efficiency of cytorhabdovirus rice stripe mosaic virus (RSMV, a plant rhabdovirus) in field. RSMV infection activates the expression of R. dorsalis E3 ubiquitin ligase Seven in absentia (RdSina), while RdBV infection suppresses its expression. We show that RdSina directly targets and mediates the degradation of RSMV phosphoprotein (P), thereby attenuating the formation of P-induced viroplasm that are crucial for viral replication. RdSina interacts with nonstructural protein NSs2 of RdBV but does not mediate its ubiquitination. However, NSs2 competes with RSMV P for binding to RdSina, thus neutralizing RdSina's ability in mediating P degradation. Furthermore, we find that the MYC transcription factor binds to the promoter sequences of RdSina, activating its transcription. However, NSs2 also directly binds to the same promoter sequences of RdSina and competitively suppresses MYC-activated RdSina transcription. Together, NSs2 obstructs the function of RdSina in mediating P degradation, ultimately promoting RSMV propagation in co-infected vectors. These findings elucidate how insect symbiotic viruses negatively regulate E3 ubiquitin ligases to benefit arbovirus transmission by co-infected insect vectors, which potentially is a common phenomenon in nature.

RevDate: 2025-05-29
CmpDate: 2025-05-29

Ishfaq S, Anum H, Shaheen T, et al (2025)

Decoding fungal communication networks: molecular signaling, genetic regulation, and ecological implications.

Functional & integrative genomics, 25(1):111.

Fungal communication networks regulate essential biological processes, enabling fungi to adapt to environmental changes, coordinate development, and establish interactions within microbial communities. These networks are mediated by diverse signaling molecules, including volatile organic compounds (VOCs), peptide signaling molecules, and quorum-sensing molecules, which facilitate intra- and interspecies communication. The intricate regulation of these signals occurs through specialized signal transduction pathways such as G-protein-coupled receptors (GPCRs) and two-component regulatory systems, allowing fungi to sense external cues and modulate their physiological responses. Genetic mechanisms also play a critical role in fungal communication, influencing community dynamics through regulatory genes governing hyphal fusion, pheromone signaling, and secondary metabolite biosynthesis. Crosstalk between these signaling pathways is further modulated by epigenetic modifications, which fine-tune gene expression in response to environmental conditions. The integration of these molecular networks shapes fungal interactions, impacting resource acquisition, symbiosis, and pathogenicity. Additionally, fungal communication has significant ecological and evolutionary implications, contributing to niche establishment, microbial competition, and host-pathogen interactions. Despite significant progress in understanding fungal communication, key knowledge gaps remain regarding the interplay between signaling molecules, genetic regulation, and environmental adaptation. Future research should focus on unraveling the molecular mechanisms underlying fungal signaling networks and their potential applications in biotechnology, agriculture, and medicine. Harnessing fungal communication could lead to novel strategies for improving crop protection, developing antifungal therapies, and optimizing industrial fermentation processes. This review synthesizes recent advancements in fungal signaling research, providing a comprehensive perspective on its complexity and evolutionary significance.

RevDate: 2025-05-29

Vetukuri RR, Lanfranco L, K Stevens (2025)

Spray-induced gene silencing boosts functional genomics in symbiotic fungi.

The New phytologist [Epub ahead of print].

RevDate: 2025-05-31

Saleem MM, Masood S, Rahmatullah MM, et al (2025)

Gut Microbiota Dysbiosis and Its Role in the Development of Irritable Bowel Syndrome.

Cureus, 17(4):e83084.

The gut microbiota refers to the diverse community of symbiotic and pathogenic microorganisms inhabiting the host digestive tract. This microbiome plays a vital role in maintaining the integrity of the digestive system. Irritable bowel syndrome (IBS) is a functional gastrointestinal disorder (FGID) characterized by chronic abdominal pain and altered bowel habits. Although the pathophysiology of IBS remains unclear, recent studies suggest that the disruption of the gut microbiota (dysbiosis) may play a significant role. This study aims to examine the role of the gut microbiota in the development of IBS, analyze factors influencing the gut microbiome, and explore the potential for microbiota-targeted therapies. Relevant literature published from 2014 until 2024 was sourced from Google Scholar, PubMed, and Scopus using the keywords "microbiome", "irritable bowel syndrome", "dysbiosis", "faecal transplantation", and "probiotics". This review revealed consistent evidence of gut microbiota dysbiosis in individuals with IBS, characterized by altered microbial diversity, composition, and metabolic function. Contributing factors included a reduced abundance of beneficial commensals, overgrowth of potentially pathogenic species, and disrupted host-microbiota interactions. This dysbiosis was also frequently associated with symptom severity and specific IBS subtypes. Emerging evidence further highlights the role of diet, stress, and genetic factors in modulating gut microbiota and influencing IBS development. The growing body of research supports a strong link between dysbiosis and the pathogenesis and symptomatology of IBS. Understanding the microbial underpinnings of IBS opens avenues for potential diagnostic biomarkers and innovative therapeutic interventions aimed at restoring a balanced gut microbiota. However, further research is needed to elucidate the underlying mechanisms and translate these insights into effective clinical strategies for the management of IBS. This review underscores the significance of gut microbiota in IBS and its potential as a target for future therapeutic interventions.

RevDate: 2025-05-31

McKenna V, Archibald JM, Beinart R, et al (2021)

The Aquatic Symbiosis Genomics Project: probing the evolution of symbiosis across the Tree of Life.

Wellcome open research, 6:254.

We present the Aquatic Symbiosis Genomics Project, a global collaboration to generate high quality genome sequences for a wide range of eukaryotes and their microbial symbionts. Launched under the Symbiosis in Aquatic Systems Initiative of the Gordon and Betty Moore Foundation, the ASG Project brings together researchers from across the globe who hope to use these reference genomes to augment and extend their analyses of the dynamics, mechanisms and environmental importance of symbioses. Applying large-scale, high-throughput sequencing and assembly technologies, the ASG collaboration will assemble and annotate the genomes of 500 symbiotic organisms - both the "hosts" and the microbial symbionts with which they associate. These data will be released openly to benefit all who work on symbioses, from conservation geneticists to those interested in the origin of the eukaryotic cell.

RevDate: 2025-05-31
CmpDate: 2025-05-29

Zhao L, Du J, Liu W, et al (2025)

How to strengthen primary health care? An exploratory study on the policy of vertical integration of high-quality medical resources based on symbiosis theory.

Frontiers in public health, 13:1578712.

BACKGROUND: The Vertical Integration of High-Quality Medical Resources (VI-HQMR) is a strategy of medical resource reallocation. It is the key to strengthen primary health care (PHC) and build an integrated delivery system (IDS). It contributes to the Sustainable Development Goals (SDGs) of universal health coverage (UHC) set out by the World Health Organization (WHO). In order to VI-HQMR, countries around the world have carried out many beneficial explorations. However, our understanding of the importance of clarifying the internal logical from policy perspective in the VI-HQMR is limited. This study aims to develop a theoretical model from the symbiotic perspective to improve the strategy of VI-HQMR.

METHODS: Policies related to the VI-HQMR were retrieved for exploratory research. The texts and entries were coded according to the four elements of symbiosis theory, the first-level categories and their variables were mined, and the occurrence frequency was used as the main indicator for thematic clustering.

RESULTS: A total of 609 policies were retrieved, among which 1,072 entries mentioned VI-HQMR. Results showed that the VI-HQMR included 482 symbiotic units, 549 symbiotic models, 383 symbiotic environments and 96 symbiotic interfaces. Secondary and above public hospitals and PHC institutions are the most important symbiotic units. Medical alliances are the most important symbiotic model. The symbiotic environment includes policy, technology and economics. The vertical integration of human resources is the main symbiotic interface.

CONCLUSION: The VI-HQMR is still in the initial exploration stage. The symbiotic model is changing from parasitism to the commensalism. To achieve the optimal mutualism model, we need to work hard from the symbiotic environment. Health administrative department should coordinate with other relevant departments to introduce special policies to support the VI-HQMR. Through opening the way for promotion, financial incentive, and informationization assistance, improve the enthusiasm of urban hospitals.

RevDate: 2025-05-29

Du H, Cai Y, Shen L, et al (2025)

Bifidobacterium animalis subsp. lactis modulates early-life immune response and gut metabolism.

Animal models and experimental medicine [Epub ahead of print].

BACKGROUND: The maturation of the immune system is critical during early life, as it involves the differentiation, maturation, and establishment of immune tolerance of immune cells. This process is influenced not only by genetic factors but also by environmental factors, particularly the symbiotic microbiota. Bifidobacterium animalis subsp. lactis (BB-12), originally found in dairy products, is widely used in infant formula and dietary supplements. However, its role and mechanisms in immune development during early life remain unclear.

METHODS: Using GF mice as the experimental model, B. animalis subsp. lactis BB-12 was administered via gavage during early life. In the juvenile stage, changes in T-cell subsets in the spleen, thymus, and gut intraepithelial lymphocytes (IEL) were assessed using spectral flow cytometry. Additionally, targeted metabolomics analysis of tryptophan metabolism and short-chain fatty acid pathways in colonic tissue was conducted to explore how B. animalis subsp. lactis BB-12 influences the immune system through gut microbiota metabolism.

RESULTS: BB-12 effectively modulates the gut immune microenvironment, leading to beneficial changes in T-cell subsets in key immune tissues such as the spleen, thymus, and gut IELs. Metabolomics analysis further supports these findings by showing that BB-12 intervention greatly increased the production of tryptophan derivatives and acetic acid in the colon of GF mice.

CONCLUSION: The findings provide theoretical evidence for the role of B. animalis subsp. lactis in immune system development and support its application in dietary supplements, suggesting potential as a component for infant immune health and in preventing immune-related diseases.

RevDate: 2025-05-28

Wang Q, Chu G, Gao C, et al (2025)

Effect of light intensity on performance, microbial community and metabolic pathway of algal-bacterial symbiosis in sequencing batch biofilm reactor treating mariculture wastewater.

Bioresource technology pii:S0960-8524(25)00692-3 [Epub ahead of print].

An algal-bacterial symbiosis (ABS) system was constructed in a sequencing batch biofilm reactor for mariculture wastewater treatment, and its performance, microbial community and metabolic pathway were analyzed under different light intensities. The ammonia oxidation rate and nitrate reduction rate under 7000 Lux light intensity were higher than other light intensities. Functional microorganisms including Nitrosomonas, Nitrospira, Alterinioella, and Chlorella vulgaris were enriched under 7000 Lux. Metabolism was the primary functional pathway based on Kyoto Encyclopedia of Genes and Genomes. Tricarboxylic acid (TCA) cycle, nitrogen metabolism and photosynthesis pathways belonging to Metabolism were promoted under 7000 Lux light intensity. The enhancement of light intensity promoted the algal photosynthesis, TCA cycle, electron generation, and nitrogen transformation. The TCA cycle and electron generation offered energy and electron donors for nitrogen transformation. This research provides fundamental knowledge to select optimal light intensity for ABS system treating mariculture wastewater.

RevDate: 2025-05-28

Chen B, Ouyang W, Yang J, et al (2025)

Dual stable isotope tracing the source and composition of biogenic substance in microalgae-bacteria symbiosis: What do the bacteria contribute to the microalgae bloom?.

The Science of the total environment, 985:179732 pii:S0048-9697(25)01373-7 [Epub ahead of print].

Microalgae blooms are often regarded as harmful, but during the process of microalgae blooms, there are positive ecological values that the biochemical interactions of symbiosis of microalgae and bacteria could inform new strategies for microalgae blooms management and water treatment. This study used [13]C and [15]N stable isotope labeling and elemental analysis to elucidate carbon and nitrogen metabolism and migration between microalgae and bacteria. Anabaena flos-aquae (AF) was selected as the target microalgae species to establish a symbiotic system with Brevundimonas lenta (B. lenta), Pseudomonas plecoglossicida (P. plecoglossicida) and mixed bacteria obtained from the Zhuxi River (ZX). The 14-day co-culture using sequential batch methods revealed that the synergy of AF with B. lenta and ZX enhanced carbon utilization efficiency in microalgae, with contribution rates of 9.69 % and 29.69 %, respectively, while also boosting nitrogen utilization by 17.72 % and 46.39 %, respectively. High-biodiversity bacterial communities in symbiotic systems improved carbon and nitrogen utilization while reducing CO2 emissions. Stable isotope analysis showed that symbiosis increased lighter isotope percentages in microalgae, with bacteria shifting from lighter to heavier isotopes. This study provides theoretical and experimental insights into managing microalgae blooms and water treatment by analyzing biogenic substance transport in microalgae-bacteria interactions.

RevDate: 2025-05-28
CmpDate: 2025-05-28

Sportès A, Hériché M, Inès D, et al (2025)

A transcriptomic perspective of P trade in mycorrhizal grapevine.

Mycorrhiza, 35(3):39.

