fbpx
Wikipedia

Frederick Sanger

January 08, 2023

Frederick Sanger OM CH CBE FRS FAA (/ˈsæŋər/; 13 August 1918 – 19 November 2013) was an English biochemist who received the Nobel Prize in Chemistry twice.

Frederick Sanger

OM CH CBE FRS FAA
Born(1918-08-13)13 August 1918
Rendcomb, Gloucestershire, England
Died19 November 2013(2013-11-19) (aged 95)
Cambridge, England[1]
Alma materUniversity of Cambridge (PhD)
Known for
Awards
Scientific career
FieldsBiochemistry
Institutions
ThesisThe metabolism of the amino acid lysine in the animal body (1943)
Doctoral advisorAlbert Neuberger[2]
Doctoral students

He won the 1958 Chemistry Prize for determining the amino acid sequence of insulin and numerous other proteins, demonstrating in the process that each had a unique, definite structure; this was a foundational discovery for the central dogma of molecular biology.

At the newly-constructed Laboratory of Molecular Biology in Cambridge, he developed and subsequently refined the first-ever DNA sequencing technique, which vastly expanded the number of feasible experiments in molecular biology and remains in widespread use today. The breakthrough earned him the 1980 Nobel Prize in Chemistry, which he shared with Walter Gilbert and Paul Berg.

He is one of only three people to have won multiple Nobel Prizes in the same category (the others being John Bardeen in physics and Karl Barry Sharpless in chemistry),[4] and one of five persons with two Nobel Prizes.

Early life and education

Frederick Sanger was born on 13 August 1918 in Rendcomb, a small village in Gloucestershire, England, the second son of Frederick Sanger, a general practitioner, and his wife, Cicely Sanger (née Crewdson).[5] He was one of three children. His brother, Theodore, was only a year older, while his sister May (Mary) was five years younger.[6] His father had worked as an Anglican medical missionary in China but returned to England because of ill health. He was 40 in 1916 when he married Cicely, who was four years younger. Sanger's father converted to Quakerism soon after his two sons were born and brought up the children as Quakers. Sanger's mother was the daughter of an affluent cotton manufacturer and had a Quaker background, but was not a Quaker.[6]

When Sanger was around five years old the family moved to the small village of Tanworth-in-Arden in Warwickshire. The family was reasonably wealthy and employed a governess to teach the children. In 1927, at the age of nine, he was sent to the Downs School, a residential preparatory school run by Quakers near Malvern. His brother Theo was a year ahead of him at the same school. In 1932, at the age of 14, he was sent to the recently established Bryanston School in Dorset. This used the Dalton system and had a more liberal regime which Sanger much preferred. At the school he liked his teachers and particularly enjoyed scientific subjects.[6] Able to complete his School Certificate a year early, for which he was awarded seven credits, Sanger was able to spend most of his last year of school experimenting in the laboratory alongside his chemistry master, Geoffrey Ordish, who had originally studied at Cambridge University and been a researcher in the Cavendish Laboratory. Working with Ordish made a refreshing change from sitting and studying books and awakened Sanger's desire to pursue a scientific career.[7] In 1935, prior to heading off to college, Sanger was sent to Schule Schloss Salem in southern Germany on an exchange program. The school placed a heavy emphasis on athletics, which caused Sanger to be much further ahead in the course material compared to the other students. He was shocked to learn that each day was started with readings from Hitler's Mein Kampf, followed by a Sieg Heil salute.[8]

In 1936 Sanger went to St John's College, Cambridge to study natural sciences. His father had attended the same college. For Part I of his Tripos he took courses in physics, chemistry, biochemistry and mathematics but struggled with physics and mathematics. Many of the other students had studied more mathematics at school. In his second year he replaced physics with physiology. He took three years to obtain his Part I. For his Part II he studied biochemistry and obtained a 1st Class Honours. Biochemistry was a relatively new department founded by Gowland Hopkins with enthusiastic lecturers who included Malcolm Dixon, Joseph Needham and Ernest Baldwin.[6]

