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Bibliography on: Classical Genetics

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ESP: PubMed Auto Bibliography 03 Dec 2024 at 01:41 Created: 

Classical Genetics

Wikipedia: Classical genetics is often referred to as the oldest form of genetics, and began with Gregor Mendel's experiments that formulated and defined a fundamental biological concept known as Mendelian Inheritance. Mendelian Inheritance is the process in which genes and traits are passed from a set of parents to their offspring. These inherited traits are passed down mechanistically with one gene from one parent and the second gene from another parent in sexually reproducing organisms. This creates the pair of genes in diploid organisms. Gregor Mendel started his experimentation and study of inheritance with phenotypes of garden peas and continued the experiments with plants. He focused on the patterns of the traits that were being passed down from one generation to the next generation. This was assessed by test-crossing two peas of different colors and observing the resulting phenotypes. After determining how the traits were likely inherited, he began to expand the amount of traits observed and tested and eventually expanded his experimentation by increasing the number of different organisms he tested.

Created with PubMed® Query: 1890:1938[PDAT] AND (genetic OR gene OR genes OR genetics OR heredity OR inheritance OR mutation OR chromosome OR mendel) NOT pmcbook NOT ispreviousversion

Citations The Papers (from PubMed®)

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RevDate: 2021-10-20
CmpDate: 2010-06-23

Gorer PA, H Schütze (1938)

Genetical studies on immunity in mice: II. Correlation between antibody formation and resistance.

The Journal of hygiene, 38(6):647-662.

RevDate: 2021-10-20
CmpDate: 2010-06-24

Mendel DL, M Saibil (1938)

AMYLOIDOSIS OF THE ADRENALS AS A CAUSE OF ADDISON'S DISEASE.

Canadian Medical Association journal, 39(5):457-459.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Surrarrer TC (1938)

On the Inheritance and Expression of a Mottledeyed Mutant in Drosophila Melanogaster.

Genetics, 23(6):631-646.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Bauer H, Demerec M, BP Kaufmann (1938)

X-Ray Induced Chromosomal Alterations in Drosophila Melanogaster.

Genetics, 23(6):610-630.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Carlson JG (1938)

Some Effects of X-Radiation on the Neuroblast Chromosomes of the Grasshopper, Chortophaga Viridifasciata.

Genetics, 23(6):596-609.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Strong LC, Hill RT, Pfeiffer CA, et al (1938)

Genetic and Endocrine Studies on a Transplantable Carcinoma of the Ovary.

Genetics, 23(6):585-595.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Gluecksohn-Schoenheimer S (1938)

The Development of Two Tailless Mutants in the House Mouse.

Genetics, 23(6):573-584.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Whiting PW (1938)

The Induction of Dominant and Recessive Lethals by Radiation in Habrobracon.

Genetics, 23(6):562-572.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Hersh AH, F Demarinis (1938)

Bar-Eyed Mosaics in Drosophila Melanogaster.

Genetics, 23(6):548-561.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Charles DR (1938)

Studies on Spotting Patterns. IV. Pattern Variation and Its Developmental Significance.

Genetics, 23(6):523-547.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Love RM (1938)

Somatic Variation of Chromosome Numbers in Hybrid Wheats.

Genetics, 23(6):517-522.

RevDate: 2019-11-20

Hain AM (1938)

Œstrogenic and Androgenic Substances in Pregnancy.

Edinburgh medical journal, 45(10):678-691.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Chatters RM (1938)

INDUCTION BY FAST NEUTRONS OF MUTATIONS IN ANTIRRHINUM AND MYOSOTIS.

Science (New York, N.Y.), 88(2280):241-242.

RevDate: 2019-11-20

Herbst C (1938)

[Not Available].

Wilhelm Roux' Archiv fur Entwicklungsmechanik der Organismen, 138(3-4):451-464.

RevDate: 2019-11-20

Dorris F (1938)

The production of pigment in vitro by chick neural crest.

Wilhelm Roux' Archiv fur Entwicklungsmechanik der Organismen, 138(3-4):323-334.

