DNA/Timelines: Difference between revisions

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{{subpages}}
{{subpages}}
{{timeline
{{timeline
|height=207
|height=290
|title=Discoveries relating to DNA}}
|title=Discoveries relating to DNA}}
{{TLevent
{{TLevent
|event='''1866''': [[Gregor Mendel]] identifies inheritance "factors" in pea plants.
|event='''1866''': [[Gregor Mendel]] identifies inheritance "factors" in pea plants.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1869''': [[Friedrich Miescher]] isolates “nuclein” (DNA) from infected wounds.
|event='''1869''': [[Friedrich Miescher]] isolates “nuclein” (DNA) from infected wounds.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1900''': [[Karl Correns]], [[Hugo de Vries]] and [[Erich von Tschermak]] independently rediscover Mendel's laws.
|event='''1900''': [[Karl Correns]], [[Hugo de Vries]] and [[Erich von Tschermak]] independently rediscover Mendel's laws.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1910''': [[Thomas Hunt Morgan]] proposed a theory of sex-linked inheritance for the first mutation discovered in the fruit fly, [[Drosophila]], white eye.  
|event='''1910''': [[Thomas Hunt Morgan]] proposed a theory of sex-linked inheritance for the first mutation discovered in the fruit fly, [[Drosophila]], white eye.  
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1913''': Morgan and [[Alfred Sturtevant]] propose principle of gene linkage leading to the first genetic map.  
|event='''1913''': Morgan and [[Alfred Sturtevant]] propose principle of gene linkage leading to the first genetic map.  
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1927''': [[Hermann J. Muller]] Used x-rays to cause artificial gene mutations in Drosophila.
|event='''1927''': [[Hermann J. Muller]] Used x-rays to cause artificial gene mutations in Drosophila.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1928''': [[Frederick Griffith]] demonstrates a "transforming factor" that can transmit the ability of [[bacteria]] to cause [[pneumonia]] in mice.
|event='''1928''': [[Frederick Griffith]] demonstrates a "transforming factor" that can transmit the ability of [[bacteria]] to cause [[pneumonia]] in mice.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1929''': [[Phoebus Levene]] describes building blocks of DNA, including four types of base A,C, T, and G.
|event='''1929''': [[Phoebus Levene]] describes building blocks of DNA, including four types of base A,C, T, and G.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1931''': [[Harriet Creighton]] and [[Barbara McClintock]] Demonstrated the cytological proof for crossing-over in [[maize]].
|event='''1931''': [[Harriet Creighton]] and [[Barbara McClintock]] Demonstrated the cytological proof for crossing-over in [[maize]].
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1941''': [[George Beadle]] and [[Edward Tatum]] prove that a gene can produce its effect by regulating particular enzymes.
|event='''1941''': [[George Beadle]] and [[Edward Tatum]] prove that a gene can produce its effect by regulating particular enzymes.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1944''': [[Oswald Avery]], [[Colin MacLeod]], and [[Maclyn McCarty]] purified the transforming factor proposed in Griffith's experiment and show it is not protein, but DNA.
|event='''1944''': [[Oswald Avery]], [[Colin MacLeod]], and [[Maclyn McCarty]] purified the transforming factor proposed in Griffith's experiment and show it is not protein, but DNA.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''Late 1940s''': Barbara McClintock developed the hypothesis of [[transposable element]]s.
|event='''Late 1940s''': Barbara McClintock developed the hypothesis of [[transposable element]]s.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
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|event='''1950''': [[Alfred Hershey]] and [[Martha Chase]] use [[bacteriophage]] to confirm DNA is the molecule of heredity.  
|event='''1950''': [[Alfred Hershey]] and [[Martha Chase]] use [[bacteriophage]] to confirm DNA is the molecule of heredity.  
:[[Erwin Chargaff]] discovered a one-to-one ratio of A:T and G:C in DNA samples from a variety of organisms.
:[[Erwin Chargaff]] discovered a one-to-one ratio of A:T and G:C in DNA samples from a variety of organisms.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1951''': [[Rosalind Franklin]] created a high quality [[X-ray diffraction]] photograph to reveal more detail of the repeating structure of DNA.
|event='''1951''': [[Rosalind Franklin]] created a high quality [[X-ray diffraction]] photograph to reveal more detail of the repeating structure of DNA.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1953''': [[Francis Crick]] and [[James Watson]] deduce the three-dimensional structure of the DNA molecule using a combination of experimental data and model building.
|event='''1953''': [[Francis Crick]] and [[James Watson]] deduce the three-dimensional structure of the DNA molecule using a combination of experimental data and model building.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
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|event='''1958''': [[Arthur Kornberg]] purified a [[DNA polymerase]] from bacteria, and used it to synthesis DNA in a test tube.
|event='''1958''': [[Arthur Kornberg]] purified a [[DNA polymerase]] from bacteria, and used it to synthesis DNA in a test tube.