Nutrient exchanges are a key feature of arbuscular mycorrhizal (AM) symbiosis. Grapevine (Vitis vinifera), one of the most economically important crops worldwide, relies heavily on AM symbiosis for its growth and development. Since the phylloxera crisis, cultivated grapevines are obtained by grafting a Vitis vinifera scion onto a rootstock. In this study, we investigated the responses of the rootstock "Riparia Gloire de Montpellier" to mycorrhizal root colonization under three distinct phosphate (P) levels. We explored regulatory aspects of plant P nutrition by comparing the transcriptome profiling of non-colonized roots and roots colonized by the AM fungus Rhizophagus irregularis DAOM197198. We have shown that P availability significantly influences gene expression in both the AM fungus and the grapevine. Our transcriptomic study shed light on the molecular mechanisms that prevail during the AM symbiosis of a perennial woody plant species, with available P affecting several functional classes of proteins. The nine genes coding for Pht1 transporters in the R. irregularis genome were either down-regulated (RiPT1 and RiPT2) or up-regulated by the high-P treatment (RiPT8 and RiPT11), up-regulated by the low-P treatment (RiPT5), and regulated in a P-dose-dependent manner (RiPT9 and RiPT10). Expression of two of the three identified AM-induced Pht1, VvPT4 and VvPT8, was enhanced under mycorrhizal conditions, but finely tuned by the P treatment. To immunolocalize VvPT4 and VvPT8, we developed an innovative root-clearing protocol specifically designed for woody plants. This technological advancement has made it possible to visualize only VvPT4 at the periarbuscular membrane of mature arbuscules, its expression being strongly influenced by differences in P availability.

RevDate: 2025-05-28
CmpDate: 2025-05-28

He B, Li M, Guo S, et al (2025)

Host complement C3 promotes malaria transmission by killing symbiotic bacteria in the mosquito midgut.

Proceedings of the National Academy of Sciences of the United States of America, 122(22):e2424570122.

Host-derived factors ingested during mosquito blood feeding are poorly understood modulators of malaria transmission. Here, we demonstrated that host complement C3, acquired by mosquitoes during Plasmodium infection, significantly enhanced rodent malaria infection in laboratory-reared mosquitoes. This effect was recapitulated in field-caught Anopheles sinensis mosquitoes, confirming its relevance to malaria transmission in a more natural setting. Moreover, host-derived C3 significantly reduced the efficacy of anti-Pfs25 antibodies in blocking malaria transmission. Mechanistically, host-derived C3 lyses the mosquito midgut symbiont Elizabethkingia anophelis (E. anophelis)-a bacterium that intrinsically suppresses parasite development by blocking the zygote-to-ookinete transition. Strikingly, host-derived C3 in mosquitoes appears to be activated by the alternative pathway, and inhibiting Factor B with Iptacopan (LNP023) reduced Plasmodium falciparum (P. falciparum) infection, while increased the efficacy of anti-Pfs25 antibodies to blocking P. falciparum transmission in the standard membrane-feeding assay. Therefore, this study describes a strategy of the malaria parasite to utilize host complement C3 to promote its transmission and provides us with an avenue to block malaria transmission and improve the blocking efficacy of anti-Pfs25 antibodies by the inhibition of C3 activation.

RevDate: 2025-05-28

Weisse L, Martin L, Moumen B, et al (2025)

Environmental diversity of Candidatus Babelota and their relationships with protists.

mSystems [Epub ahead of print].

Ca. Babelota is a phylum of strictly intracellular bacteria whose representatives are commonly detected in various environments through metagenomics, though their presence, ecology, and biology have never been addressed so far. As a group of strict intracellular, we hypothesize that their presence, occurrence, and abundance heavily depend on their hosts, which are known as heterotrophic protists, based on few described isolates. Here, we conducted a sampling campaign allowing to characterize protists and associated bacterial communities, using high-throughput sequencing. In parallel, a systematic enrichment of protists from samples was performed to attempt characterization and isolation of new Ca. Babelota within native hosts. We found that Ca. Babelota are among the most widespread phylum among the rare ones. Protist enrichments are allowed in certain cases to enrich as well for Ca. Babelota, which could be visualized in vivo infecting protist cells. Though cosmopolitan, Ca. Babelota diversity was highly site-specific. Cooccurrence analyses allowed to retrieve well-known as well as new putative associations involving numerous protists of various trophic regimes. The combination of approaches developed in this study enhances our understanding of Ca. Babelota ecology and biology, while paving the way for future isolation of new members of this elusive phylum, which could have huge impact on protists-and ecosystems-functioning.IMPORTANCEOur understanding of microbial diversity surrounding us and colonizing the environment has been dramatically impacted by the advent of DNA-based analyses. Such progress helped shine a new light on numerous lineages of yet-to-be-characterized microbes, whose ecology and biology are basically unknown. Among those uncharacterized clades is the Candidatus Babelota, a bacterial phylum for which parasitism seems to be an ancestral trait. All known Ca. Babelota thrive by infecting phagotrophic protist hosts, thereby impacting this basal link of the trophic chain. The Ca. Babelota constitutes a model that stands out, as phylum-wide conserved parasitism has only been described in one previous occurrence for Bacteria, with the Chlamydiota. Thus, exploring the intricate interplay between Ca. Babelota and their protist hosts will advance our knowledge of bacterial diversity, their ecology, and global impact on ecosystem functioning.

RevDate: 2025-05-28

Shen Y, Yan Y, Yin T, et al (2025)

An isoflavone reductase-like protein MtIFL negatively regulates nodule symbiosis in Medicago truncatula.

The New phytologist [Epub ahead of print].

Flavonoids are valuable metabolites produced by legumes, including Medicago truncatula, and play crucial roles in signaling communication during legume-rhizobium symbiosis. Isoflavone reductase proteins (IFRs) are involved in the biosynthesis of isoflavones and plant defense regulation. However, their role in symbiotic nitrogen fixation remains mostly elusive. Here, 13 putative IFR gene family members were identified, and an IFR-like gene named MtIFL was functionally characterized through expression patterns, phenotypic characterizations, flavonoid metabolome, and transcriptome analyses. Furthermore, the binding partner of MtIFL was investigated using Y1H, EMSA, and Dual-LUC assays. MtIFL was strongly induced in the process of nodule development and expressed in the meristem and infection zone of mature nodules. Knockout of MtIFL promoted nodulation, while overexpression of MtIFL induced premature senescence of nodules. Further investigations revealed that MtIFL negatively regulates nitrogen-fixing symbiosis by mediating isoflavone metabolism, and MtNIN regulates MtIFL expression by binding to the hNRE motif. Overall, our findings suggest that MtIFL negatively regulates nodule formation, thereby influencing the survival of rhizobia in nodule cells. MtNIN regulates MtIFL expression and may play a role in isoflavone metabolism. These results provide novel insights into the function of IFRs in symbiotic nodulation and the role of flavonoids in nodule development.

RevDate: 2025-05-28

Jung M, DH Lee (2025)

Effects of gut symbiotic bacteria, Caballeronia insecticola, on reproductive capacity and mating behaviors of insect host, Riptortus pedestris (Hemiptera: Alydidae).

Environmental entomology pii:8151994 [Epub ahead of print].

This study addresses how gut symbiont, Caballeronia insecticola, could change reproductive capacity, mating behaviors, and copulation success of host insect, Riptortus pedestris (Fabricius) (Hemiptera: Alydidae). First, we evaluated symbiotic effects on the female reproductive capacity with varying numbers of males available to a female. Overall, symbiotic females displayed on average a 1.8-fold increase in egg production compared to aposymbiotic individuals. However, eggs from symbiotic females were on average 42% less viable, compared to those from the aposymbiotic, when paired with single male. The decrease in the hatchability was alleviated to 12% when paired with 3 males. Consequently, this yielded significant increase in the number of viable offspring by symbiotic females when multiple males were available. Second, we evaluated symbiotic effects on male morphometric characteristics including hind legs used as weapon, and found significant increases in hind leg sizes associated with symbiosis. Finally, we investigated mating behaviors between a female and 2 males of different symbiotic status. Symbiotic females displayed on average a 1.4-fold increase in the number of copulations compared to the aposymbiotic. From both female types, however, no significant difference was observed in their mate choice and copulation success rate between aposymbiotic and symbiotic males. However, symbiotic females exhibited on average 17% reduction in copulation duration compared to the aposymbiotic. Copulation failure was caused more frequently by female's rejection than by intruder male's disruption for both female types. Our study demonstrates that symbiotic females benefit from the symbiosis increasing their reproductive capacity and copulation frequency.

RevDate: 2025-05-28
CmpDate: 2025-05-28

Murcia-Flores L, Sánchez-García A, Pecci-Lloret MP, et al (2025)

Association between oral dysbiosis and Parkinson's disease: a systematic review.

Frontiers in cellular and infection microbiology, 15:1564362.

UNLABELLED: The oral cavity serves as the gateway to the human organism, hosting a diverse community of microorganisms that coexist in a state of symbiosis. Disruption of this balance leads to oral dysbiosis, a condition associated with infections and oral pathologies, which may contribute to the etiopathogenesis of systemic disorders such as Parkinson's disease, a neurodegenerative movement disorder characterized by resting tremor, rigidity, and bradykinesia. While oral dysbiosis is recognized as a risk factor and an aggravating element for Parkinson's disease, it is not regarded as a direct cause. This systematic review aims to synthesize existing research exploring the potential relationship between oral dysbiosis and the development of Parkinson's disease. Following a comprehensive analysis, 12 studies were selected, comprising 11 case-control studies and one observational analytical study. These studies investigated the composition of oral microbiota in different sample groups, revealing a higher abundance of pathogenic oral bacteria in individuals diagnosed with Parkinson's disease. The findings suggest that oral dysbiosis may influence both the onset of Parkinson's disease and the progression of symptoms such as cognitive decline. These results pave the way for future research, particularly regarding alterations in oral microbiota as potential biomarkers for early diagnosis and disease monitoring.

https://www.crd.york.ac.uk/prospero/, identifier CRD42024540056.

RevDate: 2025-05-28

Park JS, Kim J, Kim Y, et al (2025)

Whole Genome Sequences of Cryptotympana atrata Fabricius, 1775 (Hemiptera: Cicadidae) in the Korean Peninsula: Insights into Population Structure with Novel Pathogenic Or Symbiotic Candidates.

Current genomics, 26(2):118-128.

BACKGROUND: The blackish cicada (Cryptotympana atrata) exhibits unique characteristics and is one of the model cicadas found in the Korean Peninsula. It is a species of southern origin, prefers high temperatures, and is listed as a climate-sensitive indicator species in South Korea. Therefore, this species can be utilized to study the impact of climate change on the genetic diversity and structure of populations. However, research on the genome of C. atrata is limited.

METHODS: We sequenced the genome of an individual collected from South Korea and constructed a draft genome. Additionally, we collected ten specimens from each of the five regions in South Korea and identified single nucleotide variants (SNVs) for population genetic analysis. The sequencing library was constructed using the MGIEasy DNA Library Prep Kit and sequenced using the MGISEQ-2000 platform with 150-bp paired-end reads.

RESULTS: The draft genome of C. atrata was approximately 5.0 Gb or 5.2 Gb, making it one of the largest genomes among insects. Population genetic analysis, which was conducted on four populations in South Korea, including both previously distributed and newly expanded regions, showed that Jeju Island, a remote southern island with the highest average temperature, formed an independent genetic group. However, there were no notable genetic differences among the inland populations selected based on varying average temperatures, indicating that the current population genetic composition on the Korean Peninsula is more reflective of biogeographic history rather than climate-induced genetic structures. Additionally, we unexpectedly observed that most individuals of C. atrata collected in a specific locality were infected with microbes not commonly found in insects, necessitating further research on the pathogens within C. atrata.

CONCLUSION: This study introduces the draft genome of C. atrata, a climate-sensitive indicator species in South Korea. Population analysis results indicate that the current genetic structure of C. atrata is driven by biogeographic history rather than just climate. The prevalence of widespread pathogen infections raises concerns about their impact on C. atrata. Considering the scarcity of publicly available genomic resources related to the family Cicadidae, this draft genome and population data of C. atrata are expected to serve as a valuable resource for various studies utilizing cicada genomes.

RevDate: 2025-05-28

Zhong J, Ran Q, Han Y, et al (2025)

Biosynthetic Mechanisms of Plant Chlorogenic Acid from a Microbiological Perspective.

Microorganisms, 13(5):.

Chlorogenic acid (CGA), a phenolic compound with diverse bioactivities, plays a crucial role in plant defense mechanisms and has significant therapeutic potential in human inflammatory and cardiovascular diseases. The biosynthesis and accumulation of CGA in plants result from a complex interplay between internal factors (e.g., hormones, enzymes, and genes) and external factors (e.g., microbial interactions, drought, and temperature fluctuations). This review systematically investigates the influence of microbes on internal regulatory factors governing CGA biosynthesis in plants. CGA is synthesized through four distinct metabolic pathways, with hormones, enzymes, and genes as key regulators. Notably, microbes enhance CGA biosynthesis by improving plant nutrient uptake, supplying essential hormones, regulating the expression of related enzymes and genes, and the interaction between bacteria and fungi. In addition, our review summarizes the challenges currently present in the research and proposes a series of innovative strategies. These include in-depth investigations into the molecular mechanisms of microbial regulation of plant gene expression, gene editing, development of microbial inoculants, construction of synthetic microbial communities, and exogenous application of plant hormones.

RevDate: 2025-05-28

Jimbo M, Kuniya N, Fujimaki Y, et al (2025)

A Lectin AtTL-2 Obtained from Acropora aff. tenuis Induced Stimualation of Phagocytosis of Symbiodiniaceae.

Microorganisms, 13(5):.

