DNA: The Story of Life is a four-part Channel 4 documentary series on the discovery of DNA, broadcast in 2003.
The series was broadcast to celebrate fifty years since the 1953 discovery. The first episode was broadcast on Saturday March 8, 2003 at 7pm.
It covered the discovery of DNA in 1953. [1] Maurice Wilkins and his involvement with the Manhattan Project, speaking in his university office in London; Linus Pauling's son Peter, of Caltech, now lived in Wales; Linus Pauling approached the discovery of the structure of DNA in a much more methodical rigid manner, perhaps in a plodding way, and Pauling was never one to take the same un-thought-through reckless gambles that Watson and Crick would take; but those ambitious reckless gambles of Watson and Crick would find the structure of DNA; the 1974 BBC documentary The Race for the Double Helix; Watson attended a lecture on the latest X-ray data on DNA at Somerset House in London in November 1951, with the project in Cambridge later producing their first DNA model on 28 November 1951; Sir John Randall, head of the London project, telephoned Lawrence Bragg in Cambridge, with his displeasure at how Watson and Crick had borrowed London's DNA structure X-ray data, which resulted in Watson and Crick being chastened, and removed from their work on DNA structure at Cambridge; but at the London project, events were being often undermined by frosty wooden relationships, and a complete lack of human empathy, as believed Raymond Gosling; at Cambridge, biochemist Erwin Chargaff, of Columbia University, had dinner with Watson and Crick, and although he largely disliked the pair, he explained his Chargaff's rules to them, where equal amounts of adenine and thymine had been found, which had applied to all living cells; Linus Pauling writes to Wilkins, asking for recent X-ray photographs, but is unlucky; on 6 May 1952, [2] the London project takes Photo 51, which indicated a helix structure; in December 1952, Linus Pauling produced his first rudimentary model of DNA, but it was not at all similar to DNA; Watson travelled to the London project again, on 30 January 1953, and whilst looking for any possible photographic X-ray data, Wilkins happily showed him the Photo 51, not realising the dramatic leap in understanding that this photo may have provided for Watson, who himself couldn't believe his luck; Wilkins was not disappointed that Watson had viewed this picture, as he was looking for more scientific collaboration anyway, anywhere that he could find it; in early 1953, Watson and Crick could again resume their DNA project at Cambridge, as Lawrence Bragg realised the need to find the structure before Pauling could discover it; Watson sees the hydrogen bonds between the DNA base pair structure; Watson was later the Director of Cold Spring Harbor Laboratory, and Crick later worked in computational neuroscience.
The advances in genetic engineering. [3] Herb Boyer studied bacteria in a California hospital; one morning he found a bacteria that could splice DNA, with enzymes (a restriction endonuclease); in March 1973 Boyer and Stanley Norman Cohen worked on an experiment to put a toad gene into a bacteria; the experiment worked, and the bacteria cell produced toad proteins; Paul Berg, of Stanford University was attempting to splice cancer genes with bacteria (E.coli) genes; one of his PhD students gave a talk about her work, in a group with Bob Pollack, of Columbia University, in attendance, who thought that such an experiment was unethical; Berg halted his work on genetic engineering, to examine any risks; the four-day Asilomar Conference on Recombinant DNA was held in February, in California, to look at possible risks; Alexander Capron of the University of Pennsylvania, who attended the conference; Jim Watson equated the caution to the risk, to communism; Sydney Brenner, of the University of Cambridge, to prove that the risk was low, himself drank genetically modified bacteria, mixed with milk; scientists would work in biosafety level 4 laboratories; Bob Swanson contacted Herb Boyer, to form a company - Genentech; Walter Gilbert of Harvard University wanted to make synthetic insulin; David Goeddel joined Genentech, and chose to build the insulin molecule step by step; Gilbert was banned from Harvard, so moved to England to work at a biosafety P4 laboratory at Porton Down in Wiltshire, to find the insulin gene; due to cross-contamination, but, after two years of work, he had found the gene of rat insulin instead; Genentech were the first to make synthetic insulin in bacteria; no Nobel prizes were awarded for the important genetic engineering discovery by Herb Boyer and his team; David Ebersman of Genentech.
