Genetics in data
From WikiLectures
| Období objevu | Osobnost(i) | Objev |
|---|---|---|
| 1865 | Johan Gregor Mendel | Laws of inheritance (Mendel's laws of inheritance) |
| 1869 | Paul Langerhans | He discovered and described the islets of Langerhans in the pancreas (Diabetes mellitus type I a II) |
| 1869 | Friedrich Miescher | He isolated DNA for the first time; isolated it in small quantities from white blood cells; was not analyzed further |
| 1879 | Walther Flemming | Chromosomes in mitosis (Chromosome, Mitosis) |
| 1892 | Dmitri Ivanowski (Дми́трий Ивано́вский) | The term virus (Virus) |
| 1908 | Godfrey Harold Hardy a Wilhelm Weinberg | Basic law of population genetics (Hardy-Weinberg equilibrium) |
| 1909 | Karl Landsteiner | Blood group system AB0 – classification of people into blood groups A, B, AB, 0; 1930 Nobel Prize |
| 1909 | Thomas Hunt Morgan | Linear arrangement of genes on chromosomes, linkage of genes, phase coupling and repulsion; 1933 Nobel Prize (Gene linkage) |
| 1910 | Albert Kossel | Cytology - research on proteins and nucleic acids; 1910 Nobel Prize |
| 1911 | Peyton Rous | Discovery of a virus with oncogenic potential - domestic chicken sarcomas; 1966 Nobel Prize |
| 1920 | Frederick Banting a John J. R. Macleod | Isolation of an active substance from the pancreas for the treatment of diabetes; 1923 Nobel Prize (Multifactorial inheritance, Autoimmune disease) |
| od 1930 | George D. Snell | Discovery of genetic factors that determine the possibility of tissue transplantation, the histocompatibility complex (H-2) of the mouse; 1980 Nobel Prize (Major histocompatibility complex, Transplant laws) |
| od 1931 | William Bateson, Reginald Crundall Punnett | Linkage of genes, crossing-over, recombination; (Gene linkage) |
| 1937-45 | George Wells Beadle, Edward Lawrie Tatum | Biochemical and genetic studies on the microorganism Neurospora - determining the ability of genes to regulate certain chemical reactions; 1958 Nobel Prize' (Cell Signaling) |
| 1944 | Oswald Avery, Colin MacLeod, Maclyn McCarty | Basic genetic information is stored in DNA |
| 1940-50 | Barbara McClintock | The genetic map of maize, the role of centromeres and telomeres and the subsequent discovery of genetic transposition - mobile DNA sequences (transpososomes); 1983 Nobel Prize (Transposomes, Centromere, Telomeres) |
| 1940-60 | Peter Brian Medawar, Frank (Macfarlane) Burnet | Transplantation – discovery of acquired immunological tolerance; 1960 Nobel Prize (Transplant laws, Immunological tolerance) |
| 1950 a 1970-80 | Edward B. Lewis; Christiane Nusslein-Volhard a Eric F. Wieschaus | Developmental genetics; first Drosophila melanogaster - discovery of the principle of co-linearity (localization of sets of genes on chromosomes is related to the arrangement of body segments). Furthermore, this principle is confirmed for all multicellular animals; 1995 Nobel Prize' (Embryonic Development, Drosophila melanogaster) |
| 1950-61 | Francois Jacob, André Lwoff, Jacques Monod | Control and regulation of metabolic pathway enzyme expression by feedback with the DNA sequence (for example, ``E. coli/lactose); 1965 Nobel Prize' (Single-cell models, Prokaryotes) |
| 1950-59 | Stanley Cohen, Rita Levi-Montalcini | Isolation of nerve growth factor (NGF), which led to the discovery of epidermal growth factor; 1986 Nobel Prize' (Cell Signaling, (Proto)oncogenes) |
| 1953 | James D. Watson, Francis H. C. Crick, Maurice H. Frederics | Determining the structure of DNA; 1962 Nobel Prize |
| 1956 | Joe Hin Tjio a Albert Levan | Determining the exact number of chromosomes in human somatic cells (Human karyotype) |
| 1956 | Robert W. Holley, Har. G. Khorana, Marshall W. Nirenberg | Role of RNA in protein synthesis, genetic code and its role in protein biosynthesis; 1968 Nobel Prize' (mRNA, Translation) |
| 1957 | Arthur Kornberg | While studying the bacterium Escherichia coli, he discovered DNA polymerase; Severo Ochoa and Arthur Kornberg for the discovery of the mechanism of RNA and DNA biosynthesis ' 1959 Nobel Prize |
| 1958 | Tuneko Okazaki, Reiji Okazaki | Semiconservative replication process, Okazaki fragments |
| 1958-69 | Earl W. Sutherland, Jr. | Isolation of the hitherto unknown cyclic adenosine monophosphate (cAMP), clarification of its role in the metabolism of some hormones; 1971 Nobel Prize' (Cell Signaling) |
| 1959 | Jérôme JL Marie Lejeune | Chromosomal basis of Down syndrome - trisomy of chromosome 21 (Down syndrome) |
| 1960-65 | Baruj Benacerraf, Jean Dausset | Discovery of MHC and characterization of the genes of the major histocompatibility complex (MHC) of humans and subsequently other vertebrates; 1980 Nobel Prize' (HLA) |
| od 1960 | Alfred Goodman Gilman, Martin Rodbell | Discovery of G-proteins and elucidation of their role in cell signaling; 1994 Nobel Prize' (Cell Signaling) |
| od 1961 | Leonard Hayflick a P. Moorhead | They described a limitation in the number of cell cycles in ``in vitro cultured fibroblasts - the so-called replicative aging (senescence) (Replicative senescence) |