The coral Acropora aff. tenuis selectively acquired various zooxanthella (Symbiodiniaceae) strains, and one of the selective factors was lectins. The A. aff. tenuis lectin AtTL-2 was identified as a factor for Symbiodiniaceae acquisition by the coral, but the mechanism is not fully known. The acquisition process involves three steps: chemotaxis, entry into the coral, and phagocytosis. In this study, we examined the function of AtTL-2 in more detail. Immunohistochemistry analysis was performed to examine the distribution of AtTL-2. The effect of AtTL-2 on the number of Symbiodiniaceae acquired was measured in A. aff. tenuis juvenile polyps with and without AtTL-2 siRNA treatment. The effect of AtTL-2 fixation was examined by monitoring the acquisition of AtTL-2-fixed beads by A. aff. tenuis. AtTL-2 was distributed in nematocysts, spirocysts, and around Symbiodiniaceae. AtTL-2 siRNA inhibited the acquisition of Symbiodiniaceae by juvenile polyps. Fixation of AtTL-2 promoted bead acquisition by juvenile polyps more than fixation of bovine serum albumin (BSA). Moreover, more AtTL-2-fixed beads were bound to the Symbiodiniaceae-enclosed cells than BSA-fixed beads. AtTL-2 is released from spirocysts and binds to Symbiodiniaceae. AtTL-2 then promotes the phagocytosis of Symbiodiniaceae by gastrodermal cells of A. aff. tenuis.

RevDate: 2025-05-28

Peng C, Li Y, Yu H, et al (2025)

Synergistic Recruitment of Symbiotic Fungi by Potting and Scleroderma bovista Inoculation Suppresses Pathogens in Hazel Rhizosphere Microbiomes.

Microorganisms, 13(5):.

This study explored how potted treatments (with and without Scleroderma bovista inoculation) shape rhizosphere microbial diversity in hazel across five soils using split-root cultivation. Three treatments (control, split-root, split-root with S. bovista) were analyzed for root growth and microbial dynamics. S. bovista inoculation consistently enhanced root parameters (number, tips) in all soils. Potted treatments (with and without S. bovista inoculation) altered microbial features (OTU/ASV), with only 0.9-3.3% of features remaining unchanged. At the class level, potting increased Agaricomycetes abundance while reducing Sordariomycetes, a trend amplified by S. bovista. Potting decreased species richness estimates (ACE and Chao1), while both treatments lowered diversity index (Shannon index). Potted treatments without S. bovista inoculation drove stronger shifts in species composition than inoculation. Findings reveal potting and S. bovista synergistically recruit symbiotic fungi via root exudates, establishing disease-suppressive communities that selectively inhibit pathotrophic fungi (particularly plant pathogen Coniothyrium and fungal parasite Cladobotryum) while roughly maintaining non-pathogenic saprotrophic microbes essential for organic matter decomposition. This work provides insights for optimizing hazel orchard management and ectomycorrhizal agent development.

RevDate: 2025-05-28

Fujishima M (2025)

Infection with the Endonuclear Symbiotic Bacterium Holospora obtusa Reversibly Alters Surface Antigen Expression of the Host Paramecium caudatum.

Microorganisms, 13(5):.

It is known that the ciliate Paramecium cell surface including cilia is completely covered by high-molecular-mass GPI-anchored proteins named surface antigens (SAgs). However, their functions are not well understood. It was found that ciliate Paramecium caudatum reversibly changes its SAgs depending on the absence or presence of the endonuclear symbiotic bacterium Holospora obtusa in the macronucleus. Immunofluorescence microscopy with a monoclonal antibody produced SAg of the H. obtusa-free P. caudatum strain RB-1-labeled cell surface of the H. obtusa-free P. caudatum RB-1 cell but not the H. obtusa-bearing RB-1 cell. When this antibody was added to the living P. caudatum RB-1 cells, only H. obtusa-free cells were immobilized. An immunoblot with SAgs extracted from Paramecium via cold salt/ethanol treatment showed approximately 266-kDa SAgs in the extract from H. obtusa-free cells and 188 and 149-kDa SAgs in the extract from H. obtusa-bearing cells. H. obtusa-free RB-1 cells produced from H. obtusa-bearing cells via treatment with penicillin-G-potassium re-expressed 266-kDa SAg, while the 188 and 149-kDa SAgs disappeared. This phenotypic change in the SAgs was not induced by degrees of starvation or temperature shifts. These results definitively show that Paramecium SAgs have functions related to bacterial infection.

RevDate: 2025-05-28

Jiang K, Ye L, Cao C, et al (2025)

Multi-Metagenome Analysis Unravels Community Collapse After Sampling and Hints the Cultivation Strategy of CPR Bacteria in Groundwater.

Microorganisms, 13(5):.

Groundwater harbors phylogenetically diverse Candidate Phyla Radiation (CPR) bacteria, representing an ideal ecosystem for studying this microbial dark matter. However, no CPR strains have been successfully isolated from groundwater, severely limiting further research. This study employed a multi-metagenome approach, integrating time-resolved sampling, antibiotic/nutrient interventions, and microbial correlation networks to unravel CPR ecological roles in groundwater and provide insights into their subsequent cultivation. Through 36 metagenomes from a groundwater system containing at least 68 CPR phyla, we revealed the time-sensitive collapse of CPR communities: total abundance plummeted from 7.9% to 0.15% within 48 h post-sampling, driven by competition with rapidly dividing non-CPR bacteria, such as members of Pseudomonadota. Ampicillin (100 mg/L) stabilized CPR communities by suppressing competitors, whereas low-nutrient conditions paradoxically reversed this effect. Long-term enrichment (14 months) recovered 63 CPR phyla (0.35% abundance), revealing their survival resilience despite nutrient deprivation. Correlation networks prioritized Actinomyces, a novel Acidimicrobiaceae genus, Aestuariivirga, Baekduia and Caedimonadaceae as potential CPR partners, providing actionable targets for co-culture trials. Here, we propose actionable recommendations spanning groundwater sampling, activation status, identification of CPR symbiotic partners, and optimization of culture conditions, which bypass traditional blind cultivation and are critical for future efforts to cultivate CPR bacterial strains from groundwater. Cultivating CPR bacteria will contribute to clarifying their diversity, ecological roles, evolutionary mechanisms, metabolic pathways, and genetic potential.

RevDate: 2025-05-28

Lv C, Meng T, Zhong B, et al (2025)

Pathogenicity of Steinernema carpocapsae ALL Entomopathogenic Nematodes and Their Symbiotic Bacteria as a Biological Control Agent on Red Palm Weevil.

Microorganisms, 13(5):.

Insect-specific pathogens present a sustainable alternative to pesticides for managing the red palm weevil (RPW). This study assessed the efficacy of Steinernema carpocapsae ALL nematodes and their symbiotic bacteria against the third-instar larvae and adults of RPW under laboratory conditions. The symbiotic bacteria were isolated, morphologically characterized, and genetically identified. The results indicated that the mortality rates of RPW larvae treated with S. carpocapsae exceeded 50% in all treatments at 120 h, reaching 93.33% at a concentration of 250 IJs/mL. The morphology of isolated symbiotic bacterium from S. carpocapsae on NBTA medium exhibited a light green color with a glossy surface, a raised center, and a mucilaginous texture. A novel strain of symbiotic bacterium was identified and named as LZ-G7. The bacteria toxicity on RPW adults showed a notable mortality rate of 66.67% at 48 h after feeding with concentration of 10 × 10[7] CFU/mL. The mortality rate of the third-instar larvae of RPW reached 83.33% after feeding with 0.30 × 10[8] CFU/g at 96 h and 93.33% after injection into blood cavity with 8 × 10[6] CFU at 48 h. These results suggest that S. carpocapsae and a novel symbiotic bacterium strain exhibit strong virulence against RPW and have the potential to serve as effective biological control agents in integrated pest management strategies.

RevDate: 2025-05-28

Xue Q, Liu J, Cao Y, et al (2025)

Host Lifeform Shapes Phyllospheric Microbiome Assembly in Mountain Lake: Deterministic Selection and Stochastic Colonization Dynamics.

Microorganisms, 13(5): pii:microorganisms13050960.

The phyllosphere microbiome of aquatic macrophytes constitutes an integral component of freshwater ecosystems, serving crucial functions in global biogeochemical cycling and anthropogenic pollutant remediation. In this study, we examined the assembly mechanisms of epiphytic bacterial communities across four phylogenetically diverse macrophyte species (Scirpus validus, Hippuris vulgaris, Nymphoides peltatum, and Myriophyllum spicatum) inhabiting Ningwu Mayinghai Lake (38.87° N, 112.20° E), a vulnerable subalpine freshwater system in Shanxi Province, China. Through 16S rRNA amplicon sequencing, we demonstrate marked phyllospheric microbiome divergence, as follows: Gammaproteobacteria dominated S. validus, H. vulgaris and N. peltatum, while Alphaproteobacteria dominated in M. spicatum. The nitrate, nitrite, and pH value of water bodies and the chlorophyll, leaf nitrogen, and carbon contents of plant leaves are the main driving forces affecting the changes in the β-diversity of epiphytic bacterial communities of four plant species. The partitioning of assembly processes revealed that deterministic dominance governed S. validus and M. spicatum, where niche-based selection contributed 67.5% and 100% to community assembly, respectively. Conversely, stochastic processes explained 100% of the variability in H. vulgaris and N. peltatum microbiomes, predominantly mediated by dispersal limitation and ecological drift. This investigation advances the understanding of microbial community structural dynamics and diversity stabilization strategies in aquatic macrophyte-associated microbiomes, while establishing conceptual frameworks between plant-microbe symbiosis and the ecological homeostasis mechanisms within vulnerable subalpine freshwater ecosystems. The empirical references derived from these findings offer novel perspectives for developing conservation strategies aimed at sustaining biodiversity equilibrium in high-altitude lake habitats, particularly in the climatically sensitive regions of north-central China.

RevDate: 2025-05-28

Xie K, Wang G, Ni Y, et al (2025)

ZmHPAT2 Regulates Maize Growth and Development and Mycorrhizal Symbiosis.

Plants (Basel, Switzerland), 14(10): pii:plants14101438.

Hydroxyproline O-arabinosyltransferase (HPAT), a critical enzyme in plant glycosylation pathways, catalyzes the transfer of arabinose to the hydroxyl group of hydroxyproline residues. This enzyme contains a canonical GT95 glycosyltransferase, a structural hallmark of this carbohydrate-active enzyme family. HPAT mediates arabinosylation of diverse cellular targets, including cell wall extension and small signaling peptides. Emerging evidence has shown that HPAT orthologs regulate plant development and symbiotic interactions through post-translational modification of CLV1/LRR Extracellular (CLE) peptides. Although the molecular functions of HPAT genes have been characterized in model plants such as Arabidopsis thaliana and Lotus japonicus, their roles remain unexplored in Zea mays L. In this study, we used ZmHPAT2 homozygous mutants to explore the function of the maize HPAT gene. Sequence analysis identified a N-terminal signal peptide targeting the Golgi apparatus and promoter elements responsive to AM fungal colonization. Phenotypic analysis revealed its negative regulatory role: zmhpat2 promotes vegetative growth (increased plant height and accelerated flowering) and enhances AM symbiosis (increased colonization rate). Mechanistic studies demonstrated that ZmHPAT2 possesses dual regulatory functions-the activation of auxin signaling and repression of ZmMYB1-mediated arbuscular degradation pathways. In addition, overexpression of ZmHPAT2 in Lotus japonicus inhibits growth (reduced plant height) and impairs symbiotic interactions. Our findings establish ZmHPAT2 as a critical node to regulate auxin and symbiotic signaling, providing novel insights into plant glycosylation-mediated development. This work not only advances our understanding of maize growth regulation but also identifies potential targets for crop improvement through arabinosylation pathway manipulation.

RevDate: 2025-05-28
CmpDate: 2025-05-28

San-Martin MI, Chamizo-Ampudia A, Sanchiz Á, et al (2025)

Microbiome Markers in Gastrointestinal Disorders: Inflammatory Bowel Disease, Colorectal Cancer, and Celiac Disease.

International journal of molecular sciences, 26(10): pii:ijms26104818.

Intestinal microbiota and the host's immune system form a symbiotic alliance that sustains normal development and function in the human gut. Changes such as dietary habits among societies in developed countries have led to the development of unbalanced microbial populations in the gut, likely contributing to the dramatic increase in inflammatory diseases in the last few decades. Recent advances in DNA sequencing technologies have tremendously helped to characterize the microbiome associated with disease, both in identifying global alterations and discovering specific biomarkers that potentially contribute to disease pathogenesis, as evidenced by animal studies. Beyond bacterial alterations, non-bacterial components such as fungi, viruses, and microbial metabolites have been implicated in these diseases, influencing immune responses and gut homeostasis. Multi-omics approaches integrating metagenomics, metabolomics, and transcriptomics offer a more comprehensive understanding of the microbiome's role in disease pathogenesis, paving the way for innovative diagnostic and therapeutic strategies. Unraveling the metagenomic profiles associated with disease may facilitate earlier diagnosis and intervention, as well as the development of more personalized and effective therapeutic strategies. This review synthesizes recent and relevant microbiome research studies aimed at characterizing the microbial signatures associated with inflammatory bowel disease, colorectal cancer, and celiac disease.

RevDate: 2025-05-28

Civolani S, Bariselli M, Osti R, et al (2025)

Insect Pest Control from Chemical to Biotechnological Approach: Constrains and Challenges.

Insects, 16(5): pii:insects16050528.

The large growth in the global population requires new solutions for the control of harmful insects that compete for our food. Changing regulatory requirements and public perception, together with the continuous evolution of resistance to conventional insecticides, also require, in addition to innovative molecules with different modes of action, new non-chemical control strategies that can help maintain efficient integrated pest management programs. The last 30 years have inaugurated a new era characterised by the discovery of new mechanisms of action and new chemical families. Although European programs also promote a green deal in the crop protection sector, the existing thorough regulations slow down its spread and the adoption of new products. In light of these changes, this review will describe in more detail the dynamics of discovery and registration of new conventional insecticides and the difficulties that the agrochemical industries encounter. Subsequently, the different innovative control strategies alternative to conventional insecticides based on natural substances of different origin, entomopathogenic microorganisms, semiochemical and semiophysical compounds, and classical and augmentative biological control will be described. The advantages of these green strategies will be illustrated and also the constrains to their diffusion and commercialisation. Finally, the main biotechnological discoveries will be described, from transgenic plants to symbiotic control, classical genetic control, and, more recently, control based on insect genomic transformation or on RNAi. These new biotechnologies can revolutionise the sector despite some constrains related to the regulatory restrictions present in different countries.