Both his parents died from cancer during his first two years at Cambridge. His father was 60 and his mother was 58. As an undergraduate Sanger's beliefs were strongly influenced by his Quaker upbringing. He was a pacifist and a member of the Peace Pledge Union. It was through his involvement with the Cambridge Scientists Anti-War Group that he met his future wife, Joan Howe, who was studying economics at Newnham College. They courted while he was studying for his Part II exams and married after he had graduated in December 1940. Sanger, although brought up and influenced by his religious upbringing, later began to lose sight of his Quaker related ways. He began to see the world through a more scientific lens, and with the growth of his research and scientific development he slowly drifted farther from the faith he grew up with. He has nothing but respect for the religious and states he took two things from it, truth and respect for all life.[9] Under the Military Training Act 1939 he was provisionally registered as a conscientious objector, and again under the National Service (Armed Forces) Act 1939, before being granted unconditional exemption from military service by a tribunal. In the meantime he undertook training in social relief work at the Quaker centre, Spicelands, Devon and served briefly as a hospital orderly.[6]

Sanger began studying for a PhD in October 1940 under N.W. "Bill" Pirie. His project was to investigate whether edible protein could be obtained from grass. After little more than a month Pirie left the department and Albert Neuberger became his adviser.[6] Sanger changed his research project to study the metabolism of lysine[10] and a more practical problem concerning the nitrogen of potatoes.[11] His thesis had the title, "The metabolism of the amino acid lysine in the animal body". He was examined by Charles Harington and Albert Charles Chibnall and awarded his doctorate in 1943.[6]

Research and career

 
Amino acid sequence of bovine insulin, with disulfide bridges shown in red.

Sequencing insulin

Neuberger moved to the National Institute for Medical Research in London, but Sanger stayed in Cambridge and in 1943 joined the group of Charles Chibnall, a protein chemist who had recently taken up the chair in the Department of Biochemistry.[12] Chibnall had already done some work on the amino acid composition of bovine insulin[13] and suggested that Sanger look at the amino groups in the protein. Insulin could be purchased from the pharmacy chain Boots and was one of the very few proteins that were available in a pure form. Up to this time Sanger had been funding himself. In Chibnall's group he was initially supported by the Medical Research Council and then from 1944 until 1951 by a Beit Memorial Fellowship for Medical Research.[5]

Sanger's first triumph was to determine the complete amino acid sequence of the two polypeptide chains of bovine insulin, A and B, in 1952 and 1951, respectively.[14][15] Prior to this it was widely assumed that proteins were somewhat amorphous. In determining these sequences, Sanger proved that proteins have a defined chemical composition.[6]

To get to this point, Sanger refined a partition chromatography method first developed by Richard Laurence Millington Synge and Archer John Porter Martin to determine the composition of amino acids in wool. Sanger used a chemical reagent 1-fluoro-2,4-dinitrobenzene (now, also known as Sanger's reagent, fluorodinitrobenzene, FDNB or DNFB), sourced from poisonous gas research by Bernhard Charles Saunders at the Chemistry Department at Cambridge University. Sanger's reagent proved effective at labelling the N-terminal amino group at one end of the polypeptide chain.[16] He then partially hydrolysed the insulin into short peptides, either with hydrochloric acid or using an enzyme such as trypsin. The mixture of peptides was fractionated in two dimensions on a sheet of filter paper, first by electrophoresis in one dimension and then, perpendicular to that, by chromatography in the other. The different peptide fragments of insulin, detected with ninhydrin, moved to different positions on the paper, creating a distinct pattern that Sanger called "fingerprints". The peptide from the N-terminus could be recognised by the yellow colour imparted by the FDNB label and the identity of the labelled amino acid at the end of the peptide determined by complete acid hydrolysis and discovering which dinitrophenyl-amino acid was there.[6]