Plant biologist Rob Horsch, whose father James Robert Horsch was an electrical engineer on the Apollo programme, wanted to modify crop genes, so approached Monsanto, working in a modest laboratory, at the Chesterfield Village Research Center in Chesterfield, Missouri, on Agrobacterium tumefaciens on petunia plants; he next worked on a genetically modified potato, first growing one on 2 June 1987; after proving it could be done, Horsch worked on cotton, more on the potato, wheat, soya, corn, and rice, to give pest resistance; current work includes crops with more vitamins.
The 1990s and the start of human genome project. [4] Sir Alec Jeffreys, and his discovery on 17 September 1984 at the University of Leicester Department of Genetics, and how his wife Sue thought of possible applications; the Colin Pitchfork case in 1988; Fred Sanger FRS, of the MRC Laboratory of Molecular Biology, and reading the nucleotide sequence; he found a method by chemical markers, which attached to the different nucleotides; Sanger found the 5,000 nucleotide-sequence of a virus, after four years; Sanger invented DNA sequencing; Jeffreys found the portion (minisatellites) of human DNA where that same DNA sequencing, of Fred Sanger, could be best applied; but the human DNA sequence had around 3 billion nucleotide base pairs.
Jim Watson invited scientists to a meeting, in 1986, to discuss possibly sequencing the human genome; David Botstein was against any sequencing, but physicist Walter Gilbert was for the genome sequencing, estimating that it would cost £3bn over 30 years, and one scientist could sequence around 100,000 base pairs in one year; the US Congress approved the project funding in 1990, after Jim Watson put the case; Francis Collins took over the project from 1992; the repeated parts of the DNA sequence, that Alec Jeffreys found, could divide the human genome DNA up into parts, so that sixteen laboratories, around the world, sequenced one separate region, to finish in 2005; one third of the human genome would be sequenced at the Sanger Centre (now the Wellcome Sanger Institute) in South Cambridgeshire, headed in the UK by Sir John Sulston; by 1998, one-third had been sequenced, but Craig Venter thought that progress was much too slow, and would be quicker with shotgun sequencing, and computer reading of the sequence of bases; Leroy Hood of the Institute for Systems Biology, with Michael Hunkapiller of Applied Biosystems; on 10 May 1998, Venter announced that he would go it alone, as he thought that he could complete it by 2001; Venter was met by a torrent of verbal abuse from Jim Watson, at a meeting, who thought that the idea of a private company holding the DNA information was completely unacceptable; Venter had 300 DNA sequence-reading robots made, for his Celera Genomics company, which read DNA from five people, run by Tony White; Jim Watson returned to the US Congress to get more funding, and the public project bought £300,000 DNA sequencing machines from Celera.
With the new machines, 4 million base pairs could be sequenced, by one laboratory, in one day; a main sequencing operation was at the Whitehead Institute at MIT, run by mathematician Eric Lander; Greek scientist Aristides Patrinos, who arranged for Collins and Venter to socially meet; the two sides agreed to make a joint announcement on 26 March 2000; software developers Jim Kent, for the public project, and Gene Myers, for Celera, had to reassemble the data from the many laboratories; but someone had to work out where the protein gene sequences were, so Ewan Birney FRS at the Sanger Centre in Cambridgeshire developed his Ensembl genome database project (with Tim Hubbard and Michele Clamp), to find the individual genes; 48 hours before the announcement on Monday 26 March, the two teams did not know how many genes that there were; the teams estimated around 38,000; around 25% of the genome was found to be gene deserts, and people shared largely the same DNA data - with only around 1 in 1200 base pairs that differed.
The last episode was broadcast on Sunday 30 March 2003 at 8pm.; [5] Mary-Claire King, of University of California, Berkeley, was puzzled as to why the breast cancer risk appeared to be mostly inherited; it would be the BRCA1 gene; she asked David Botstein, of MIT, for assistance; he looked at the spread of known genetic markers across the chromosomes of generations of families; if the markers were not found right across the generations, that part of the chromosome was not probably causing the BRCA mutation; different families' chromosomes were checked for 173 common genetic markers (known as restriction fragment length polymorphisms), which later led to identifying chromosome 17 in 1990; Mary Claire- King needed family information over many generations; she found it at the Family History Library in Utah, kept in immaculate condition by the Mormons (The Church of Jesus Christ of Latter-day Saints); Mark Skolnick also had looked at the Mormon family trees; in October 1987 Mary Claire-King appealed, on local television networks, for family histories, it would take seventeen years to find the BRCA1 gene; around 600,000 women in the US carried the BRCA1 gene; Barbara Weber of the University of Michigan; Mark Skolnick founded Myriad Genetics, to look for the BRCA1 gene, and his company found the mutation; Per Lønning, of Haukeland University Hospital in Norway, and son of Per Lønning, had collected cancer specimens, for possible later understanding of cancer genetics; David Botstein and Patrick O. Brown, who invented the DNA microarray; Brian Druker of the Oregon Health & Science University Hospital (OHSU), who started researching cancer genetics from 1979, and worked with Novartis to make Imatinib; Michael Wigler, of Cold Spring Harbor Laboratory, was finding cancer-causing genes
The series was repeated ten years later on More4.