RevDate: 2025-05-28

Rybalka D, V Brygadyrenko (2025)

Effects of Toxic Organic Compounds on Tenebrio molitor and Its Parasite Gregarina steini.

Biology, 14(5): pii:biology14050453.

Environmental pollution by toxic compounds affects various species of living organisms, their life cycles, and symbiotic relationships. This study investigated the host-parasite relationship between Tenebrio molitor Linnaeus, 1758 (Coleoptera, Tenebrionidae) and Gregarina steini Berthold, 1827 (Eugregarinorida, Gregarinida) under exposure to aniline, formaldehyde, and o-xylene at different concentrations. For laboratory studies, 480 larvae of T. molitor and five concentrations of the studied organic compounds were used. Groups of T. molitor, each consisting of ten individuals, were subjected to the tested compounds for 10 days following the initial weight measurement. We measured the body weight and survival rate of T. molitor and the number of G. steini in them to assess the impact of the tested organic compounds on the host-parasite relationship. For all the compounds studied, a decrease in body weight and high mortality were observed in T. molitor at high concentrations. The lethality of the studied organic compounds was concentration-dependent. o-Xylene showed low toxicity at lower concentrations (10.4 and 26.0 mg/kg of feed), with a survival rate of 93.3% and 86.7%, respectively. At a concentration of 10.4 mg/kg, no lethal cases in T. molitor were observed. At higher concentrations (78 and 104 mg/kg feed), T. molitor mortality significantly increased to 33.3% and 53.3%, respectively.

RevDate: 2025-05-27

Xie J, P Lu (2025)

Cytochrome P450s from the fungal symbiont of Sirex noctilio, Amylostereum areolatum: characterization, sequence analysis and their response to host terpenoids.

Gene pii:S0378-1119(25)00382-8 [Epub ahead of print].

Amylostereum areolatum is the main symbiotic fungus of woodwasp (Sirex noctilio) and is an active participant in the large-scale death of Pinus sylvestris. Woodwasps and associated fungi resort to active detoxification mechanisms to overcome the toxicity of host defence chemicals, which consist of a multitude of monoterpenes and diterpenes. Since cytochrome P450 (CYP) is considered to have extensive detoxification capabilities in fungi, 35 CYP genes were identified from A. areolatum by Iso-Seq. Moreover, we analysed the transcriptional levels of 11 chosen CYPs in the mycelia of fungi grown on different carbon sources or sprayed with different terpene mixtures or extracts to explore the relationship between CYPs and utilization of terpenoids or the detoxification capabilities for terpenoids. Molecular modeling and docking were also employed to predict the interaction between the P450 protein structure and substrate. The results showed that the 35 CYPs of A. areolatum belong to 22 families and 12 clans, and all had the typical P450 conserved domains. RT-qPCR revealed that most CYPs were down-regulated with monoterpenes as the sole carbon source and up-regulated with diterpenes. CYPs were induced after spraying with xylem extract, and venom can increase the expression levels of CYPs. Molecular docking predicted that three P450 proteins (CYP5037BM3, CYP5144KC1, and CYP5152T1) bind tightly to diterpenes through hydrogen bonds and π-alkyl interactions, they have a higher binding affinity for diterpenes than for monoterpenes, suggesting that they may preferentially metabolize diterpenes. This indicates that A. areolatum regulates the expression levels of key P450 enzymes through a special response pattern to reduce the toxicity of the chemical defence of the host on itself and its symbiotic insect, Sirex noctilio.

RevDate: 2025-05-27
CmpDate: 2025-05-27

Atanasković I, Nedeljković M, J Lozo (2025)

Beyond pathogenicity: the immunomodulatory role of the type III secretion system in beneficial plant-microbe interactions.

Open biology, 15(5):240318.

The type III secretion system (T3SS) has traditionally been studied for its role in bacterial virulence. However, recent research emphasizes its dual role in beneficial interactions between bacteria and plants. This review examines the immunomodulatory functions of T3SS beyond pathogenicity and focuses on how T3SS effectors manipulate plant immune responses to promote symbioses. By comparing T3SS mechanisms in pathogenic and non-pathogenic bacteria, we aim to understand how this system enables beneficial microbes to colonize plants and improve plant growth and stress resilience. We also investigate the potential of T3SS to trigger induced systemic resistance in plants, a mechanism that could be utilized in agriculture to improve crop resistance to pathogens. The review concludes with an outlook on future research and emphasizes the need for comprehensive studies on T3SS effectors in non-pathogenic bacteria and their interactions with plant hosts.

RevDate: 2025-05-27

Cabric V, CC Brown (2025)

Thetis cells: regulators of intestinal immune tolerance.

Current opinion in immunology, 95:102570 pii:S0952-7915(25)00046-9 [Epub ahead of print].

Our body's mucosal surfaces interface with the external environment and are potential sites of entry for pathogens as well as noxious substances. Yet, these barrier sites are also colonized with symbiotic microbes and are in contact with harmless environmental antigens. Different barrier epithelia harbor distinct microbial communities that shape both the epithelial layer and local immune cells that maintain tissue homeostasis and tolerance to symbiotic microbes. This seemingly paradoxical peaceful co-existence of immune cells and microbes has fascinated immunologists for decades: how does the immune system balance inflammatory and tolerogenic responses? The mechanisms underlying peripheral immune tolerance to harmless foreign antigens have been most widely studied within the intestine, where the immune system must establish and maintain tolerance to harmless food and commensal antigens. Dysregulated immune responses to these antigens are linked to several human diseases, including inflammatory bowel disease, celiac disease, and food allergy. Understanding the cellular and molecular cues that promote intestinal immune tolerance is key to the development of effective therapeutic strategies for these pathologies. Here, we review recent insights into mechanisms of intestinal tolerance with a focus on recently identified RORγt[+] antigen-presenting cells.

RevDate: 2025-05-27

Sun YP, Zhao MW, L Shi (2025)

The orchestration of ectomycorrhizal symbiosis: a review of fungal-produced symbiotic regulators and their functions.

Mycologia [Epub ahead of print].

Ectomycorrhiza is a mutualistic symbiotic association formed between fungi and plants, which enhances the host plant's stress resistance and promotes plant growth. It plays an important role in forest ecosystems. A plethora of symbiotically active regulatory molecules are secreted throughout the continuum of ectomycorrhizal development, encompassing the period before physical contact between the fungi and their host plant roots to the maturation of the ectomycorrhizal symbiosis. However, our understanding of these substances is still limited. In recent years, as research in this field has deepened, several studies have documented that fungi release symbiotic regulatory substances, including fungal-derived plant hormones and small secreted proteins, which participate in the regulation of mycorrhizal formation. This article, from a fungal perspective, elaborates on the symbiotic regulatory substances secreted by ectomycorrhizal fungi into the surrounding environment or within the host plant. It further discusses the role of these substances in establishing symbiotic relationships with plants, aiming to offer novel insights for researchers in this field.

RevDate: 2025-05-27

Wang L, Fu N, Wang M, et al (2025)

Integrative Transcriptome and Metabolome Analysis Reveals Candidate Genes Related to Terpenoid Synthesis in Amylostereum areolatum (Russulales: Amylostereaceae).

Journal of fungi (Basel, Switzerland), 11(5):.

Amylostereum areolatum (Chaillet ex Fr.) Boidin (Russulales: Amylostereaceae) is a symbiotic fungus of Sirex noctilio Fabricius that has ecological significance. Terpenoids are key mediators in fungal-insect interactions, yet the biosynthetic mechanisms of terpenoids in this species remain unclear. Under nutritional conditions that mimic natural growth, A. areolatum was sampled during the lag phase (day 7), exponential phase (day 14), and stationary phase (day 21). Metabolome (solid-phase microextraction (SPME) combined with gas chromatography-mass spectrometry (GC-MS) and liquid chromatography-mass spectrometry (LC-MS)) and transcriptome (Illumina NovaSeq) profiles were integrated to investigate terpenoid-gene correlations. This analysis identified 103 terpenoids in A. areolatum, substantially expanding the known repertoire of terpenoid compounds in this species. Total terpenoid abundance progressively increased across three developmental stages, with triterpenoids and sesquiterpenoids demonstrating the highest diversity and abundance levels. Transcriptomic profiling (61.66 Gb clean data) revealed 26 terpenoid biosynthesis-associated genes, establishing a comprehensive transcriptional framework for fungal terpenoid metabolism. Among 11 differentially expressed genes (DEGs) (|log2Fold Change| ≥ 1, adjusted p < 0.05), HMGS1, HMGR2, and AaTPS1-3 emerged as key regulators potentially governing terpenoid biosynthesis. These findings provide foundational insights into the molecular mechanisms underlying terpenoid production in A. areolatum and related basidiomycetes.

RevDate: 2025-05-27

Zhang Q, Yang W, Wang M, et al (2025)

Transcriptome Analysis Reveals the Molecular Mechanisms for Mycorrhiza-Enhanced Drought Tolerance in Maize by Regulating the Ca[2+] Signaling Pathway.

Journal of fungi (Basel, Switzerland), 11(5):.

With the continuous change of climate, drought stress has emerged as the primary constraint on crop growth, posing a significant threat to the stability of global grain reserves. Arbuscular mycorrhizal fungi (AMF), as a kind of widely distributed root endophytes, enhance the drought tolerance of maize (Zea mays L.) through regulating the physiological and molecular responses. However, comprehensive transcriptome analysis to reveal the molecular mechanism of drought tolerance in the symbiotic process between AMF and maize is still limited. In the potted plant experiment, maizes inoculated with and without arbuscular mycorrhizal fungus Funneliformis mosseae were grown under well-watered (WW) or drought-stressed (DS) conditions. By using RNA-Seq and transcriptome analysis on maize roots and leaves, this work aimed to investigate the differential expressed genes (DEGs) related to the Ca[2+] signaling pathway induced by AMF symbiosis under drought stress. Our findings indicated that F. mosseae inoculation resulted in a decrease in the net fluxes of Ca[2+], while simultaneously elevating Ca[2+] contents in the maize roots and leaves under well-watered or drought-stressed conditions. Notably, 189 DEGs were regulated not only by AMF symbiosis and drought stress, but also exhibited preferential expression in either leaves or roots. The annotation and enrichment of Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) showed that most of the DEGs were significantly enriched in Ca[2+] signaling pathway genes, related to signal transduction, cellular process, and defense response. A high number of DEGs with this function (including calcineurin B-like protein (CBL), CBL-interacting protein kinase (CIPK), mitogen-activated protein kinase (MAPK), and calcium-dependent protein kinase (CDPK) receptor kinases) were upregulated-DEGs or downregulated-DEGs in F. mosseae-inoculated maizes under drought stress. Furthermore, some DEGs belong to transcription factor (TF) families, including bHLH ERF, and, MYB, were speculated to play key roles in improving the drought tolerance of maize. Based on the expression data and co-expression analysis between TF and Ca[2+] signaling pathway genes, Whirly1 with CBL11, and BRI1-EMS-SUPPRESSOR 1 (BES1) with CBL10, CIPK24, CDPK1, CDPK14, CDPK19, and MAPK9 genes showed significant positive correlations, while B3 domain-containing transcription factors (B3 TFs) with MAPK1 and both CBL9 genes showed significant negative correlations in response to both F. mosseae inoculation and drought stress. The regulation of Ca[2+] signaling pathways by AMF symbiosis was an important response mechanism of maize to improve their drought resistance. This study provides insightful perspectives on how AMF-induced modulation of gene expression within the Ca[2+] signaling pathway can enhance the drought tolerance of mycorrhizal maize in the future.

RevDate: 2025-05-27

Xie K, Ni Y, Bai L, et al (2025)

Functional Characterization of Ammonium Transporter LjAMT2;4 During Lotus japonicus Symbiosis with Rhizobia and Arbuscular Mycorrhizal Fungi.

Journal of fungi (Basel, Switzerland), 11(5):.

Arbuscular mycorrhizal fungi (AMF) and rhizobia are important symbiotic microorganisms in soil, which can symbiose with legumes to form mycorrhizal symbionts and nodules, respectively. Once a stable symbiotic relationship is established, these microorganisms have been found to enhance nitrogen absorption by legumes. Although plants can directly utilize ammonium through ammonium transporters (AMTs), there is limited research on the role of the AMT gene family in promoting ammonium transport in symbiotic relationships. Lotus japonicus, a common host of arbuscular mycorrhizal fungi and rhizobia, serves as a model legume plant. In this study, we examined the characteristics of the ammonium transporter LjAMT2;4 in L. japonicus and found that LjAMT2;4 is localized to the plasma membrane and is predominantly expressed in roots. The promoter region of LjAMT2;4 contains cis-acting elements induced by arbuscular mycorrhizal fungi and rhizomes, and the expression of LjAMT2;4 was induced by AM fungi and rhizobia. However, there was no significant difference in the mycorrhizal colonization rate of ljamt2;4 compared to the wild type, while the absence of LjAMT2;4 significantly increased the number of root nodules under nitrogen-starved conditions, enhancing nitrogen fixation and alleviating nitrogen stress in extremely nitrogen-starved environments, ultimately promoting plant growth. These findings suggest that manipulating the genes involved in symbiotic nitrogen fixation, such as LjAMT2;4, could offer new strategies for sustainable agricultural production. Given that AM and rhizobia symbiosis are critical for crop growth, our findings may inform strategies to improve agricultural management.