:[[Matthew Meselson]] and [[Franklin Stahl]] demonstrated that DNA replicates by a semi-conservative mechanism.
:[[Matthew Meselson]] and [[Franklin Stahl]] demonstrated that DNA replicates by a semi-conservative mechanism.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1966''': [[Marshall Nirenberg]] and [[Gobind Khorana]] crack the [[genetic code]] linking the DNA sequence of nucleotides to the protein sequence of amino acid residues.
|event='''1966''': [[Marshall Nirenberg]] and [[Gobind Khorana]] crack the [[genetic code]] linking the DNA sequence of nucleotides to the protein sequence of amino acid residues.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1967''': Discovery of [[DNA ligase]].
|event='''1967''': Discovery of [[DNA ligase]].
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1969''': FISH  
|event='''1969''': FISH  
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
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|event='''1970''': [[Howard Temin]] discovered the of activity of [[reverse transcriptase]].
|event='''1970''': [[Howard Temin]] discovered the of activity of [[reverse transcriptase]].
:[[Hamilton Smith]] and [[Kent Wilcox]] isolated the first [[restriction enzyme]], HindII, that cuts DNA at a very specific nucleotide sequence.
:[[Hamilton Smith]] and [[Kent Wilcox]] isolated the first [[restriction enzyme]], HindII, that cuts DNA at a very specific nucleotide sequence.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1972''': [[Paul Berg]] creates the first recombinant DNA molecules, using restriction enzymes. This technology will be the beginning of the biotechnology industry.
|event='''1972''': [[Paul Berg]] creates the first recombinant DNA molecules, using restriction enzymes. This technology will be the beginning of the biotechnology industry.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
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|event='''1973''': [[Annie Chang]] and [[Stanley Cohen]] showed that a recombinant DNA molecule can be maintained and replicated in E. coli.
|event='''1973''': [[Annie Chang]] and [[Stanley Cohen]] showed that a recombinant DNA molecule can be maintained and replicated in E. coli.
:[[Joseph Sambrook]] refined [[DNA electrophoresis]] (first described in 1953) by using an agarose gel and staining the DNA with [[ethidium bromide]].
:[[Joseph Sambrook]] refined [[DNA electrophoresis]] (first described in 1953) by using an agarose gel and staining the DNA with [[ethidium bromide]].
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
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|event='''1975''': An International meeting at [[Asilomar, California]] provided guidelines regulating recombinant DNA experimentation.
|event='''1975''': An International meeting at [[Asilomar, California]] provided guidelines regulating recombinant DNA experimentation.
:[[Ed Southern]] developed the [[Southern blot]] for DNA. This name inspires similar blotting techniques for  RNA ([[northern blot]]) and protein ([[western blot]]).
:[[Ed Southern]] developed the [[Southern blot]] for DNA. This name inspires similar blotting techniques for  RNA ([[northern blot]]) and protein ([[western blot]]).
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1976''': [[Herbert Boyer]] cofounds [[Genentech]], the first firm founded in the United States to apply recombinant DNA technology
|event='''1976''': [[Herbert Boyer]] cofounds [[Genentech]], the first firm founded in the United States to apply recombinant DNA technology
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1977''': [[Frederick Sanger]], [[Allan Maxam]], and [[Walter Gilbert]] developed the chain termination (dideoxy) method for sequencing DNA.
|event='''1977''': [[Frederick Sanger]], [[Allan Maxam]], and [[Walter Gilbert]] developed the chain termination (dideoxy) method for sequencing DNA.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1978''': [[Somatostatin]], which regulates [[human growth hormone]]s, is the first human protein made using recombinant technology.
|event='''1978''': [[Somatostatin]], which regulates [[human growth hormone]]s, is the first human protein made using recombinant technology.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1980''': [[Mark Skolnick]], [[Ray White]], [[David Botstein]], and [[Ronald Davis]] create [[RFLP marker]] map of [[human genome]].
|event='''1980''': [[Mark Skolnick]], [[Ray White]], [[David Botstein]], and [[Ronald Davis]] create [[RFLP marker]] map of [[human genome]].