A fifth part of the series was added to a DVD in 2004, entitled DNA: The Story of the Pioneers Who Changed the World
David Dugan was the producer, with Joe Bini the editor. It was a joint production with WNET.
Francis Harry Compton Crick was an English molecular biologist, biophysicist, and neuroscientist. He, James Watson, Rosalind Franklin, and Maurice Wilkins played crucial roles in deciphering the helical structure of the DNA molecule.
Genetics is the study of genes, genetic variation, and heredity in organisms. It is an important branch in biology because heredity is vital to organisms' evolution. Gregor Mendel, a Moravian Augustinian friar working in the 19th century in Brno, was the first to study genetics scientifically. Mendel studied "trait inheritance", patterns in the way traits are handed down from parents to offspring over time. He observed that organisms inherit traits by way of discrete "units of inheritance". This term, still used today, is a somewhat ambiguous definition of what is referred to as a gene.
In the fields of molecular biology and genetics, a genome is all the genetic information of an organism. It consists of nucleotide sequences of DNA. The nuclear genome includes protein-coding genes and non-coding genes, other functional regions of the genome such as regulatory sequences, and often a substantial fraction of junk DNA with no evident function. Almost all eukaryotes have mitochondria and a small mitochondrial genome. Algae and plants also contain chloroplasts with a chloroplast genome.
James Dewey Watson is an American molecular biologist, geneticist, and zoologist. In 1953, he co-authored with Francis Crick the academic paper proposing the double helix structure of the DNA molecule. Watson, Crick and Maurice Wilkins were awarded the 1962 Nobel Prize in Physiology or Medicine "for their discoveries concerning the molecular structure of nucleic acids and its significance for information transfer in living material".
Nucleic acids are large biomolecules that are crucial in all cells and viruses. They are composed of nucleotides, which are the monomer components: a 5-carbon sugar, a phosphate group and a nitrogenous base. The two main classes of nucleic acids are deoxyribonucleic acid (DNA) and ribonucleic acid (RNA). If the sugar is ribose, the polymer is RNA; if the sugar is deoxyribose, a variant of ribose, the polymer is DNA.
Walter Gilbert is an American biochemist, physicist, molecular biology pioneer, and Nobel laureate.
The human genome is a complete set of nucleic acid sequences for humans, encoded as DNA within the 23 chromosome pairs in cell nuclei and in a small DNA molecule found within individual mitochondria. These are usually treated separately as the nuclear genome and the mitochondrial genome. Human genomes include both protein-coding DNA sequences and various types of DNA that does not encode proteins. The latter is a diverse category that includes DNA coding for non-translated RNA, such as that for ribosomal RNA, transfer RNA, ribozymes, small nuclear RNAs, and several types of regulatory RNAs. It also includes promoters and their associated gene-regulatory elements, DNA playing structural and replicatory roles, such as scaffolding regions, telomeres, centromeres, and origins of replication, plus large numbers of transposable elements, inserted viral DNA, non-functional pseudogenes and simple, highly repetitive sequences. Introns make up a large percentage of non-coding DNA. Some of this non-coding DNA is non-functional junk DNA, such as pseudogenes, but there is no firm consensus on the total amount of junk DNA.
Genomics is an interdisciplinary field of biology focusing on the structure, function, evolution, mapping, and editing of genomes. A genome is an organism's complete set of DNA, including all of its genes as well as its hierarchical, three-dimensional structural configuration. In contrast to genetics, which refers to the study of individual genes and their roles in inheritance, genomics aims at the collective characterization and quantification of all of an organism's genes, their interrelations and influence on the organism. Genes may direct the production of proteins with the assistance of enzymes and messenger molecules. In turn, proteins make up body structures such as organs and tissues as well as control chemical reactions and carry signals between cells. Genomics also involves the sequencing and analysis of genomes through uses of high throughput DNA sequencing and bioinformatics to assemble and analyze the function and structure of entire genomes. Advances in genomics have triggered a revolution in discovery-based research and systems biology to facilitate understanding of even the most complex biological systems such as the brain.