RevDate: 2025-05-27

Zhang S, Yang Z, Yang X, et al (2025)

Plant-Soil Interactions Shape Arbuscular Mycorrhizal Fungal Diversity and Functionality in Eastern Tibetan Meadows.

Journal of fungi (Basel, Switzerland), 11(5):.

Arbuscular mycorrhizal (AM) fungi occur in the interface between soils and plants. Yet, the impacts of the plant community functional composition and soil properties on AM fungal communities remain poorly understood in the face of ongoing climate change. Here, we investigated the AM fungal community in alpine meadow habitats of the Tibetan Plateau by linking fungal species richness to plant community functional composition and soil parameters at three latitudinal sites. High-throughput sequencing of the AM fungal small subunit rRNA gene was performed to characterize fungal communities. We found that AM fungal diversity and plant functional diversity, as well as the contents of soil nutrients, were significantly higher in the southernmost site, Hongyuan (HY). Total soil nitrogen and soil-available phosphorus explained the variation in AM fungal diversity, while AM fungal biomass was best predicted by the plant community-weighed mean nitrogen:phosphorus ratio (CWM-N:P). Glomus species preferentially occurred in the northernmost site of Hezuo (HZ). Distance-based redundancy analysis (db-RDA) revealed that AM fungal community structure was influenced by not only CWM-N:P but also by plant community-weighed mean photosynthetic rate (CWM-Pn), soil total carbon, and plant community functional dispersion (FDis). We conclude that plant traits and soil properties are crucial for nutrient-carbon (C) exchange, as fungal symbionts may shape AM communities in this vast alpine meadow ecosystem. Our findings provide timely insight into AM fungal community assembly from the perspective of nutrient-C exchange dynamics in the Tibetan Plateau's alpine meadow habitats.

RevDate: 2025-05-27

Shen Y, He J, Ma Y, et al (2025)

MtPEPC2 Encodes a Phosphoenolpyruvate Carboxylase Essential for Symbiotic Nitrogen Fixation in Medicago truncatula.

Plant, cell & environment [Epub ahead of print].

Symbiotic nitrogen fixation (SNF) that takes place in root nodules of legumes essentially relies on the exchange of nitrogen (N) and carbon (C) metabolites between the symbiotic partners. The endosymbionts rhizobia provide ammonium to the host plants, and in return receive carbon and energy sources from the host for nitrogen fixation. In a forward genetic study, we identified FN6516 as an SNF-defective (fix[-]) mutant of Medicago truncatula. Whole genome resequencing, genetic linkage analysis of an F2 segregating population, genetic complementation and gene editing results show that a plant-type PEPC, MtPEPC2, is the candidate gene. We demonstrate that MtPEPC2 expression is activated in nodules and that a high level of expression is detected at an early stage of nodule development. MtPEPC2 protein is localised in the cytoplasm of both infected and uninfected cells, but not in symbiosomes. Our work shows that a nonsense mutation in MtPEPC2 resulted in a great reduction in PEPC activities, almost complete loss of nodule nitrogen fixation activities, and defects in differentiation and/or maintenance of bacteroids. Importantly, overexpression of MtPEPC2 increased nodule nitrogenase activities.

RevDate: 2025-05-27

Zhao X, Guo F, Ma Y, et al (2025)

Enzymatic Characterization of a Rumen Microorganism-Derived Multifunctional Glycoside Hydrolase and Its GH26 Domain with Mannanase Activity.

Journal of agricultural and food chemistry [Epub ahead of print].

In this study, a novel multifunctional glycoside hydrolase (GH) with two distinct domains homologous to the GH family 5 (GH5) and family 26 (GH26) was isolated from the rumen microorganism Segatella bryantii. The heterologous expression product of this enzyme exhibited both endo-β-1,4-glucanase and endo-β-1,4-mannanase activities. Intriguingly, segmental expression studies indicated that the GH26 domain alone contributed to the β-mannanase activity, and its specific activity reached 2060 U/mg under optimal conditions (30 °C, pH 5.5). Furthermore, site-directed mutagenesis confirmed that the glutamic acid residues at positions 165 and 276 were indispensable for the catalytic activity of the GH26 domain. Collectively, a novel multifunctional GH from a symbiotic microorganism of ruminants was identified. Preliminary enzymatic characterizations of its GH26 family domain, which has independent β-mannanase activities, were determined.

RevDate: 2025-05-27

Carner M, Bianconi L, Sacchetto L, et al (2025)

The"symbiotic"regulation approach in bimodal hearing adults.

Indian journal of otolaryngology and head and neck surgery : official publication of the Association of Otolaryngologists of India, 77(6):2239-2246.

PURPOSE: Patients with bimodal auditory stimulation represent an expanding group of cochlear implant users in many countries. The hearing results reported in the literature for subjects with bimodal hearing are controversial and often only evaluate hearing aids that are simply synchronized with their cochlear implant ("synchronized" regulation) and sometimes even adapted independently of the cochlear implant ("classic" regulation). This study aims to verify that the innovative "symbiotic'' regulation of the cochlear implant with an integrated hearing aid and dedicated fitting formula allows to achieve adequate rehabilitative hearing levels.

MATERIAL AND METHODS: Thirty adult patients (12 females and 18 males; age range: 18-69 years) with bimodal hearing have been enrolled in a one-year study and divided into three groups of ten subjects for each of the regulation modes ("classic", "synchronized" and "symbiotic") applied to fit the cochlear implant and the hearing aid. Statistical analysis of the demographic characteristics and hearing outcomes observed in the three groups was conducted using the R statistical software.

RESULTS: For all subjects, the use of the "symbiotic" regulation approach with a dedicated bimodal regulation formula and integrated hearing aid allowed significantly better hearing performances (p < 0.05) compared to those obtained to either the "classic" or the "synchronized" regulations.

CONCLUSION: The "symbiotic" bimodal fitting formula provides significant hearing benefits compared to "classic" and "synchronized" regulation and it proves to be the ideal adjustment and coupling modality between a cochlear implant and a contralateral integrated hearing aid in bimodal listeners.

RevDate: 2025-05-26
CmpDate: 2025-05-27

Wu Z, Dunlop JA, Klimov PB, et al (2025)

A new whip scorpion (Arachnida: Thelyphonida) with a phoretic mite (Acariformes: Trochometridiidae) from Mid-Cretaceous Kachin amber.

BMC ecology and evolution, 25(1):55.

BACKGROUND: Mid-Cretaceous Kachin amber is a valuable resource for studying the diversity, evolution, and ecology of microarthropods, including arachnids. Its exceptional preservation offers a unique opportunity to uncover biological associations between organisms with high fidelity. Whip scorpions (Thelyphonida) are rare in the fossil record, with a few known from the Paleozoic era and Cretaceous period. However, the ecological interactions of these fossils with other organisms remain largely unexplored.

RESULTS: Here, we describe a new whip scorpion species, Mesothelyphonus xiaoae sp. nov., from Kachin amber. This species is diagnosed by its relatively small body size, an accessory tooth on the pedipalp coxal apophysis, six teeth on the pedipalpal trochanter, and an unmodified abdominal sternite III. Notably, the fossil includes a heterostigmatic mite (Acariformes: Prostigmata: Heterostigmata: Trochometridiidae) attached to the first leg of the whip scorpion. The mite appears to have selected a densely setose area on a limb primarily used for sensory purposes by the host, which may have made it more difficult to dislodge. This association likely represents an instance of phoresy, where the mite benefits from transportation and protection provided by the whip scorpion.

CONCLUSION: Based on modern knowledge of Trochometridium biology and host associations, we suggest that while the whip scorpion served as an incidental host, the primary host was likely a ground-nesting Apoidea (bees or wasps). This hypothesis implies that Mid-Cretaceous ecosystems included early apoids exhibiting nesting behavior, providing an essential niche for the development of this ancient symbiosis.

RevDate: 2025-05-26

Srivastava AK, Riaz A, Jiang J, et al (2025)

Advancing Climate-Resilient Sorghum: the Synergistic Role of Plant Biotechnology and Microbial Interactions.

Rice (New York, N.Y.), 18(1):41.

Climate-related problems such as drought stress, extreme temperature, erratic rainfall patterns, soil degradation, heatwaves, flooding, water logging, pests and diseases afflict the production and sustainability of sorghum. These challenges may be addressed by adopting climate-resilient practices and using advanced agronomic techniques. These challenges are being addressed through innovative applications of plant biotechnology and microbiology, which offer targeted solutions to enhance sorghum's resilience. For instance, biotechnological tools like CRISPR/Cas9 enable precise genetic modifications to improve drought and heat tolerance, while microbial inoculants, such as plant growth-promoting rhizobacteria (PGPR) and arbuscular mycorrhizal fungi (AMF), enhance nutrient uptake and stress tolerance through symbiotic interactions. However, biotechnological tools lead to the development of sorghum varieties with heat, drought and salinity tolerance, while marker-assisted selection significantly accelerates breeding for stress-resilient traits. When genetic engineering is introduced, genes encoding heat shock proteins, Osmo protectants and antioxidant pathways are introduced to increase plant resistance to abiotic stress. These compounds stabilise cellular structures, protect enzymes, and maintain osmotic balance, enhancing the plant's ability to survive and function in adverse environmental conditions. At the same time, it is reported that microbiology offers beneficial microbes, nitrogen-fixing bacteria, phosphate-solubilizing microorganisms, and arbuscular mycorrhizal fungi that help enhance nutrient availability, soil health and water uptake. Combinations of endophytes and microbial inoculants enhance plant immunity to pests and diseases while increasing tolerance to stress. Biocontrol agents such as Bacillus and Trichoderma contain suppression of pathogens and need less dependence on the use of chemical pesticides. On top of that, genetic modification increases the nutritional quality of sorghum biofortified. This is where biotechnology and microbiology work together to deliver sustainable farming systems reducing environmental impacts, boosting yields and securing food supply under environmental stresses. This review aims to examine the synergistic integration of plant biotechnology and microbial interactions as a strategy to enhance sorghum's resilience to climate-induced stresses, including drought, elevated temperatures, and nutrient-deficient soils. It highlights recent advancements in biotechnological tools such as gene editing, marker-assisted selection, and tissue culture, alongside the emerging role of plant-beneficial microbes in promoting stress tolerance and improving soil health. By synthesizing current knowledge across these disciplines, this review seeks to outline a framework for future research that harnesses the intersection of biotechnology and microbial ecology to support the sustainable improvement of sorghum resilience.

RevDate: 2025-05-26

Ranner JL, Stabl G, Martyniak C, et al (2025)

Comprehensive Quantification of (Poly)phenols in Lotus japonicus with and without Arbuscular Mycorrhizal Symbiosis.

Journal of agricultural and food chemistry [Epub ahead of print].

In the present study, a highly specific, accurate, and robust ultrahigh-performance liquid chromatography-tandem mass spectrometry (UHPLC-MS/MS) method for the simultaneous quantification of 50 plant (poly)phenol analytes was developed and validated to assess the effect of arbuscular mycorrhizal (AM) symbiosis on the (poly)phenolic content of the model legume Lotus japonicus (L. japonicus). Determination of molar concentrations of analytes in roots and shoots of wild-type and AM mutant L. japonicus (with and without AM symbiosis, respectively) revealed an overall increase in (poly)phenols in mycorrhizal plants. Time-course observation over 10 weeks showed a shift in (poly)phenol concentrations, especially in the roots. In total, 13 analytes were notably more abundant in young AM roots, suggesting a potential role in symbiosis initiation. An accumulation of various (poly)phenols at later stages of symbiosis might indicate a potential involvement in arbuscule degradation or AM autoregulation.

RevDate: 2025-05-26

Han J, Wang F, Dmitrii D, et al (2025)

Effects of arbuscular mycorrhizal fungi on root architecture and ultrastructure of Hordeum jubatum under the interactive impact of nitrogen deposition and cold stress.

Plant biology (Stuttgart, Germany) [Epub ahead of print].

Hordeum jubatum L. is a perennial herb with high ornamental value and strong stress tolerance. Nitrogen deposition and cold stress are key environmental factors that affect stability of ecosystems in cold regions of northeast China. These factors significantly affect plant growth and development. Arbuscular mycorrhizal fungi (AMF) are symbiotic soil fungi that can increase plant resistance and growth. However, research on impacts of nitrogen deposition and cold stress on roots of H. jubatum-AM symbionts remains limited. Root biomass (dry and fresh weight), architecture (length, surface area, volume, forks, number of fourth-order roots, and root fractal dimension), and ultrastructure of H. jubatum were assessed, both in the presence and absence of AMF, under conditions of nitrogen deposition and cold stress. Cold stress inhibited all indicators of root architecture and disrupted root ultrastructure, with greater inhibition shown in the N2 (NH4 [+]/NO3 [-] = 1:1) treatment under cold stress, indicating nitrogen deposition increased sensitivity of H. jubatum to cold stress. Inoculation with AMF significantly reduced damage caused by nitrogen deposition and cold stress on H. jubatum roots compared with the non-inoculation treatment. Our results demonstrate different effects of the interaction of nitrogen deposition and cold stress versus single stress (nitrogen deposition or cold stress) on plant root development and provide a scientific basis for the use of mycorrhizal technology to improve resistance and productivity of cold-tolerant plants in cold regions under stress conditions.