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1981''': Three independent research teams announced the discovery of human [[oncogene]]s (cancer genes).
|event='''1981''': Three independent research teams announced the discovery of human [[oncogene]]s (cancer genes).
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1983''': [[James Gusella]] demonstrate that the [[Huntington's disease]] gene is on chromosome 4.
|event='''1983''': [[James Gusella]] demonstrate that the [[Huntington's disease]] gene is on chromosome 4.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
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|event='''1985''': [[Kary Mullis]] published a paper describing the [[polymerase chain reaction]] (PCR) a technique to amplify specific DNA sequences from minutes quantities of starting material.
|event='''1985''': [[Kary Mullis]] published a paper describing the [[polymerase chain reaction]] (PCR) a technique to amplify specific DNA sequences from minutes quantities of starting material.
:[[Alec Jeffreys]] devised a technique that uses DNA polymorphisms to distinguish between different individuals. He later coined the term [[DNA fingerprinting]] and this is now impotant for many paternity, immigration, and murder cases.  
:[[Alec Jeffreys]] devised a technique that uses DNA polymorphisms to distinguish between different individuals. He later coined the term [[DNA fingerprinting]] and this is now impotant for many paternity, immigration, and murder cases.  
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1986''': [[Leroy Hood]] and [[Lloyd Smith]] automate DNA sequencing with the goal of sequencing whole genomes.  
|event='''1986''': [[Leroy Hood]] and [[Lloyd Smith]] automate DNA sequencing with the goal of sequencing whole genomes.  
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1987''': US DOE officially begins [[human genome project]].
|event='''1987''': US DOE officially begins [[human genome project]].
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1990''': [[BLAST algorithm]] developed to align DNA sequences and is the key to comparative genomics.
|event='''1990''': [[BLAST algorithm]] developed to align DNA sequences and is the key to comparative genomics.
:The first occurance of gene replacement therapy to repair a defective ADA gene in a four year old girls T-cells.
:The first occurrence of gene replacement therapy to repair a defective ADA gene in a four year old girls T-cells.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1993''': FlavrSavr tomatoes are the first genetically modified organisms to be marketed. They were engineered to ripen more slowly for longer shelf life.  
|event='''1993''': FlavrSavr tomatoes are the first genetically modified organisms to be marketed. They were engineered to ripen more slowly for longer shelf life.  
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
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|event='''1995''': [[Patrick Brown]] and Stanford University colleagues invent [[DNA microarray]] technology.
|event='''1995''': [[Patrick Brown]] and Stanford University colleagues invent [[DNA microarray]] technology.
:Researchers at The Institute for Genomic Research publish first genome sequence of free-living organism: ''[[Haemophilus influenzae]]''.
:Researchers at The Institute for Genomic Research publish first genome sequence of free-living organism: ''[[Haemophilus influenzae]]''.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1998''': NIH begins the Single Nucleotide Polymorphism ([[SNP]]) project to reveal human genetic variation.
|event='''1998''': NIH begins the [[single-nucleotide polymorphism|Single-Nucleotide Polymorphism]] (SNP) project to reveal human genetic variation.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''1999''': First human chromosome sequence published.
|event='''1999''': First human chromosome sequence published.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''2000''': Fruit fly genome sequenced using Celera’s whole-genome shotgun method.  
|event='''2000''': Fruit fly genome sequenced using Celera’s whole-genome shotgun method.  
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''2001''': Science and Nature publish annotations and analyses of human genome.
|event='''2001''': Science and Nature publish annotations and analyses of human genome.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
{{tlevent
{{tlevent
|event='''2005''': [[HapMap]] published giving a huge resource of SNP's and information relating to human variation.
|event='''2005''': [[HapMap]] published giving a huge resource of SNP's and information relating to human variation.
|width=80%
|width=500px
|color=#FFF
|color=#FFF
}}
}}
|}
|}
{{-}}
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Latest revision as of 10:36, 15 September 2013

This article has a Citable Version.
Main Article
Discussion
Related Articles  [?]
Bibliography  [?]
External Links  [?]
Citable Version  [?]
Timelines [?]
Student Level [?]
 
A timeline (or several) relating to DNA.
1866: Gregor Mendel identifies inheritance "factors" in pea plants.
1869: Friedrich Miescher isolates “nuclein” (DNA) from infected wounds.
1900: Karl Correns, Hugo de Vries and Erich von Tschermak independently rediscover Mendel's laws.
1910: Thomas Hunt Morgan proposed a theory of sex-linked inheritance for the first mutation discovered in the fruit fly, Drosophila, white eye.