By repeating this type of procedure Sanger was able to determine the sequences of the many peptides generated using different methods for the initial partial hydrolysis. These could then be assembled into the longer sequences to deduce the complete structure of insulin. Finally, because the A and B chains are physiologically inactive without the three linking disulfide bonds (two interchain, one intrachain on A), Sanger and coworkers determined their assignments in 1955.[17][18] Sanger's principal conclusion was that the two polypeptide chains of the protein insulin had precise amino acid sequences and, by extension, that every protein had a unique sequence. It was this achievement that earned him his first Nobel prize in Chemistry in 1958.[19] This discovery was crucial for the later sequence hypothesis of Crick for developing ideas of how DNA codes for proteins.[20]

Sequencing RNA

From 1951 Sanger was a member of the external staff of the Medical Research Council[5] and when they opened the Laboratory of Molecular Biology in 1962, he moved from his laboratories in the Biochemistry Department of the university to the top floor of the new building. He became head of the Protein Chemistry division.[6]

Prior to his move, Sanger began exploring the possibility of sequencing RNA molecules and began developing methods for separating ribonucleotide fragments generated with specific nucleases. This work he did while trying to refine the sequencing techniques he had developed during his work on insulin.[20]

The key challenge in the work was finding a pure piece of RNA to sequence. In the course of the work he discovered in 1964, with Kjeld Marcker, the formylmethionine tRNA which initiates protein synthesis in bacteria.[21] He was beaten in the race to be the first to sequence a tRNA molecule by a group led by Robert Holley from Cornell University, who published the sequence of the 77 ribonucleotides of alanine tRNA from Saccharomyces cerevisiae in 1965.[22] By 1967 Sanger's group had determined the nucleotide sequence of the 5S ribosomal RNA from Escherichia coli, a small RNA of 120 nucleotides.[23]

Sequencing DNA

Main article: DNA sequencing

Sanger then turned to sequencing DNA, which would require an entirely different approach. He looked at different ways of using DNA polymerase I from E. coli to copy single stranded DNA.[24] In 1975, together with Alan Coulson, he published a sequencing procedure using DNA polymerase with radiolabelled nucleotides that he called the "Plus and Minus" technique.[25][26] This involved two closely related methods that generated short oligonucleotides with defined 3' termini. These could be fractionated by electrophoresis on a polyacrylamide gel and visualised using autoradiography. The procedure could sequence up to 80 nucleotides in one go and was a big improvement on what had gone before, but was still very laborious. Nevertheless, his group were able to sequence most of the 5,386 nucleotides of the single-stranded bacteriophage φX174.[27] This was the first fully sequenced DNA-based genome. To their surprise they discovered that the coding regions of some of the genes overlapped with one another.[3]

In 1977 Sanger and colleagues introduced the "dideoxy" chain-termination method for sequencing DNA molecules, also known as the "Sanger method".[26][28] This was a major breakthrough and allowed long stretches of DNA to be rapidly and accurately sequenced. It earned him his second Nobel prize in Chemistry in 1980, which he shared with Walter Gilbert and Paul Berg.[29] The new method was used by Sanger and colleagues to sequence human mitochondrial DNA (16,569 base pairs)[30] and bacteriophage λ (48,502 base pairs).[31] The dideoxy method was eventually used to sequence the entire human genome.[32]

Postgraduate students

During the course of his career Sanger supervised more than ten PhD students, two of whom went on to also win Nobel Prizes. His first graduate student was Rodney Porter who joined the research group in 1947.[3] Porter later shared the 1972 Nobel Prize in Physiology or Medicine with Gerald Edelman for his work on the chemical structure of antibodies.[33] Elizabeth Blackburn studied for a PhD in Sanger's laboratory between 1971 and 1974.[3][34] She shared the 2009 Nobel Prize in Physiology or Medicine with Carol W. Greider and Jack W. Szostak for her work on telomeres and the action of telomerase.[35]

Sanger's rule

... anytime you get technical development that’s two to threefold or more efficient, accurate, cheaper, a whole range of experiments opens up.[36]

This rule should not be confused with Terence Sanger's rule, which is related to Oja's rule.