RevDate: 2025-05-27

Anonymous (2025)

Correction to "Identification of Novel Candidate Genes Associated With the Symbiotic Compatibility of Soybean With Rhizobia Under Natural Conditions".

Plant direct, 9(5):e70083.

[This corrects the article DOI: 10.1002/pld3.70069.].

RevDate: 2025-05-27

Karugu JC, Kimuyu DM, Kenfack D, et al (2025)

Influence of Myrmecophytic Acacia drepanolobium on the Composition and Growth of Surrounding Herbaceous Vegetation.

Ecology and evolution, 15(5):e71500.

Whistling thorn acacia (Acacia (Vachellia) drepanolobium) forms nearly monospecific stands among woody species in black cotton soils in East Africa arid highlands. The tree defends itself against large mammal herbivores with spinescence and symbiotic ants. While these defenses have been extensively studied, little is known about the extent to which A. drepanolobium defense may benefit other plants growing in close association. We examined variation in herbaceous vegetation height, biomass, and composition between areas underneath A. drepanolobium canopies and the adjacent matrix in both fenced herbivore exclosures and unfenced areas. In unfenced areas, there was more tall herbaceous vegetation and biomass underneath tree canopies than away from tree canopies, while these differences were not significant in fenced exclosures. Both height and biomass of understory vegetation were negatively correlated with A. drepanolobium canopy height. Species richness was higher underneath tree canopies in both fenced and unfenced locations. In the unfenced locations, species evenness was lower underneath tree canopies than in the surrounding matrix, but the opposite was true in the fenced herbivore exclosures. The differences in herbaceous vegetation composition (Bray-Curtis dissimilarity index) between underneath tree and off tree locations were more pronounced in the unfenced areas than within the fenced herbivore exclosures. Our findings suggest that highly defended trees may moderate herbivore effects on herbaceous vegetation. To the extent that herbaceous vegetation underneath trees experiences protection from herbivory, such refugia microhabitats may serve as recolonization nuclei in attempts to restore chronically overgrazed systems.

RevDate: 2025-05-26

Koop JAH, NW Blackstone (2025)

Synergy, complexity, and the dirty, dirty cheats of the world.

Biological reviews of the Cambridge Philosophical Society [Epub ahead of print].

Studies of symbiosis employ the term "parasitism" to connote different sorts of relationships. Within the context of mutualistic symbioses, parasites are otherwise cooperative individuals or strains that appropriate a disproportionate amount of the synergistic products. In the context of antagonistic symbioses, there is no pretence of cooperation, and instead parasites are defined as individuals or strains that derive fitness benefits at a fitness cost to their hosts. In both cases, parasitism is selected for at the lower level (that of the individual symbiont) but selected against at the higher level (the group of symbionts in a single host). Despite these similarities, these different sorts of parasitism likely evolve by different pathways. Once a host-symbiont relationship initiates, if functional synergy is lacking, the relationship will remain exploitative, although parasites may differ in their detrimental effects on the host and the higher-level unit. If functional synergy is present, however, cooperation may develop with benefits for both host and symbionts (i.e. mutualism). Nevertheless, parasites may still evolve from within these incipient relationships when individuals or strains of symbionts act parasitically by defecting from the common good to further their selfish replication. Levels-of-selection dynamics thus underlie both forms of parasitism, but only in the case of latent functional synergy can true symbiotic complexity at the higher level emerge.

RevDate: 2025-05-27
CmpDate: 2025-05-26

Rubia MI, Larrainzar E, C Arrese-Igor (2025)

Drought Stress Modifies the Source-Sink Dynamics of Nitrogen-Fixing Soybean Plants Prioritizing Roots and Nodules.

Physiologia plantarum, 177(3):e70276.

Soybean plants are one of the most cultivated legume crops worldwide. Their ability to establish nitrogen-fixing symbiosis with rhizobium bacteria allows the reduction of molecular nitrogen to ammonium, contributing to a reduction in the dependence on nitrogen fertilizers. However, nitrogen fixation is highly sensitive to environmental stresses, such as water deficit, and the regulatory mechanisms underlying this inhibition remain debatable. In the current study, we analyzed carbon (C) allocation dynamics in drought-stressed soybean plants following the application of [U-[13]C]-sucrose to source leaves. Three sets of plants were analyzed: well-watered plants, mild drought, and severe drought-stressed plants. [13]C distribution was monitored for up to 6 h post-application. Under optimal water conditions, [13]C was mainly allocated to young (sink) leaves. During drought stress, transport trends changed, prioritizing C allocation primarily to the roots and nodules to a lesser extent. Metabolite profiling identified drought- and tissue-specific variations in the levels of the major C and N compounds.

RevDate: 2025-05-25

Yamamoto S, Shimomura A, Watanabe S, et al (2025)

Overwhelming glycyrrhizin production in Glycyrrhiza glabra induced by rihizobial symbiosis.

Journal of natural medicines [Epub ahead of print].

We reported that Glycyrrhiza uralensis inoculated with rhizobium tended to increase biomass production and glycyrrhizic acid (GL) production, in this study we have also achieved drastically increase in biomass and GL production in Glycyrrhiza glabra. At thirty days after inoculation (DAI), a significant increase in SPAD values was observed, and the expression of GL synthesis marker genes was also significantly increased. At 150 DAI, a significant increase in biomass was observed. Characteristically, it was also found that thick roots were enlarged by rhizobial inoculation. In addition, the expression of GL synthesis marker genes was also significantly increased. Moreover, GL content per unit root dry weight reached 4%, and GL production per plant increased six times compared to uninoculated plants. Moreover, we tried to reveal the mechanism of induction of GL production by rhizobial inoculation. Since it has been reported that the expression of jasmonic acid (JA) synthesis marker genes is increased by rhizobium in soybean, we investigated the expression of those genes in G. glabra, and found that GgMYC2 and GgJAR1 were up-regulated at Thirty DAI. Furthermore, methyl jasmonate treatment increased the expression of GL synthesis marker genes, suggesting that JA signaling is involved in the increased GL production due to rhizobial inoculation. These results aid in understanding the mechanism of increased GL production through the introduction of rhizobial symbiosis, and show the potential for providing a technology to significantly shorten the cultivation period for the production of Glycyrrhiza that meets the criteria for herbal medicines.

RevDate: 2025-05-25
CmpDate: 2025-05-25

Alviti Kankanamalage HP, Yang JY, Karunarathna SC, et al (2025)

Entomopathogenic fungi: insights into recent understanding.

World journal of microbiology & biotechnology, 41(6):179.

Entomopathogenic fungi (EPF) are cosmopolitan, obligate, or facultative pathogens that show ruthless aggression toward various insects and ultimately cause them to die. They also have the ability to colonize and establish symbiotic relationships with plants as endophytes, thus offering a number of benefits to the host plants, inducing plant resistance against a number of biotic and abiotic stresses, and growth promotion. Recently, considerable attention has been paid to this group of fungi, mainly due to their exceptional ability to control numerous arthropod pests in crops. This practical application of EPF, which is of great interest, offers an eco-friendly manner of pest control, a key feature that makes them a potential solution to growing environmental concerns. This eco-friendly nature of EPF is particularly significant in the current context of growing environmental concerns and the need for sustainable solutions. This paper has attempted to review our current understanding of EPF. First, we briefly describe the historical identifications of EPF, landmark studies, and their classifications. Second, we discuss the group from an evolutionary standpoint. Third, the insect infection mechanisms, particularly the cuticular penetration pathway and different steps, are discussed. Finally, we emphasize the eco-friendly nature of these fungi, which makes them a sustainable option to mitigate the devastating effects of insect pests in current agriculture systems.

RevDate: 2025-05-25

Chen C, Shi Y, Chen B, et al (2025)

Understanding diurnal variability in organic matter processing by microalgal-bacterial granular sludge in lake water remediation.

Bioresource technology pii:S0960-8524(25)00683-2 [Epub ahead of print].

This study investigates the diurnal variability of organic matter removal by microalgal-bacterial granular sludge (MBGS) in lake water remediation. Results showed that daytime removal efficiencies for NH4[+]-N, NO3[-]-N, NO2[-]-N, TN, and TP reached 72.1%, 73.2%, 91.5%, 60.5%, and 52.8%, respectively, exceeding nighttime values of 52.7%, 55.8%, 88.4%, 37.9%, and 39.9%. However, chemical oxygen demand (COD) exhibited a net release during daylight, contrasting with removal during night conditions. Significant microbial community shifts, notably increased Bacteroidota abundance, were driven by fluctuations in dissolved oxygen and organic carbon levels. Additionally, the upregulation of fatty acid metabolism-related genes like paaF and ACSL mechanistically supported COD removal efficiency. These findings suggest that optimizing MBGS operation through diurnal parameter regulation can enhance lake restoration efficacy and provide a theoretical foundation for developing sustainable engineering strategies in aquatic ecosystem management.

RevDate: 2025-05-27
CmpDate: 2025-05-25

Hashimoto R, Nishiyama K, Namai F, et al (2025)

Milk sialyl-oligosaccharides mediate the early colonization of gut commensal microbes in piglets.

Microbiome, 13(1):135.

BACKGROUND: The suckling period in pigs is a key phase in development for shaping the gut microbiota, which is essential for maintaining biological homeostasis in neonates. In piglets fed sow milk, the gut microbiota comprises predominantly lactobacilli, indicating a host-gut microbiota symbiosis that is influenced by sow milk components. In this study, we sought to elucidate the mechanisms underlying the establishment and maintenance of the gut microbiome in suckling piglets, with a specific focus on the metabolism of sialyl-oligosaccharides by lactobacilli.

RESULTS: Based on liquid chromatography-mass spectrometry analysis, we identified 3'-sialyl-lactose (3'SL) as the major oligosaccharide in porcine milk, and microbiome profiling revealed the predominance of Ligilactobacillus salivarius during the suckling period, with a subsequent transition to Limosilactobacillus reuteri dominance post-weaning. Notably, sialic acid metabolism was established to be exclusively attributable to L. salivarius, thereby highlighting the pivotal role of 3'SL in determining species-specific bacterial segregation. L. salivarius was found to metabolize 3'SL when co-cultured with Bacteroides thetaiotaomicron, resulting in a shift in the predominant short-chain fatty acid produced, from lactate to acetate. This metabolic shift, in turn, inhibits the growth of enterotoxigenic Escherichia coli. Furthermore, the comparison of the gut microbiota between suckling piglets and those fed a low-3'SL formula revealed distinct diversity profiles. We accordingly speculate that an absence of sialyl-oligosaccharides in the formula-fed piglets may have restricted the growth of sialic acid-utilizing bacteria such as L. salivarius, thereby leading to a higher abundance of Enterobacteriaceae.

CONCLUSIONS: Our findings reveal the influence of sialyl-oligosaccharides in promoting microbial diversity and gut homeostasis, thereby highlighting the importance of sialic acid as a key factor in shaping milk-driven microbial colonization during the early stages of piglet development. Video Abstract.

RevDate: 2025-05-24
CmpDate: 2025-05-24

Mahto RK, Chandana BS, Singh RK, et al (2025)

Uncovering potentials of an association panel subset for nitrogen fixation and sustainable chickpea productivity.

BMC plant biology, 25(1):693.

BACKGROUND: Chickpea (Cicer arietinum L.) is a nutritious legume that fixes atmospheric nitrogen through Rhizobium symbiosis, enhancing growth and yield. Sustainable agriculture is essential to address food security, climate change, and environmental sustainability. Plant Growth-Promoting Rhizobacteria (PGPR) improve crop productivity, reduce chemical fertilizer use, and support eco-friendly farming. This study highlights PGPR's role in enhancing chickpea yield, resilience, and resource efficiency while minimizing environmental impacts. PGPR reduces chemical dependency, preserves ecosystems, and supports global sustainability goals. Findings demonstrate PGPR's potential to improve food security and promote equitable distribution. This research offers innovative strategies for advancing sustainable agriculture.

RESULTS: The study revealed significant variability in nodulation, nitrogen fixation, and yield among 20 chickpea genotypes under different treatments, including Rhizobium, vesicular-arbuscular mycorrhiza (VAM), and chemical fertilizers (NPK), applied alone and in combinations. Genotype ICC9085 consistently outperformed others, exhibiting the highest nodules per plant (22.67), nitrogen content (3.65%), and protein content (22.85%), while ICC1083 and ICC6579 showed minimal nodulation (< 5 nodules). Rhizobium treatment proved the most effective, achieving the highest nitrogenase activity (mean: 35.806; max: 189.2) and yielding superior growth-promoting results compared to VAM and control treatments. Molecular genotyping identified 20 out of 128 SSR markers as polymorphic, with an average polymorphic information content (PIC) of 0.35 and two alleles per marker, revealing moderate polymorphism and significant genetic diversity. Cluster analysis grouped the genotypes into four primary clusters, reflecting geographical and genetic diversity in nodulation traits. Environmental factors such as soil nutrients, temperature, and water stress, alongside genetic traits like root architecture and nitrogen-fixing efficiency, contributed to variations in growth and productivity. This interplay of genotype and environment underscores the adaptability and superior performance of certain varieties like ICC9085 under specific conditions.

CONCLUSION: These observations suggest that the identified superior genotypes can be used to introduce desirable traits into allied chickpea cultivars through marker-assisted selection and crop improvement programs.The research of the chickpea, a crop with significant agricultural and industrial value, will eventually help develop efficient methods for the production of climate-smart food crops to meet the food and feed needs of future generations for a sustainable environment.

RevDate: 2025-05-24

Glazer I, Simões N, Eleftherianos I, et al (2025)

Entomopathogenic nematodes: Survival, virulence and immunity.