1913: Morgan and Alfred Sturtevant propose principle of gene linkage leading to the first genetic map.
1927: Hermann J. Muller Used x-rays to cause artificial gene mutations in Drosophila.
1928: Frederick Griffith demonstrates a "transforming factor" that can transmit the ability of bacteria to cause pneumonia in mice.
1929: Phoebus Levene describes building blocks of DNA, including four types of base A,C, T, and G.
1931: Harriet Creighton and Barbara McClintock Demonstrated the cytological proof for crossing-over in maize.
1941: George Beadle and Edward Tatum prove that a gene can produce its effect by regulating particular enzymes.
1944: Oswald Avery, Colin MacLeod, and Maclyn McCarty purified the transforming factor proposed in Griffith's experiment and show it is not protein, but DNA.
Late 1940s: Barbara McClintock developed the hypothesis of transposable elements.
1950: Alfred Hershey and Martha Chase use bacteriophage to confirm DNA is the molecule of heredity.
Erwin Chargaff discovered a one-to-one ratio of A:T and G:C in DNA samples from a variety of organisms.
1951: Rosalind Franklin created a high quality X-ray diffraction photograph to reveal more detail of the repeating structure of DNA.
1953: Francis Crick and James Watson deduce the three-dimensional structure of the DNA molecule using a combination of experimental data and model building.
1958: Arthur Kornberg purified a DNA polymerase from bacteria, and used it to synthesis DNA in a test tube.
Matthew Meselson and Franklin Stahl demonstrated that DNA replicates by a semi-conservative mechanism.
1966: Marshall Nirenberg and Gobind Khorana crack the genetic code linking the DNA sequence of nucleotides to the protein sequence of amino acid residues.
1967: Discovery of DNA ligase.
1969: FISH
1970: Howard Temin discovered the of activity of reverse transcriptase.
Hamilton Smith and Kent Wilcox isolated the first restriction enzyme, HindII, that cuts DNA at a very specific nucleotide sequence.
1972: Paul Berg creates the first recombinant DNA molecules, using restriction enzymes. This technology will be the beginning of the biotechnology industry.
1973: Annie Chang and Stanley Cohen showed that a recombinant DNA molecule can be maintained and replicated in E. coli.
Joseph Sambrook refined DNA electrophoresis (first described in 1953) by using an agarose gel and staining the DNA with ethidium bromide.
1975: An International meeting at Asilomar, California provided guidelines regulating recombinant DNA experimentation.
Ed Southern developed the Southern blot for DNA. This name inspires similar blotting techniques for RNA (northern blot) and protein (western blot).
1976: Herbert Boyer cofounds Genentech, the first firm founded in the United States to apply recombinant DNA technology
1977: Frederick Sanger, Allan Maxam, and Walter Gilbert developed the chain termination (dideoxy) method for sequencing DNA.
1978: Somatostatin, which regulates human growth hormones, is the first human protein made using recombinant technology.
1981: Three independent research teams announced the discovery of human oncogenes (cancer genes).
1983: James Gusella demonstrate that the Huntington's disease gene is on chromosome 4.
1985: Kary Mullis published a paper describing the polymerase chain reaction (PCR) a technique to amplify specific DNA sequences from minutes quantities of starting material.
Alec Jeffreys devised a technique that uses DNA polymorphisms to distinguish between different individuals. He later coined the term DNA fingerprinting and this is now impotant for many paternity, immigration, and murder cases.
1986: Leroy Hood and Lloyd Smith automate DNA sequencing with the goal of sequencing whole genomes.
1987: US DOE officially begins human genome project.
1990: BLAST algorithm developed to align DNA sequences and is the key to comparative genomics.
The first occurrence of gene replacement therapy to repair a defective ADA gene in a four year old girls T-cells.
1993: FlavrSavr tomatoes are the first genetically modified organisms to be marketed. They were engineered to ripen more slowly for longer shelf life.
1995: Patrick Brown and Stanford University colleagues invent DNA microarray technology.
Researchers at The Institute for Genomic Research publish first genome sequence of free-living organism: Haemophilus influenzae.
1998: NIH begins the Single-Nucleotide Polymorphism (SNP) project to reveal human genetic variation.
1999: First human chromosome sequence published.
2000: Fruit fly genome sequenced using Celera’s whole-genome shotgun method.
2001: Science and Nature publish annotations and analyses of human genome.
2005: HapMap published giving a huge resource of SNP's and information relating to human variation.