Awards and honours

As of 2015, Sanger is one of the only two people to have been awarded the Nobel Prize in Chemistry twice (the other being Karl Barry Sharpless in 2001 and 2022), and one of only five two-time Nobel laureates: The other four were Marie Curie (Physics, 1903 and Chemistry, 1911), Linus Pauling (Chemistry, 1954 and Peace, 1962), John Bardeen (twice Physics, 1956 and 1972), and Karl Barry Sharpless (twice Chemistry, 2001 and 2022).[4]

The Wellcome Trust Sanger Institute (formerly the Sanger Centre) is named in his honour.[3]

Personal life

Marriage and family

Sanger married Margaret Joan Howe (not to be confused with Margaret Sanger) in 1940. She died in 2012. They had three children — Robin, born in 1943, Peter born in 1946 and Sally Joan born in 1960.[5] He said that his wife had "contributed more to his work than anyone else by providing a peaceful and happy home."[42]

Later life

 
The Sanger Institute

Sanger retired in 1983, aged 65, to his home, "Far Leys", in Swaffham Bulbeck outside Cambridge.[3]

In 1992, the Wellcome Trust and the Medical Research Council founded the Sanger Centre (now the Sanger Institute), named after him.[43] The institute is on the Wellcome Trust Genome Campus near Hinxton, only a few miles from Sanger's home. He agreed to having the Centre named after him when asked by John Sulston, the founding director, but warned, "It had better be good."[43] It was opened by Sanger in person on 4 October 1993, with a staff of fewer than 50 people, and went on to take a leading role in the sequencing of the human genome.[43] The Institute now[when?] has over 900 people and is one of the world's largest genomic research centres.

Sanger said he found no evidence for a God so he became an agnostic.[44] In an interview published in the Times newspaper in 2000 Sanger is quoted as saying: "My father was a committed Quaker and I was brought up as a Quaker, and for them truth is very important. I drifted away from those beliefs – one is obviously looking for truth, but one needs some evidence for it. Even if I wanted to believe in God I would find it very difficult. I would need to see proof."[45]

He declined the offer of a knighthood, as he did not wish to be addressed as "Sir". He is quoted as saying, "A knighthood makes you different, doesn't it, and I don't want to be different." In 1986 he accepted admission to the Order of Merit, which can have only 24 living members.[42][44][45]

In 2007 the British Biochemical Society was given a grant by the Wellcome Trust to catalogue and preserve the 35 laboratory notebooks in which Sanger recorded his research from 1944 to 1983. In reporting this matter, Science noted that Sanger, "the most self-effacing person you could hope to meet", was spending his time gardening at his Cambridgeshire home.[46]

Sanger died in his sleep at Addenbrooke's Hospital in Cambridge on 19 November 2013.[42][47] As noted in his obituary, he had described himself as "just a chap who messed about in a lab",[48] and "academically not brilliant".[49]