1. Neural crest, or regions containing presumptive neural crest, from chick embryos between late primitive streak stage and 20 somites, was explanted in plasma clot cultures on depression slides, and grown for periods ranging from 3 to 14 days. 2. During the first four days in vitro, differentiation of pigment occurs, the colorless refractile granules of the cells gradually deepening in tone from yellow to deep brown or black, until large numbers of typical melanophores are present. 3. The most intense pigmentation occurred in cultures from embryos of dominant black breeds. There is an apparent positive correlation between the presence of the genetic factor for black and the capacity for pigment production, since hybrids carrying the black factor, and dominant white in which the presence of the black factor is masked by an inhibitor, also produce pigment in cultures of neural crest, while cultures of recessive white which lack the genetic factor for pigment were negative. 4. Pigment production is related to the stage of the embryo at the time of explantation. A very low percentage of positives was obtained from embryos prior to the formation of the neural folds, the highest percentage of strongly positive cultures being obtained from embryos of from one to 7 somites, when the neural crest material is most concentrated. The lower percentages obtained in early stages are probably due to the undetermined nature of the explant, in the older stages to the increasing diffuseness of the neural crest as a result of cellular migration. 5. Control cultures, made from other regions of the embryo, were invariably negative when taken in stages prior to migration of the neural crest, except in cases where the whole embryo was explanted after removal of the pre-otic crest. Here a few black cells occurred as probable derivatives of the post-otic section of the crest.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Sax K (1938)

Chromosome Aberrations Induced by X-Rays.

Genetics, 23(5):494-516.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Lesley MM (1938)

The Relation between Satellite Size and Nucleolus Size in Three Races of Solanum Lycopersicum.

Genetics, 23(5):485-493.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Dobzhansky T, ML Queal (1938)

Genetics of Natural Populations. II. Genic Variation in Populations of Drosophila Pseudoobscura Inhabiting Isolated Mountain Ranges.

Genetics, 23(5):463-484.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Morgan LV (1938)

Effects of a Compound Duplication of the X Chromosome of Drosophila Melanogaster.

Genetics, 23(5):423-462.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Law LW (1938)

Studies on Size Inheritance in Mice.

Genetics, 23(5):399-422.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Mendel B, Strelitz F, D Mundell (1938)

1-GLYCERIC ALDEHYDE AND TUMOR METABOLISM.

Science (New York, N.Y.), 88(2276):149-150.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Anonymous (1938)

ECOLOGICAL SOCIETY OF AMERICA AND GENETICS SOCIETY OF AMERICA.

Science (New York, N.Y.), 88(2274):96.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Rhoades MM (1938)

Effect of the Dt Gene on the Mutability of the a(1) Allele in Maize.

Genetics, 23(4):377-397.

RevDate: 2022-03-31
CmpDate: 2007-02-02

McClintock B (1938)

The Production of Homozygous Deficient Tissues with Mutant Characteristics by Means of the Aberrant Mitotic Behavior of Ring-Shaped Chromosomes.

Genetics, 23(4):315-376.

RevDate: 2021-10-20
CmpDate: 2011-04-04

Anonymous (1938)

CANCER AND HEREDITY.

British medical journal, 1(4041):1317-1318.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Randolph LF, DB Hand (1938)

INCREASE IN VITAMIN A ACTIVITY OF CORN CAUSED BY DOUBLING THE NUMBER OF CHROMOSOMES.

Science (New York, N.Y.), 87(2263):442-443.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Anderson EG (1938)

Translocations in Maize Involving Chromosome 9.

Genetics, 23(3):307-313.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Whittinghill M (1938)

The Induction of OOgonial Crossing over in Drosophila Melanogaster.

Genetics, 23(3):300-306.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Slizynska H (1938)

Salivary Chromosome Analysis of the White-Facet Region of Drosophila Melanogaster.

Genetics, 23(3):291-299.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Slizynski BM (1938)

Salivary Chromosome Studies of Lethals in Drosophila Melanogaster.