Journal of invertebrate pathology pii:S0022-2011(25)00097-7 [Epub ahead of print].

As entomopathogenic nematodes (EPNs) are used as biological control agents, their survival and persistence are crucial to ensure success in application against insect pests. The survival of Heterorhabditis and Steinernema species is dependent on abiotic and biotic factors in the environment. Abiotic stress environments such as desiccation, temperature, and ultraviolet radiation (UV) severely impact their performance on field. EPNs produce and secrete effector molecules during the early stages of infection to interfere with the molecular mechanisms that control the insect innate immune function. Also, EPN effectors facilitate the subsequent release and spread of their symbiotic bacteria within the host. Hence, a comprehensive understanding of the underlying survival and virulence mechanisms enabling protection against environmental conditions and insect host immune responses is imperative to realistically enhance their performance on field. Thus, identifying key players regulating EPN survival, virulence and immunity could invariably contribute towards developing more robust, reliable solutions and application strategies including genetic tools and formulation technologies.

RevDate: 2025-05-24

Xie Y, Wang R, Wu Z, et al (2025)

Prophylactic application of sodium new houttuyfonate to regulate macrophage activation and antifungal infection in intra-abdominal candidiasis model mice.

International immunopharmacology, 159:114922 pii:S1567-5769(25)00912-9 [Epub ahead of print].

The abuse of immunosuppressants causes damage to the immune system, while the pathological proliferation and translocation of symbiotic Candida albicans can result in abdominal infection in immunocompromised people. In this study, we established a mouse peritoneal C. albicans infection model and investigated the effects of preventive application of Sodium New Houttuyfonate (SNH) by analyzing the proportion of immune cells, polarization of peritoneal macrophages, changes in fungal tissue load, and histology, and the data showed prophylactic SNH administration yields a double anti-infection effect in phagocytosis and regulation of immunity according to the immune inflammatory states of the body. In vitro, neutral red, colony counting, cytometric bead array, RT-qPCR, western blot, inhibitor treatment, and detection of reactive oxygen species (ROS) and nitric oxide (NO) production on RAW264.7 macrophages showed SNH can stimulate the production of tumor necrosis factor-alpha (TNF-α) and CC motif ligand 2 (CCL2) and the release of ROS and NO through a TLR2/p38/NF-κB pathway. Taken together, our data provide an innovative insight into the prevention use of exogenous SNH for the treatment of C. albicans infection.

RevDate: 2025-05-26
CmpDate: 2025-05-24

Onsun B, Toprak K, N Sanlier (2025)

Kombucha Tea: A Functional Beverage and All its Aspects.

Current nutrition reports, 14(1):69.

PURPOSE OF REVIEW: The increasing interest in functional foods and beverages worldwide is driven by rising living standards, advancing technology, and heightened health awareness. Kombucha tea, a fermented beverage produced from sweetened tea and a symbiotic culture of bacteria and yeast (SCOBY), is a prominent example within this category. This review explores the definition, bioactive components, and health benefits of kombucha, emphasizing its potential roles as a functional beverage in the prevention and management of various diseases.

RECENT FINDINGS: The fermentation process of kombucha tea, typically lasting up to 14 days, results in the transformation of sugar into ethanol and acetic acid, contributing to its distinctive tangy flavor. Kombucha contains bioactive compounds such as organic acids, antioxidants, and probiotics, which are linked to potential health benefits including improved digestive health, enhanced immune function, and antioxidant activity. Recent advancements in sustainable production methods and innovative formulations have further contributed to the increasing popularity of this beverage. Kombucha tea, originating in Northeast China with a history of over 2,000 years, is increasingly recognized for its potential health-promoting effects. Its production through traditional fermentation methods combined with modern innovations underscores its value as a functional beverage with the potential to support health and well-being. This review assesses the roles of kombucha in maintaining human health, considering its use as a complementary strategy for the prevention and management of diseases due to the bioactive components it contains.

RevDate: 2025-05-26
CmpDate: 2025-05-24

Nakajima M, Tanaka N, Motouchi S, et al (2025)

New glycoside hydrolase families of β-1,2-glucanases.

Protein science : a publication of the Protein Society, 34(6):e70147.

β-1,2-Glucans are natural glucose polymers produced by bacteria and play important physiological roles, including as symbiotic or pathogenic factors and in osmoregulation. Glycoside hydrolase (GH) families related to β-1,2-glucan metabolism (GH144, GH162, and GH189) have recently been created by identification of two β-1,2-glucanases and a β-1,2-glucanotransferase, respectively. In this study, we further found four phylogenetically new groups with unknown functions (Groups 1-4) by sequence database analysis using enzymes from GH144 and GH162 as queries. Biochemical analysis of representative proteins in these groups revealed that the proteins in Groups 1-3 showed hydrolytic activity specific to β-1,2-glucan, while no substrate was found for the Group 4 protein. The kinetic parameters of the enzymes of Groups 1-3 were similar to GH144 and GH162 β-1,2-glucanases, indicating that these enzymes were β-1,2-glucanases. Optical rotation analysis revealed that the β-1,2-glucanases followed an anomer-inverting mechanism. Structural analysis of the proteins in Groups 1-4 revealed that they possess (α/α)6-barrel folds similar to those of GH144, GH162, and GH189 enzymes. Comparison of spatial positions of predicted acidic catalytic residues suggested that Groups 1-3 and GH144 had the same reaction mechanism. Overall, phylogenetic, biochemical, and structural analyses revealed that Groups 1-3 are new GH families, GH192, GH193, and GH194, respectively, and that the three families belong to clan GH-S (clan GH, classification based on structural similarity) as GH144 and GH162.

RevDate: 2025-05-24

Patra A, Das Bairagya J, S Chakraborty (2025)

Bayesian ecoevolutionary game dynamics.

Physical review. E, 111(4-1):044401.

The symbiotic relationship between the frameworks of classical game theory and evolutionary game theory is well established. However, evolutionary game theorists have mostly tapped into the classical game of complete information where players are completely informed of all other players' payoffs. Of late, there is a surge of interest in ecoevolutionary interactions where the environment's state is changed by the players' actions which, in turn, are influenced by the changing environment. However, in real life, the information about the true environmental state must pass through some noisy channel (like the usually imperfect sensory apparatus of the players) before it is perceived by the players: The players naturally are prone to sometimes perceive the true state erroneously. Given the uncertain perceived environment, the players may adopt bet-hedging kind of strategies in which they play different actions in different perceptions. In a population of such ill-informed players, a player would be confused about the information state of her opponent, and an incomplete information situation akin to a Bayesian game surfaces. In short, we contemplate the possibility of the natural emergence of the symbiotic relationship between the frameworks of Bayesian games and ecoevolutionary games when the players are equipped with inefficient sensory apparatus. Herein, we illustrate this connection using a setup of infinitely large, well-mixed population of players equipped with two actions for exploiting a resource (the environment) at two different rates so that the resource state evolves accordingly. The state of the resource impacts every player's decision of playing particular action. We investigate the continuous state environment in the presence of a Gaussian noisy channel. Employing the formalism of deterministic replicator dynamics, we find that noisy information can be effective in preventing the resource from going extinct.

RevDate: 2025-05-25

Yin H, Shan Y, Zhu Q, et al (2025)

Improved VPS4B O-GlcNAc modification triggers lipid droplets transferring from adipocytes to nasopharyngeal carcinoma cells.

Cancer & metabolism, 13(1):24.

BACKGROUND: The tumor microenvironment (TME) supplies critical metabolites that support cancer cell survival and progression. Adipocytes support tumor progression by secreting free fatty acids (FFAs) and adipokines; however, the role and mechanisms underlying lipid droplet (LD) release from adipocytes remain elusive.

METHODS: Using two nasopharyngeal carcinoma (NPC) cell lines and primary human pre-adipocytes (HPA), we evaluate the effect of LDs on cell growth, proliferation, colony formation, and migration. We also assess the roles of LD on the tumor progression in vivo. Using RNA-seq analysis, we elucidate the effect of hypoxic NPC cell-derived exosomes (H-exo) on the gene expression profile of adipocytes. By co-culture system, we investigated the effect of vacuolar protein sorting 4 homolog B (VPS4B)-annexin A5 (ANXA5) interaction on adipocyte LD maturity and release.

RESULTS: Herein, we report that LDs, rather than FFAs, are the primary lipid form transferred from adipocytes to NPC cells, enhancing cancer progression. NPC cells internalize LDs directly via macropinocytosis, while H-exo induces oxidative stress and membrane fluidity in adipocytes, leading to LD release. Transcriptomic and proteomic analyses reveal that VPS4B triggers LD release by interacting with ANXA5, and low LKB1 in H-exo enhances VPS4B O-linked N-acetylglucosamine (O-GlcNAc) modification through the inhibition of serine/threonine kinase 11 (STK11/LKB1)-AMP-activated protein kinase (AMPK) pathway and activation of the hexosamine biosynthesis pathway (HBP) flux.

CONCLUSIONS: This study uncovers critical mechanisms of LD transfer in the TME, suggesting new therapeutic avenues in NPC.

RevDate: 2025-05-25
CmpDate: 2025-05-24

Chu B, Ge S, He W, et al (2025)

Gut symbiotic bacteria enhance reproduction in Spodoptera frugiperda (J.E. Smith) by regulating juvenile hormone III and 20-hydroxyecdysone pathways.

Microbiome, 13(1):132.

BACKGROUND: The insect gut microbiota forms a complex, multifunctional system that significantly affects phenotypic traits linked to environmental adaptation. Strong reproductive potential underpins the migratory success, population growth and destructive impact of the fall armyworm, Spodoptera frugiperda (J.E. Smith). However, the precise role of gut bacteria in S. frugiperda reproductive processes, distribution and transmission dynamics remains unclear.

RESULTS: We examined the gut microbiota of S. frugiperda a major invasive agricultural pest, identifying Enterococcus, Enterobacter, and Klebsiella as core microorganisms present throughout its life cycle. These microbes showed heightened activity during the egg stage, early larval stages and pre-oviposition period in females. Using an axenic insect re-infection system, Enterococcus quebecensis FAW181, Klebsiella michiganensis FAW071 and Enterobacter hormaechei FAW049 were found to significantly enhance host fecundity, increasing egg production by 62.73%, 59.95%, and 56.71%, respectively. Metagenomic and haemolymph metabolomic analyses revealed a positive correlation between gut symbiotic bacteria and hormone metabolism in female S. frugiperda. Further analysis of metabolites in the insect hormone biosynthesis pathway, along with exogenous injection of juvenile hormone III and 20-hydroxyecdysone, revealed that gut microbes regulate these hormones, maintaining levels equivalent to those in control insects. This regulation supports improved fecundity in S. frugiperda, aiding rapid colonization and population expansion.

CONCLUSIONS: These findings emphasize the pivotal role of gut bacteria E. quebecensis FAW181, E. hormaechei FAW049, and K. michiganensis FAW071 in enhancing S. frugiperda reproduction by modulating JH III levels through JHAMT regulation and concurrently modulating the levels of 20E and its precursors via PHM. Our results provide novel insights into microbe-host symbiosis and pest management strategies for alien invasive species. Video Abstract.

RevDate: 2025-05-26
CmpDate: 2025-05-23

Eftekhari F, Sarcheshmehpour M, Lohrasbi-Nejad A, et al (2025)

Effects of mycorrhizal and Trichoderma treatment on enhancing maize tolerance to salinity and drought stress, through metabolic and enzymatic evaluation.

BMC plant biology, 25(1):687.

BACKGROUND: Nowadays, climate change has intensified environmental stresses, including salinity and drought stress. Salinity and drought significantly impair crop growth and yield by affecting physiological and biochemical processes. One of the ways to enhance environmental stress tolerance in plants is to improve their symbiotic relationships with soil microorganisms. This study investigates the impact of arbuscular mycorrhizal fungi (AMF) and Trichoderma harzianum (accession number: PV544806) inoculation on maize to trace the activated pathways under stress conditions. Maize plants were exposed to different stress conditions: salinity (S1D0), drought (S0D1), and a combination of both salinity and drought (S1D1). They received treatments with arbuscular mycorrhizal fungi (AMF) (M1T0), Trichoderma (M0T1), and a combination of both (M1T1).

RESULTS: Inoculation of maize plants with AMF and T. harzianum markedly enhanced root dry weight, root volume, and total biomass under stress conditions. Additionally, the simultaneous inoculation of AMF and T. harzianum under combined salinity and drought conditions significantly affected traits such as dry weight of aerial parts, total biomass, and root colonization percentage compared to the non-inoculated control. Physiologically, the results also indicated that the inoculation significantly increased the activity of antioxidant enzymes SOD and APX. Results from GC-MS analysis and metabolic pathway analysis showed that the combined inoculation of AMF and Trichoderma in maize plants stimulated the production of specific secondary metabolites such as oxaloacetate, Δ1-piperidine-6-carboxylate, and cadaverine under stress conditions.

CONCLUSIONS: Based on this study's findings, the use of AMF and T. harzianum can enhance maize growth and performance under salinity and drought stress by stimulating the production of secondary metabolites.

RevDate: 2025-05-26
CmpDate: 2025-05-23

Hu J, Chen T, Lian CA, et al (2025)

Deciphering factors influencing planktonic and sedimentary microbial assembly processes in Midwest salinity lakes.

Applied microbiology and biotechnology, 109(1):124.