Selected publications

  • Neuberger, A.; Sanger, F. (1942), "The nitrogen of the potato", Biochemical Journal, 36 (7–9): 662–671, doi:10.1042/bj0360662, PMC 1266851, PMID 16747571.
  • Neuberger, A.; Sanger, F. (1944), "The metabolism of lysine", Biochemical Journal, 38 (1): 119–125, doi:10.1042/bj0380119, PMC 1258037, PMID 16747737.
  • Sanger, F. (1945), "The free amino groups of insulin", Biochemical Journal, 39 (5): 507–515, doi:10.1042/bj0390507, PMC 1258275, PMID 16747948.
  • Sanger, F. (1947), "Oxidation of insulin by performic acid", Nature, 160 (4061): 295–296, Bibcode:1947Natur.160..295S, doi:10.1038/160295b0, PMID 20344639, S2CID 4127677.
  • Porter, R.R.; Sanger, F. (1948), "The free amino groups of haemoglobins", Biochemical Journal, 42 (2): 287–294, doi:10.1042/bj0420287, PMC 1258669, PMID 16748281.
  • Sanger, F. (1949a), "Fractionation of oxidized insulin", Biochemical Journal, 44 (1): 126–128, doi:10.1042/bj0440126, PMC 1274818, PMID 16748471.
  • Sanger, F. (1949b), "The terminal peptides of insulin", Biochemical Journal, 45 (5): 563–574, doi:10.1042/bj0450563, PMC 1275055, PMID 15396627.
  • Sanger, F.; Tuppy, H. (1951a), "The amino-acid sequence in the phenylalanyl chain of insulin. 1. The identification of lower peptides from partial hydrolysates", Biochemical Journal, 49 (4): 463–481, doi:10.1042/bj0490463, PMC 1197535, PMID 14886310.
  • Sanger, F.; Tuppy, H. (1951b), "The amino-acid sequence in the phenylalanyl chain of insulin. 2. The investigation of peptides from enzymic hydrolysates", Biochemical Journal, 49 (4): 481–490, doi:10.1042/bj0490481, PMC 1197536, PMID 14886311.
  • Sanger, F.; Thompson, E.O.P. (1953a), "The amino-acid sequence in the glycyl chain of insulin. 1. The identification of lower peptides from partial hydrolysates", Biochemical Journal, 53 (3): 353–366, doi:10.1042/bj0530353, PMC 1198157, PMID 13032078.
  • Sanger, F.; Thompson, E.O.P. (1953b), "The amino-acid sequence in the glycyl chain of insulin. 2. The investigation of peptides from enzymic hydrolysates", Biochemical Journal, 53 (3): 366–374, doi:10.1042/bj0530366, PMC 1198158, PMID 13032079.
  • Sanger, F.; Thompson, E.O.P.; Kitai, R. (1955), "The amide groups of insulin", Biochemical Journal, 59 (3): 509–518, doi:10.1042/bj0590509, PMC 1216278, PMID 14363129.
  • Ryle, A.P.; Sanger, F.; Smith, L.F.; Kitai, R. (1955), "The disulphide bonds of insulin", Biochemical Journal, 60 (4): 541–556, doi:10.1042/bj0600541, PMC 1216151, PMID 13249947.
  • Brown, H.; Sanger, F.; Kitai, R. (1955), "The structure of pig and sheep insulins", Biochemical Journal, 60 (4): 556–565, doi:10.1042/bj0600556, PMC 1216152, PMID 13249948.
  • Sanger, F. (1959), "Chemistry of Insulin: determination of the structure of insulin opens the way to greater understanding of life processes", Science, 129 (3359): 1340–1344, Bibcode:1959Sci...129.1340G, doi:10.1126/science.129.3359.1340, PMID 13658959.
  • Milstein, C.; Sanger, F. (1961), "An amino acid sequence in the active centre of phosphoglucomutase", Biochemical Journal, 79 (3): 456–469, doi:10.1042/bj0790456, PMC 1205670, PMID 13771000.
  • Marcker, K.; Sanger, F. (1964), "N-formyl-methionyl-S-RNA", Journal of Molecular Biology, 8 (6): 835–840, doi:10.1016/S0022-2836(64)80164-9, PMID 14187409.
  • Sanger, F.; Brownlee, G.G.; Barrell, B.G. (1965), "A two-dimensional fractionation procedure for radioactive nucleotides", Journal of Molecular Biology, 13 (2): 373–398, doi:10.1016/S0022-2836(65)80104-8, PMID 5325727.
  • Brownlee, G.G.; Sanger, F.; Barrell, B.G. (1967), "Nucleotide sequence of 5S-ribosomal RNA from Escherichia coli", Nature, 215 (5102): 735–736, Bibcode:1967Natur.215..735B, doi:10.1038/215735a0, PMID 4862513, S2CID 4270186.