Genetics, 23(3):283-290.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Crouse HV, H Smith-Stocking (1938)

New Mutants in Sciara and Their Genetic Behavior.

Genetics, 23(3):275-282.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Castle WE (1938)

The Relation of Albinism to Body Size in Mice.

Genetics, 23(3):269-274.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Macarthur JW, L Butler (1938)

Size Inheritance and Geometric Growth Processes in the Tomato Fruit.

Genetics, 23(3):253-268.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Morton JJ, GB Mider (1938)

THE PRODUCTION OF LYMPHOMATOSIS IN MICE OF KNOWN GENETIC CONSTITUTION.

Science (New York, N.Y.), 87(2258):327-328.

RevDate: 2019-11-20

Enzmann EV, CP Haskins (1938)

Morphogenesis studies by means of X-rays : III. X-ray induced persistence of a larval character in Drosophila.

Wilhelm Roux' Archiv fur Entwicklungsmechanik der Organismen, 138(1):161-162.

A peculiar x-ray induced localized growth inDrosophila imagos is described and provisionally identified as a persistent larval spiracle. The view is expressed that a chromosomal upset changes the cell chemistry in such a way as to make them impervious to normal destruction during metamorphosis.

RevDate: 2019-11-20

Exzmann EV, CP Haskins (1938)

Morphogenesis studies by means of X-rays : II. Note on an inherited cuticular tumor in Drosophila.

Wilhelm Roux' Archiv fur Entwicklungsmechanik der Organismen, 138(1):159-160.

RevDate: 2019-05-01
CmpDate: 2008-01-11

Hamilton JB (1938)

THE SIGNIFICANCE OF HEREDITY IN OPHTHALMOLOGY. PRELIMINARY SURVEY OF HEREDITARY EYE DISEASES IN TASMANIA.

The British journal of ophthalmology, 22(3):129-148.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Dobzhansky T, ML Queal (1938)

Genetics of Natural Populations. I. Chromosome Variation in Populations of Drosophila Pseudoobscura Inhabiting Isolated Mountain Ranges.

Genetics, 23(2):239-251.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Gottschewski G, CC Tan (1938)

The Homology of the Eye Color Genes in Drosophila Melanogaster and Drosophila Pseudoobscura as Determined by Transplantation. II.

Genetics, 23(2):221-238.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Reynolds JP (1938)

Sex Determination in a "Bisexual" Strain of Sciara Coprophila.

Genetics, 23(2):203-220.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Emerson S (1938)

The Genetics of Self-Incompatibility in Oenothera Organensis.

Genetics, 23(2):190-202.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Nagai MA, GL Locher (1938)

The Production of Mutations in Drosophila with Neutron Radiation.

Genetics, 23(2):179-189.

RevDate: 2019-05-01
CmpDate: 2008-01-11

Hamilton JB (1938)

THE SIGNIFICANCE OF HEREDITY IN OPHTHALMOLOGY. PRELIMINARY SURVEY OF HEREDITARY EYE DISEASES IN TASMANIA.

The British journal of ophthalmology, 22(2):83-108.

RevDate: 2019-05-01
CmpDate: 2008-01-11

Hamilton JB (1938)

THE SIGNIFICANCE OF HEREDITY IN OPHTHALMOLOGY. PRELIMINARY SURVEY OF HEREDITARY EYE DISEASES IN TASMANIA.

The British journal of ophthalmology, 22(1):19-43.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Stebbins GL (1938)

Cytogenetic Studies in Paeonia II. the Cytology of the Diploid Species and Hybrids.

Genetics, 23(1):83-110.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Saunders AP, GL Stebbins (1938)

Cytogenetic Studies in Paeonia I. the Compatibility of the Species and the Appearance of the Hybrids.

Genetics, 23(1):65-82.

RevDate: 2022-03-18
CmpDate: 2007-02-02

Dobzhansky T, AH Sturtevant (1938)

Inversions in the Chromosomes of Drosophila Pseudoobscura.