Frederick Sanger was a British biochemist who received the Nobel Prize in Chemistry twice.
Molecular genetics is a branch of biology that addresses how differences in the structures or expression of DNA molecules manifests as variation among organisms. Molecular genetics often applies an "investigative approach" to determine the structure and/or function of genes in an organism's genome using genetic screens.
"Molecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic Acid" was the first article published to describe the discovery of the double helix structure of DNA, using X-ray diffraction and the mathematics of a helix transform. It was published by Francis Crick and James D. Watson in the scientific journal Nature on pages 737–738 of its 171st volume.
The history of molecular biology begins in the 1930s with the convergence of various, previously distinct biological and physical disciplines: biochemistry, genetics, microbiology, virology and physics. With the hope of understanding life at its most fundamental level, numerous physicists and chemists also took an interest in what would become molecular biology.
The Human Genome Project (HGP) was an international scientific research project with the goal of determining the base pairs that make up human DNA, and of identifying, mapping and sequencing all of the genes of the human genome from both a physical and a functional standpoint. It started in 1990 and was completed in 2003. It remains the world's largest collaborative biological project. Planning for the project started after it was adopted in 1984 by the US government, and it officially launched in 1990. It was declared complete on April 14, 2003, and included about 92% of the genome. Level "complete genome" was achieved in May 2021, with a remaining only 0.3% bases covered by potential issues. The final gapless assembly was finished in January 2022.
David Botstein is an American biologist who is the chief scientific officer of Calico. He was the director of the Lewis-Sigler Institute for Integrative Genomics at Princeton University from 2003 to 2013, where he remains an Anthony B. Evnin Professor of Genomics.
The history of molecular evolution starts in the early 20th century with "comparative biochemistry", but the field of molecular evolution came into its own in the 1960s and 1970s, following the rise of molecular biology. The advent of protein sequencing allowed molecular biologists to create phylogenies based on sequence comparison, and to use the differences between homologous sequences as a molecular clock to estimate the time since the last common ancestor. In the late 1960s, the neutral theory of molecular evolution provided a theoretical basis for the molecular clock, though both the clock and the neutral theory were controversial, since most evolutionary biologists held strongly to panselectionism, with natural selection as the only important cause of evolutionary change. After the 1970s, nucleic acid sequencing allowed molecular evolution to reach beyond proteins to highly conserved ribosomal RNA sequences, the foundation of a reconceptualization of the early history of life.
Applied Biosystems is one of various brands under the Life Technologies brand of Thermo Fisher Scientific corporation. The brand is focused on integrated systems for genetic analysis, which include computerized machines and the consumables used within them.
The following outline is provided as an overview of and topical guide to genetics:
The history of genetics can be represented on a timeline of events from the earliest work in the 1850s, to the DNA era starting in the 1940s, and the genomics era beginning in the 1970s.
A variant of uncertainsignificance (VUS) is a genetic variant that has been identified through genetic testing but whose significance to the function or health of an organism is not known. Two related terms are "gene of uncertain significance" (GUS), which refers to a gene that has been identified through genome sequencing but whose connection to a human disease has not been established, and "insignificant mutation", referring to a gene variant that has no impact on the health or function of an organism. The term "variant' is favored in clinical practice over "mutation" because it can be used to describe an allele more precisely. When the variant has no impact on health, it is called a "benign variant". When it is associated with a disease, it is called a "pathogenic variant". A "pharmacogenomic variant" has an effect only when an individual takes a particular drug and therefore is neither benign nor pathogenic.
The Gene: An Intimate History is a book written by Siddhartha Mukherjee, an Indian-born American physician and oncologist. It was published on 17 May 2016 by Scribner. The book chronicles the history of the gene and genetic research, all the way from Aristotle to Crick, Watson and Franklin and then the 21st century scientists who mapped the human genome. The book discusses the power of genetics in determining people's well-being and traits. It delves into the personal genetic history of Siddhartha Mukherjee's family, including mental illness. However, it is also a cautionary message toward not letting genetic predispositions define a person or their fate, a mentality that the author says led to the rise of eugenics in history.