  • Brownlee, G.G.; Sanger, F. (1967), "Nucleotide sequences from the low molecular weight ribosomal RNA of Escherichia coli", Journal of Molecular Biology, 23 (3): 337–353, doi:10.1016/S0022-2836(67)80109-8, PMID 4291728.
  • Brownlee, G.G.; Sanger, F.; Barrell, B.G. (1968), "The sequence of 5S ribosomal ribonucleic acid", Journal of Molecular Biology, 34 (3): 379–412, doi:10.1016/0022-2836(68)90168-X, PMID 4938553.
  • Adams, J.M.; Jeppesen, P.G.; Sanger, F.; Barrell, B.G. (1969), "Nucleotide sequence from the coat protein cistron of R17 bacteriophage RNA", Nature, 223 (5210): 1009–1014, Bibcode:1969Natur.223.1009A, doi:10.1038/2231009a0, PMID 5811898, S2CID 4152602.
  • Barrell, B.G.; Sanger, F. (1969), "The sequence of phenylalanine tRNA from E. coli", FEBS Letters, 3 (4): 275–278, doi:10.1016/0014-5793(69)80157-2, PMID 11947028, S2CID 34155866.
  • Jeppesen, P.G.; Barrell, B.G.; Sanger, F.; Coulson, A.R. (1972), "Nucleotide sequences of two fragments from the coat-protein cistron of bacteriophage R17 ribonucleic acid", Biochemical Journal, 128 (5): 993–1006, doi:10.1042/bj1280993h, PMC 1173988, PMID 4566195.
  • Sanger, F.; Donelson, J.E.; Coulson, A.R.; Kössel, H.; Fischer, D. (1973), "Use of DNA Polymerase I Primed by a Synthetic Oligonucleotide to Determine a Nucleotide Sequence in Phage f1 DNA", Proceedings of the National Academy of Sciences USA, 70 (4): 1209–1213, Bibcode:1973PNAS...70.1209S, doi:10.1073/pnas.70.4.1209, PMC 433459, PMID 4577794.
  • Sanger, F.; Coulson, A.R. (1975), "A rapid method for determining sequences in DNA by primed synthesis with DNA polymerase", Journal of Molecular Biology, 94 (3): 441–448, doi:10.1016/0022-2836(75)90213-2, PMID 1100841.
  • Sanger, F.; Nicklen, S.; Coulson, A.R. (1977), "DNA sequencing with chain-terminating inhibitors", Proceedings of the National Academy of Sciences USA, 74 (12): 5463–5467, Bibcode:1977PNAS...74.5463S, doi:10.1073/pnas.74.12.5463, PMC 431765, PMID 271968. According to the Institute for Scientific Information (ISI) database, by October 2010 this paper had been cited over 64,000 times.
  • Sanger, F.; Air, G.M.; Barrell, B.G.; Brown, N.L.; Coulson, A.R.; Fiddes, C.A.; Hutchinson, C.A.; Slocombe, P.M.; Smith, M. (1977), "Nucleotide sequence of bacteriophage φX174 DNA", Nature, 265 (5596): 687–695, Bibcode:1977Natur.265..687S, doi:10.1038/265687a0, PMID 870828, S2CID 4206886.
  • Sanger, F.; Coulson, A.R. (1978), "The use of thin acrylamide gels for DNA sequencing", FEBS Letters, 87 (1): 107–110, doi:10.1016/0014-5793(78)80145-8, PMID 631324, S2CID 1620755.
  • Sanger, F.; Coulson, A.R.; Barrell, B.G.; Smith, A.J.; Roe, B.A. (1980), "Cloning in single-stranded bacteriophage as an aid to rapid DNA sequencing", Journal of Molecular Biology, 143 (2): 161–178, doi:10.1016/0022-2836(80)90196-5, PMID 6260957.
  • Anderson, S.; Bankier, A.T.; Barrell, B.G.; De Bruijn, M.H.; Coulson, A.R.; Drouin, J.; Eperon, I.C.; Nierlich, D.P.; Roe, B.A.; Sanger, F.; Schreier, P.H.; Smith, A.J.; Staden, R.; Young, I.G. (1981), "Sequence and organization of the human mitochondrial genome", Nature, 290 (5806): 457–465, Bibcode:1981Natur.290..457A, doi:10.1038/290457a0, PMID 7219534, S2CID 4355527.
  • Anderson, S.; De Bruijn, M.H.; Coulson, A.R.; Eperon, I.C.; Sanger, F.; Young, I.G. (1982), "Complete sequence of bovine mitochondrial DNA. Conserved features of the mammalian mitochondrial genome", Journal of Molecular Biology, 156 (4): 683–717, doi:10.1016/0022-2836(82)90137-1, PMID 7120390.
  • Sanger, F.; Coulson, A.R.; Hong, G.F.; Hill, D.F.; Petersen, G.B. (1982), "Nucleotide sequence of bacteriophage λ DNA", Journal of Molecular Biology, 162 (4): 729–773, doi:10.1016/0022-2836(82)90546-0, PMID 6221115.
  • Sanger, F. (1988), "Sequences, sequences, and sequences", Annual Review of Biochemistry, 57: 1–28, doi:10.1146/annurev.bi.57.070188.000245, PMID 2460023.