Genetics, 23(1):28-64.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Hollander WF (1938)

A Sex Difference in Linkage Intensity of Three Autosomal Factors in the Domestic Pigeon.

Genetics, 23(1):24-27.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Demerec M (1938)

Abstracts of Papers Presented at the 1937 Meetings of the Genetics Society of America.

Genetics, 23(1):139-177.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Hollander WF (1938)

Inheritance of Certain "Blue-Black" Patterns and "Bleached" Colorations in the Domestic Pigeon.

Genetics, 23(1):12-23.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Smith TL (1938)

Genetical Studies on the Wax Moth Galleria Mellonella Linn.

Genetics, 23(1):115-137.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Bridges CB, PN Bridges (1938)

Salivary Analysis of Inversion-3r-Payne in the "Venation" Stock of Drosophila Melanogaster.

Genetics, 23(1):111-114.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Currence TM (1938)

The Relation of the First Chromosome Pair to Date of Fruit Ripening in the Tomato (Lycopersicum Esculentum).

Genetics, 23(1):1-11.

RevDate: 2021-10-20
CmpDate: 2010-06-24

Hutton WL (1937)

THE INHERITABILITY OF FEEBLE-MINDEDNESS.

Canadian Medical Association journal, 37(6):591-594.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Demerec M, H Slizynska (1937)

Mottled White 258-18 of Drosophila Melanogaster.

Genetics, 22(6):641-649.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Hoover ME (1937)

A Tandem Inversion in Drosophila Melanogaster.

Genetics, 22(6):634-640.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Painter TS, AB Griffen (1937)

The Structure and the Development of the Salivary Gland Chromosomes of Simulium.

Genetics, 22(6):612-633.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Beadle GW (1937)

Development of Eye Colors in Drosophila: Fat Bodies and Malpighian Tubes in Relation to Diffusible Substances.

Genetics, 22(6):587-611.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Beers CV (1937)

Linkage Groups in Drosophila Pseudoobscura, Race B.

Genetics, 22(6):577-586.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Catcheside DG (1937)

The Extra Chromosome of Oenothera Lamarckiana Lata.

Genetics, 22(6):564-576.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Combs JD, HL Gravett (1937)

The Effects of a Constant Dosage of X-Rays during the Pre-, Post-, and Mid-Proliferative Periods in Drosophila Melanogaster.

Genetics, 22(6):557-563.

RevDate: 2021-10-20
CmpDate: 2010-06-22

Crozier WJ, Wolf E, G Zerrahn-Wolf (1937)

CRITICAL ILLUMINATION AND FLICKER FREQUENCY IN RELATED FISHES.

The Journal of general physiology, 21(1):17-56.

Flicker response curves have been obtained at 21.5 degrees C. for three genera of fresh water teleosts: Enneacanthus (sunfish), Xiphophorus (swordtail), Platypoecilius (Platy), by the determination of mean critical intensities for response at fixed flicker frequencies, and for a certain homogeneous group of backcross hybrids of swordtail x Platy (Black Helleri). The curves exhibit marked differences in form and proportions. The same type of analysis is applicable to each, however. A low intensity rod-governed section has added to it a more extensive cone portion. Each part is accurately described by the equation F = F(max.)/(1 + e(-p log(-p logI/I(i)))), where F = flicker frequency, I = associated mean critical intensity, and I(i) is the intensity at the inflection point of the sigmoid curve relating F to log I. There is no correlation between quantitative features of the rod and cone portions. Threshold intensities, p, I(i), and F(max.) are separately and independently determined. The hybrid Black Helleri show quantitative agreement with the Xiphophorus parental stock in the values of p for rods and cones, and in the cone F(max.); the rod F(max.) is very similar to that for the Platy stock; the general level of effective intensities is rather like that of the Platy form. This provides, among other things, a new kind of support for the duplicity doctrine. Various races of Platypoecilius maculatus, and P. variatus, give closely agreeing values of I(m) at different flicker frequencies; and two species of sunfish also agree. The effect of cross-breeding is thus not a superficial thing. It indicates the possibility of further genetic investigation. The variability of the critical intensity for response to flicker follows the rules previously found to hold for other forms. The variation is the expression of a property of the tested organism. It is shown that, on the assumption of a frequency distribution of receptor element thresholds as a function of log I, with fluctuation in the excitabilities of the marginally excited elements, it is to be expected that the dispersion of critical flicker frequencies in repeated measurements will pass through a maximum as log I is increased, whereas the dispersion of critical intensities will be proportional to I(m); and that the proportionality factor in the case of different organisms bears no relation to the form or position of the respective curves relating mean critical intensity to flicker frequency. These deductions agree with the experimental findings.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Murray WS (1937)