The salt lake ecosystem, characterized by extreme environmental gradients, harbors microbes that uniquely adapt to high salt stress through natural selection. However, how abiotic and biotic factors shape the microbial community assembly in Yuncheng Salt Lakes remains unclear. Here, we investigated the assembly processes and meta co-occurrence patterns of microbiota in both water and sediment sampled from 14 distinct wide range of salinity lakes in the Shanxi Yuncheng area, Midwest of China, using 16S rRNA and 18S rRNA gene sequencing technology combined with multivariate ecological and statistical methods. Habitat differentiation led to the differences in microbial diversity, co-occurrence patterns, and community assembly between sedimentary and planktonic communities. Sedimentary prokaryotes were more shaped by deterministic processes than planktonic bacterial communities. Salinity was a major abiotic factor influencing the balance between stochastic and deterministic processes in both sediment and water. Enhanced microbial interactions within sediments exhibited a more prominent impact in shaping community assembly, as indicated by the stronger association between network-inferred species and prokaryotic βNTI. Moreover, we revealed significant differences in how core species concerning βNTI responded to biotic and abiotic factors. Our findings elucidated the ecological process underlying microbial communities in Yuncheng Salt Lakes and shed light on the mechanism of microorganisms to maintain community complexity and diversity in the extreme environment. KEY POINTS: • Sedimentary prokaryotes were more shaped by deterministic processes than planktonic prokaryotic communities. • Salinity was a major factor influencing the balance between stochastic and deterministic process. • Inter-domain and intra-domain symbiotic interactions within sedimentary communities represent key biotic factors influencing their community assembly.

RevDate: 2025-05-23

Yang YQ, Li X, Wang ZZ, et al (2025)

Single cell protein production of co-culture Kodamaea ohmeri and Lactococcus lactis in corn straw hydrolysate.

Bioresource technology pii:S0960-8524(25)00615-7 [Epub ahead of print].

With the world population continuously increasing, the protein demand will double by 2050. Single cell protein (SCP) derived from lignocellulosic biomass offers a sustainable solution. Many inhibitors are produced during the pretreatment process of lignocellulosic biomass. Inhibitor-rich hydrolysates limit microorganisms cell growth and SCP yields. In this work, we report a co-culture consortium of Kodamaea ohmeri SSK (pentose-utilizing yeast) and Lactococcus lactis LX (probiotic bacterium) that efficiently converts real corn straw hydrolysate into SCP. K. ohmeri SSK can tolerate inhibitors such as furfural, 5-hydroxymethylfurfural (5-HMF), and acetic acid and consume glucose, xylose, and arabinose in real hydrolysate. L. lactis LX showed less growth in monoculture than that of co-culture. The total amino acid content from co-cultured K. ohmeri SSK and L. lactis LX was increased to 331.42 mg/g crude protein, but that of monocultured K. ohmeri SSK was 309.89 mg/g crude protein containing 17 amino acids. This work demonstrates a symbiotic microbial platform can produce SCP from non-detoxified lignocellulosic biomass. The co-culture robust inhibitor tolerance and balanced amino acid profile highlight its potential for industrial-scale protein production. These results will represent an attractive choice cell factory for lignocellulosic substrate utilization and provide a platform for biomass conversion to SCP.

RevDate: 2025-05-23

Liu M, Zhou G, Zhang C, et al (2025)

Impact of Virus-Mediated Modifications in Bacterial Communities on the Accumulation of Soil Organic Carbon.

Advanced science (Weinheim, Baden-Wurttemberg, Germany) [Epub ahead of print].

Microbial adaptations to resource availability are crucial to predict the responses of ecosystems to carbon (C) changes, yet viral roles in C cycling under varying levels of C remain elusive. Through metagenomic analysis of soils with contrasting C availability, a total of 24,789 viral contigs predominantly represent Microviridae and Siphoviridae. The soils with low C availability (straw removal) harbored 21% lysogenic viruses and enriched auxiliary metabolic genes (AMGs) related to C degradation (p < 0.05). Conversely, the soils with high C availability (straw returning) show 93% lytic viruses, stronger virus-bacteria symbiosis, and numerous host functional genes related to C cycling and viral AMGs linked to C fixation (p < 0.05). Furthermore, these findings show that the addition of viruses boosted microbial metabolic efficiency and recalcitrant C accumulation (p < 0.05), with lytic activity accelerating organic C turnover via nutrient release and necromass formation. Overall, this study demonstrates viruses as key regulators of sustainable sequestration of C through host-driven metabolic optimization.

RevDate: 2025-05-23

Rawstern AH, Carbajal LJ, Slade TJ, et al (2025)

Non-Additive Interactions Between Multiple Mutualists and Host Plant Genotype Simultaneously Promote Increased Plant Growth and Pathogen Defence.

Plant, cell & environment [Epub ahead of print].

Understanding the impact of microbial interactions on plants is critical for maintaining healthy native ecosystems and sustainable agricultural practices. Despite the reality that genetically distinct plants host multiple microbes of large effect in the field, it remains unclear the extent to which host genotypes modulate non-additive microbial interactions and how these interactions differ between benign/pathogenic environments. Our study fills this gap by performing a large-scale manipulative microbiome experiment across seven genotypes of the model legume Medicago truncatula. We combine plant performance metrics, survival analyses, predictive modelling, RNA extractions and targeted gene expression to assess how host genotype and microbes non-additively interact to shape plant growth and disease ecology. Our results reveal three important findings: (1) host genotypes with high tolerance to pathogens benefit more from multiple mutualist interactions than susceptible genotypes, (2) only high-tolerance genotypes retain the same beneficial host performance outcomes from the benign environment within the pathogenic environment and (3) the quality of the symbiotic relationship with mutualists is a strong predictor of host survival against pathogenic disease. By applying these findings towards developing crops that promote synergistic microbial interactions, yields and pathogen defence could be simultaneously increased while reducing the need for toxic fertilisers and pesticides.

RevDate: 2025-05-23

Zhang S, Wang Z, Liu A, et al (2025)

Hosts and Commensal Bacteria Synergistically Antagonize Opportunistic Pathogens at the Single-Cell Resolution.

Advanced science (Weinheim, Baden-Wurttemberg, Germany) [Epub ahead of print].

Natural microbes coexist in a diverse species population with competition for space and nutrient resources. However, the molecular mechanisms underpinning the regulatory networks of microbes among themselves and with their host are still in infancy. Here, it is reported that Drosophila and the commensal Lactiplantibacillus plantarum form an alliance to compete with the pathogenic Serratia marcescens using the integrated three-species model system. In the dual-species model, larvae diminish the L. plantarum population, but reversibly increase lactate production through altering its transcriptional reprogramming. In the tripartite-species model, larvae facilitate the growth of L. plantarum that confers colonization resistance against S. marcescens. On the other hand, S. marcescens launches sophisticated arms race strategies to impair colonization resistance by sensing lactate derived from L. plantarum. More importantly, the S. marcescens population challenged with Drosophila and L. plantarum adaptively diverge into virulent and reduced virulence subclusters with an increase in resistance heterogeneity. To form the alliance with Drosophila, heterogeneity in lactate generation is broadened among L. plantarum subpopulations. Altogether, these findings provide an insight into the host-commensal-pathogen symbiosis at both bulk and single-cell resolutions, advancing fundamental concepts of precise manipulation of bacterial communities.

RevDate: 2025-05-25

Tong A, Liu W, Liu X, et al (2025)

Comparative analysis of actinorhizal nodule and associated soil microorganism diversity and structure in three Alnus species.

Frontiers in plant science, 16:1572494.

BACKGROUND: Due to the importance of biological nitrogen fixation in terrestrial ecosystems, actinorhizal symbiosis has attracted more and more attention. Alders (Alnus) are important actinorhizal plants, but little is known about the diversity of symbiotic microbiota in the actinorhizal nodules. In addition, it remains unclear about the influence of the host species and habitats on the microbial community of alder root nodules and rhizospheric soils.

METHODS: In this study we sequenced the hyper-variable regions of the 16S rRNA from the root nodules and their rhizosphere soils of three alder species (Alnus mandshurica, A. sibirica, A. japonica) in northeastern China to explore the diversity, composition, network association, and nitrogen cycling pathway of the microbial communities in the actinorhizal nodules and associated soils.

RESULTS: The results showed that the microbial community α-diversity decreased significantly from the associated soil to the root nodule, and the microbial diversity in the root nodule of A. sibirica was not affected by the habitats. The dominant microbe genus in alder nodules was Frankia, whose abundance was significantly higher than that in associated soil samples. Furthermore, the abundance of Frankia was affected by alder tree species, but not by the habitats. The most significant taxon in the nodules of all the three alders was Frankia genus, which was negatively correlated with other six genera of microbes. The main function of microorganisms in alder nodules is nitrogen fixation, which is not affected by tree species and their habitats.

CONCLUSION: These findings suggest that the host determines the microbial community composition in the root nodule of three alders. This study provides valuable insights into the effects of alder species and habitats on the microbial communities of alder nodules and associated soils.

RevDate: 2025-05-25

Striganavičiūtė G, Vaitiekūnaitė D, Šilanskienė M, et al (2025)

Harnessing microbial allies: enhancing black alder resilience to PAH stress through microbial symbiosis.

Frontiers in plant science, 16:1552258.

Polycyclic aromatic hydrocarbons (PAHs) are persistent environmental pollutants that pose significant risks to plant health and ecosystem function. Phytoremediation, using plants in combination with microorganisms, offers a promising strategy for mitigating PAH toxicity. This study investigates the role of PAH-degrading microorganisms in mitigating the phytotoxic effects of PAHs on black alder (Alnus glutinosa L.) seedlings. Specifically, we examined the effects of three microbial strains-Pseudomonas putida Trevisan, Sphingobium yanoikuyae Yabuuchi et al., and Rhodotorula sphaerocarpa (S.Y. Newell & Fell) Q.M. Wang, F.Y. Bai, M. Groenewald & Boekhout-on plant growth and biochemical responses under exposure to naphthalene, pyrene, phenanthrene, and fluorene. The results revealed genotype-dependent variations in plant responses. In family 13-99-1K, S. yanoikuyae significantly enhanced defense mechanisms under phenanthrene exposure, evidenced by reduced malondialdehyde (MDA) levels and increased antioxidant enzyme activity. In contrast, family 41-65-7K exhibited stable shoot height and increased chlorophyll a/b ratio, but a decrease in soluble sugars under P. putida treatment with pyrene. This suggests a shift in metabolic priorities towards growth rather than stress mitigation. These findings highlight the complex interactions between plant genotype, microbial strain, and PAH type, underscoring the potential of microbial-assisted phytoremediation. Our study suggests that tailored microbial inoculants, in combination with appropriate plant genotypes, could optimize phytoremediation efforts in PAH-contaminated environments. Future research should focus on soil-based systems and longer-term evaluations to better understand the dynamics of plant-microbe-PAH interactions.

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ESP Quick Facts

ESP Origins

In the early 1990's, Robert Robbins was a faculty member at Johns Hopkins, where he directed the informatics core of GDB — the human gene-mapping database of the international human genome project. To share papers with colleagues around the world, he set up a small paper-sharing section on his personal web page. This small project evolved into The Electronic Scholarly Publishing Project.

ESP Support

In 1995, Robbins became the VP/IT of the Fred Hutchinson Cancer Research Center in Seattle, WA. Soon after arriving in Seattle, Robbins secured funding, through the ELSI component of the US Human Genome Project, to create the original ESP.ORG web site, with the formal goal of providing free, world-wide access to the literature of classical genetics.

ESP Rationale

Although the methods of molecular biology can seem almost magical to the uninitiated, the original techniques of classical genetics are readily appreciated by one and all: cross individuals that differ in some inherited trait, collect all of the progeny, score their attributes, and propose mechanisms to explain the patterns of inheritance observed.

ESP Goal

In reading the early works of classical genetics, one is drawn, almost inexorably, into ever more complex models, until molecular explanations begin to seem both necessary and natural. At that point, the tools for understanding genome research are at hand. Assisting readers reach this point was the original goal of The Electronic Scholarly Publishing Project.

ESP Usage

Usage of the site grew rapidly and has remained high. Faculty began to use the site for their assigned readings. Other on-line publishers, ranging from The New York Times to Nature referenced ESP materials in their own publications. Nobel laureates (e.g., Joshua Lederberg) regularly used the site and even wrote to suggest changes and improvements.

ESP Content

When the site began, no journals were making their early content available in digital format. As a result, ESP was obliged to digitize classic literature before it could be made available. For many important papers — such as Mendel's original paper or the first genetic map — ESP had to produce entirely new typeset versions of the works, if they were to be available in a high-quality format.

ESP Help

Early support from the DOE component of the Human Genome Project was critically important for getting the ESP project on a firm foundation. Since that funding ended (nearly 20 years ago), the project has been operated as a purely volunteer effort. Anyone wishing to assist in these efforts should send an email to Robbins.

ESP Plans

With the development of methods for adding typeset side notes to PDF files, the ESP project now plans to add annotated versions of some classical papers to its holdings. We also plan to add new reference and pedagogical material. We have already started providing regularly updated, comprehensive bibliographies to the ESP.ORG site.

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Papers in Classical Genetics

The ESP began as an effort to share a handful of key papers from the early days of classical genetics. Now the collection has grown to include hundreds of papers, in full-text format.

Digital Books

Along with papers on classical genetics, ESP offers a collection of full-text digital books, including many works by Darwin and even a collection of poetry — Chicago Poems by Carl Sandburg.

Timelines

ESP now offers a large collection of user-selected side-by-side timelines (e.g., all science vs. all other categories, or arts and culture vs. world history), designed to provide a comparative context for appreciating world events.

Biographies

Biographical information about many key scientists (e.g., Walter Sutton).

Selected Bibliographies

Bibliographies on several topics of potential interest to the ESP community are automatically maintained and generated on the ESP site.

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