References

Citations

  1. ^ "Seven days: 22–28 November 2013". Nature. 503 (7477): 442–443. 2013. Bibcode:2013Natur.503..442.. doi:10.1038/503442a.
  2. ^ Allen, A.K.; Muir, H.M. (2001). "Albert Neuberger. 15 April 1908 – 14 August 1996". Biographical Memoirs of Fellows of the Royal Society. 47: 369–382. doi:10.1098/rsbm.2001.0021. JSTOR 770373. PMID 15124648. S2CID 72943723.
  3. ^ a b c d e f g h i j k l m n o p q r s Brownlee, George G. (2015). "Frederick Sanger CBE CH OM. 13 August 1918 – 19 November 2013". Biographical Memoirs of Fellows of the Royal Society. 61: 437–466. doi:10.1098/rsbm.2015.0013.
  4. ^ a b "Nobel Prize Facts". Nobelprize.org. Retrieved 1 September 2015.
  5. ^ a b c d "The Nobel Prize in Chemistry 1958: Frederick Sanger – biography". Nobelprize.org. Retrieved 10 August 2020.
  6. ^ a b c d e f g h i j . Biochemical Society, Edina – Film & Sound Online. 9 October 1992. Archived from the original on 13 March 2014. Retrieved 29 April 2013.. Subscription required. A 200 min interview divided into 44 segments. Notes give the content of each segment.[dead link]
  7. ^ Marks, Lara. "Sanger's early life: From the cradle to the laboratory". The path to DNA sequencing: The life and work of Fred Sanger. What is Biotechnology. Retrieved 1 September 2015.
  8. ^ Jeffers, Joe S. (2017). Frederick Sanger Two-Time Nobel Laureate in Chemistry. Springer International Publishing.
  9. ^ "The Nobel Prize in Chemistry 1980".
  10. ^ Sanger, Frederick (1944). The metabolism of the amino acid lysine in the animal body (PhD thesis). University of Cambridge.
  11. ^ Neuberger & Sanger 1942; Neuberger & Sanger 1944
  12. ^ "Frederick Sanger, Ph.D. Biography and Interview". www.achievement.org. American Academy of Achievement.
  13. ^ Chibnall, A. C. (1942). "Bakerian Lecture: Amino-Acid Analysis and the Structure of Proteins" (PDF). Proceedings of the Royal Society B: Biological Sciences. 131 (863): 136–160. Bibcode:1942RSPSB.131..136C. doi:10.1098/rspb.1942.0021. S2CID 85124201. Section on insulin starts on page 153.
  14. ^ Sanger & Tuppy 1951a; Sanger & Tuppy 1951b; Sanger & Thompson 1953a; Sanger & Thompson 1953b
  15. ^ Sanger, F. (1958), Nobel lecture: The chemistry of insulin (PDF), Nobelprize.org, retrieved 18 October 2010. Sanger's Nobel lecture was also published in Science: Sanger 1959
  16. ^ Marks, Lara. "Sequencing proteins: Insulin". The path to DNA sequencing: The life and work of Fred Sanger. What is Biotechnology. Retrieved 1 September 2015.
  17. ^ Ryle et al. 1955.
  18. ^ Stretton, A.O. (2002). "The first sequence. Fred Sanger and insulin". Genetics. 162 (2): 527–532. doi:10.1093/genetics/162.2.527. PMC 1462286. PMID 12399368.
  19. ^ a b "The Nobel Prize in Chemistry 1958: Frederick Sanger". Nobelprize.org. Retrieved 8 October 2010.
  20. ^ a b Marks, Lara. "The path to sequencing nucleic acids". The path to DNA sequencing: The life and work of Fred Sanger. What is Biotechnology. Retrieved 1 September 2015.