THE OCCURRENCE OF A POSSIBLE MUTATION, CANCER TO NON-CANCER, IN THE HOUSE MOUSE.

Science (New York, N.Y.), 86(2229):268-269.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Metz CW (1937)

Small Deficiencies and the Problem of Genetic Units in the Giant Chromosomes.

Genetics, 22(5):543-556.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Jollos V (1937)

Some Attempts to Test the ROle of Cosmic Radiation in the Production of Mutations in Drosophila Melanogaster.

Genetics, 22(5):534-542.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Sax K (1937)

Chromosome Behavior and Nuclear Development in Tradescantia.

Genetics, 22(5):523-533.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Jones DF (1937)

Somatic Segregation and Its Relation to Atypical Growth.

Genetics, 22(5):484-522.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Ephrussi B, GW Beadle (1937)

Development of Eye Colors in Drosophila: Production and Release of cn Substance by the Eyes of Different Eye Color Mutants.

Genetics, 22(5):479-483.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Demerec M (1937)

Frequency of Spontaneous Mutations in Certain Stocks of Drosophila Melanogaster.

Genetics, 22(5):469-478.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Bywaters JH (1937)

The Hereditary and Environmental Portions of the Variance in Weaning Weights of Poland-China Pigs.

Genetics, 22(5):457-468.

RevDate: 2021-10-20
CmpDate: 2011-04-04

Kretschmer E (1937)

Heredity and Constitution in Aetiology of Psychic Disorders.

British medical journal, 2(3999):403-406.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Kostoff D (1937)

CHROMOSOME ALTERATIONS BY CENTRIFUGING.

Science (New York, N.Y.), 86(2222):101.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Li JC (1937)

A SIX-CHROMOSOME ASCARIS IN CHINESE HORSES.

Science (New York, N.Y.), 86(2222):101-102.

RevDate: 2021-10-20
CmpDate: 2010-06-22

Mendel DL, M Saibil (1937)

A Case of Subacute Bacterial Endocarditis with Brain Abscess.

Canadian Medical Association journal, 37(1):53-55.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Bishop DW (1937)

Induction of Dominant Lethal Effects by X-Radiation in Habrobracon.

Genetics, 22(4):452-456.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Robertson DW (1937)

Inheritance in Barley II.

Genetics, 22(4):443-451.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Howland RB, Glancy EA, BP Sonnenblick (1937)

Transplantation of Wild Type and Vermilion Eye Disks among Four Species of Drosophila.

Genetics, 22(4):434-442.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Combs JD (1937)

Genetic and Environmental Factors Affecting the Development of the Sex-Combs of Drosophila Melanogaster.

Genetics, 22(4):427-433.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Patterson JT, Stone W, S Bedichek (1937)

Further Studies on X Chromosome Balance in Drosophila.

Genetics, 22(4):407-426.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Wright S (1937)

THE DISTRIBUTION OF GENE FREQUENCIES IN POPULATIONS.

Science (New York, N.Y.), 85(2212):504.

RevDate: 2010-06-10
CmpDate: 2010-07-02

Ladd GE (1937)

LINES OF INHERITANCE IN FAMILIES OF "BLEEDERS" AS NARRATED IN 1834.

Science (New York, N.Y.), 85(2211):478-479.

RevDate: 2021-10-20
CmpDate: 2010-06-24

McInnes RG (1937)

Observations on Heredity in Neurosis: (Section of Psychiatry).