| 1962 | Werner Aber, Daniel Nathans, Hamilton O. Smith | Discovery of restriction endonucleases; 1978 Nobel Prize' (Restriction fragment length polymorphism) |
| 1970 | David Baltimore, Renato Dulbecco, Howard M. Temin | Oncovirology – interaction of retroviruses with the genetic material of the cell, reverse transcription; 1975 Nobel Prize' (Viral carcinogenesis) |
| 1970-71 | Leland Harrison Hartwell, Richard Timothy Hunt, Paul Maxime Nurse | During the study of the cell cycle of yeast (Saccharomyces cerevisiae), genes regulating the cell cycle were discovered; discovery of homologous genes in humans (cyclins and cyclin-dependent protein kinases) (Cell cycle, (Proto)oncogenes) |
| 1970-80 | Susumu Tonegawa | Analysis of DNA of the B cells (experiments on mice), discovery of the genetic principle of antibody diversity; 1987 Nobel Prize' (Gene Control of Antibody Formation) |
| 1970-80 | John M. Bishop, Harold E. Varmus | Study of the relationship of retroviruses to the development of malignant tumors, discovery of the first human oncogene "c-src"; 1989 Nobel Prize' (Oncoviruses, (Proto)oncogenes) |
| 1975 | Edwin Mellor Southern | Developed the DNA hybridization method in gel electrophoresis to identify a specific DNA sequence (DNA hybridization, Southern blot) |
| 1975 | John Foxton Ross Kerr | He first described apoptosis – the genetically programmed death of cells; Nobel Prize 2002 - Sydney Brenner, H. Robert Horvitz, John E. Sulston - was awarded for the discoveries of genetic regulation of organ development and apoptosis (Embryonic development, Aging of the organism) |
| 1975-77 | Frederick Sanger, Walter Gilbert, Paul Berg | They developed DNA sequencing techniques; 1980 Nobel Prize (DNA; Sequencing); Frederick Sanger won already one Nobel Prize in 1958' for determining the polypeptide chain of insulin (Genetics of "Civilization" Diseases) |
| 1976 | Harald zur Hausen | Discovery of the papillomavirus, which is the cause of cervical cancer; Nobel Prize 2008' (Viral Carcinogenesis) |
| 1977 | Richard John Roberts, Phillip Allen Sharp | They independently discovered the division of genes of eukaryotic cells into sections (introns and exons) and the cutting of introns from mRNA (gene-splicing); 1993 Nobel Prize' (Gene Structure, Post-Transcriptional Modifications) |
| 1982 | Stanley B. Prusiner | He formulated a theory about a new causative agent of infectious diseases of the nervous system; discovery of prions; 1997 Nobel Prize' (Prions) |
| 1983 | Francoise Barréová-Sinoussiová, Luc Montagnier | Discovery of HIV (Human Immunodeficiency Virus); Nobel Prize 2008' – (Immunodeficiency, AIDS) |
| 1984 | Elizabeth Blackburnová, Carol Whidney Greiderová, Jack William Szostak | Discovery of telomeres (protection of the ends of linear chromosomes) and the enzyme telomerase; Nobel Prize 2009' - (Telomeres and telomerase) |
| 1985 | Kary Banks Mullis s kolegy | He developed the PCR (Polymerase Chain Reaction) method, which makes it possible to multiply a selected section of hereditary information even from a single DNA molecule; Nobel Prize 1993 - (DNA, Polymerase Chain Reaction) |
| 1988-2001 | Projekt HUGO | Human Genome Sequencing; The International Human Genome Project Consortium and the American private company Celera Genomics - "rough" reading of the genome (DNA, Genome Mapping) |
| 1989 | Mario Renato Capecchi, Martin Evans, Oliver Smithies | Study of embryonic development – mouse embryonic stem cells, knockout mice; Nobel Prize 2007 - (Stem cells, Knockout mouse, Mus musculus) |
| 1990 | Stephen F. Altshul, Gish W., David J. Lipmann, Miller W., Eugene Wilson Meyers | They created the BLAST (Basic Local Alignment Search Tool) algorithm for calculating sequence similarity and then searching for genes and proteins based on mutual homology (in silico – computer models) |
| 1990 | William French Anderson | The first performed gene therapy on a 4-year-old child suffering from immunodeficiency (SCID – Severe Combined Immunodeficiency); the treatment result was partial. 2001 Alan Fisher cured SCID (Immunodeficiency) with gene therapy |
| 1996 | ovce Dolly | First cloning of a mammal from a single body cell (Stem cells) |
| 1998 | Andrew Z. Fire, Craig C. Mello | Discovery of RNA interference – a system of controlling the activity of some (specific) genes; Nobel Prize 2006 (Transcription, RNA interference) |
| 2012 | Jennifer A. Doudna, E. Charpentier | Targeted genome editing using CRISPR/Cas9; Nobel Prize 2020 |
Gallery of personalities[edit | edit source]
- Významné osobnosti historie genetiky
Johann Gregor Mendel (1822–1884)
Walther Flemming (1843–1905)
Karl Landsteiner (1868–1943)
Thomas Hunt Morgan (1866–1945)
Oswald Theodore Avery (1877–1955)
Barbara McClintock (1902–1992)
Francis Harry Compton Crick (1916–2004)
James Dewey Watson (1928)
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