Proceedings of the Royal Society of Medicine, 30(7):895-904.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Berg RL (1937)

The Relative Roles of Stabilization and Redifferentiation of the Gene in the Evolution of the Hereditary Substance.

Genetics, 22(3):402-405.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Harnly MH, B Ephrussi (1937)

Development of Eye Colors in Drosophila: Time of Action of Body Fluid on Cinnabar.

Genetics, 22(3):393-401.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Gordon M (1937)

Genetics of Platypoecilus III. Inheritance of Sex and Crossing over of the Sex Chromosomes in the Platyfish.

Genetics, 22(3):376-392.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Smith HH (1937)

The Relation between Genes Affecting Size and Color in Certain Species of Nicotiana.

Genetics, 22(3):361-375.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Smith HH (1937)

Inheritance of Corolla Color in the Cross Nicotiana Langsdorffii by N. Sanderae.

Genetics, 22(3):347-360.

RevDate: 2022-03-18
CmpDate: 2007-02-02

Dobzhansky T (1937)

Further Data on the Variation of the Y Chromosome in Drosophila Pseudoobscura.

Genetics, 22(3):340-346.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Neuhaus M (1937)

Additional Data on Crossing over between X and Y Chromosomes in Drosophila Melanogaster.

Genetics, 22(3):333-339.

RevDate: 2021-10-20
CmpDate: 2011-03-30

Gun WT (1937)

The heredity of the royal caste.

The Eugenics review, 29(1):19-31.

RevDate: 2021-10-20
CmpDate: 2010-06-22

Ardashnikov SN (1937)

The genetics of leukaemia in man.

The Journal of hygiene, 37(2):286-302.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Margolis OS, CW Robertson (1937)

Studies on the Bar Series of Drosophila IV. the Temperature-Effective Period for Facet Determination in the Wild Type.

Genetics, 22(2):319-331.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Dunn LC, Macdowell EC, GA Lebedeff (1937)

Studies on Spotting Patterns III. Interaction between Genes Affecting White Spotting and Those Affecting Color in the House Mouse.

Genetics, 22(2):307-318.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Lesley JW (1937)

Crossing over in Tomatoes Trisomic for the "A" or First Chromosome.

Genetics, 22(2):297-306.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Sonneborn TM, RS Lynch (1937)

Factors Determining Conjugation in Paramecium Aurelia III. a Genetic Factor: The Origin at Endomixis of Genetic Diversities.

Genetics, 22(2):284-296.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Hetzer HO (1937)

The Genetic Basis for Resistance and Susceptibility to Salmonella Aertrycke in Mice.

Genetics, 22(2):264-283.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Monod J, DF Poulson (1937)

Specific Reactions of the Ovary to Interspecific Transplantation among Members of the Melanogaster Group of Drosophila.

Genetics, 22(2):257-263.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Macknight RH (1937)

Crossing over in the Sex Chromosome of Racial Hybrids of Drosophila Pseudoobscura.

Genetics, 22(2):249-256.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Berg RL (1937)

The Relative Frequency of Mutations in Different Chromosomes of Drosophila Melanogaster II. Sterility Mutations.

Genetics, 22(2):241-248.

RevDate: 2021-09-16
CmpDate: 2007-02-02

Berg RL (1937)

The Relative Frequency of Mutations in Different Chromosomes of Drosophila Melanogaster I. Lethal Mutations.

Genetics, 22(2):225-240.

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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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This is a must read book for anyone with an interest in invasion biology. The full title of the book lays out the author's premise — The New Wild: Why Invasive Species Will Be Nature's Salvation. Not only is species movement not bad for ecosystems, it is the way that ecosystems respond to perturbation — it is the way ecosystems heal. Even if you are one of those who is absolutely convinced that invasive species are actually "a blight, pollution, an epidemic, or a cancer on nature", you should read this book to clarify your own thinking. True scientific understanding never comes from just interacting with those with whom you already agree. R. Robbins

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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.

ESP Picks from Around the Web (updated 28 JUL 2024 )