  21. ^ Marcker & Sanger 1964
  22. ^ Holley, R. W.; Apgar, J.; Everett, G. A.; Madison, J. T.; Marquisee, M.; Merrill, S. H.; Penswick, J. R.; Zamir, A. (1965). "Structure of a Ribonucleic Acid". Science. 147 (3664): 1462–1465. Bibcode:1965Sci...147.1462H. doi:10.1126/science.147.3664.1462. PMID 14263761. S2CID 40989800.
  23. ^ Brownlee, Sanger & Barrell 1967; Brownlee, Sanger & Barrell 1968
  24. ^ Sanger et al. 1973
  25. ^ Sanger & Coulson 1975
  26. ^ a b Sanger, F. (1980). "Nobel lecture: Determination of nucleotide sequences in DNA" (PDF). Nobelprize.org. Retrieved 15 September 2019.
  27. ^ Sanger et al. 1977
  28. ^ a b Sanger, F.; Nicklen, S.; Coulson, A.R. (1977), "DNA sequencing with chain-terminating inhibitors", Proceedings of the National Academy of Sciences USA, 74 (12): 5463–5467, Bibcode:1977PNAS...74.5463S, doi:10.1073/pnas.74.12.5463, PMC 431765, PMID 271968
  29. ^ a b "The Nobel Prize in Chemistry 1980: Paul Berg, Walter Gilbert, Frederick Sanger". Nobelprize.org. Retrieved 8 October 2010.
  30. ^ Anderson et al. 1981
  31. ^ Sanger et al. 1982
  32. ^ Walker, John (2014). "Frederick Sanger (1918–2013) Double Nobel-prizewinning genomics pioneer". Nature. 505 (7481): 27. Bibcode:2014Natur.505...27W. doi:10.1038/505027a. PMID 24380948.
  33. ^ "The Nobel Prize in Physiology or Medicine 1972". Nobelprize.org. Retrieved 1 September 2015.
  34. ^ Blackburn, E. H. (1974). Sequence studies on bacteriophage ØX174 DNA by transcription (PhD thesis). University of Cambridge.
  35. ^ "The Nobel Prize in Physiology or Medicine 2009". Nobelprize.org. Retrieved 1 September 2015.
  36. ^ "Schlessinger, David" (PDF). National Human Genome Research Institute (NHGRI, genome.gov). March 2018.
  37. ^ . Association of Biomolecular Resource facilities. Archived from the original on 6 August 2020. Retrieved 11 August 2020.
  38. ^ "Golden Plate Awardees of the American Academy of Achievement". www.achievement.org. American Academy of Achievement.
  39. ^ "Summit Overview Photo". Awards Council member and Nobel Prize laureate Dr. Charles H. Townes presenting the American Academy of Achievement’s Golden Plate Award to British biochemist Dr. Frederick Sanger, recipient of two Nobel Prizes in Chemistry, at the 2000 Summit in Hampton Court.
  40. ^ "2016 Awardees". American Chemical Society, Division of the History of Chemistry. University of Illinois at Urbana-Champaign School of Chemical Sciences. 2016. Retrieved 14 June 2017.
  41. ^ "Citation for Chemical Breakthrough Award" (PDF). American Chemical Society, Division of the History of Chemistry. University of Illinois at Urbana-Champaign School of Chemical Sciences. 2016. Retrieved 14 June 2017.
  42. ^ a b c "Frederick Sanger, OM". The Telegraph. 20 November 2013. Archived from the original on 12 January 2022. Retrieved 20 November 2013.
  43. ^ a b c . Wellcome Trust Sanger Institute. Archived from the original on 7 April 2011. Retrieved 12 October 2010.
  44. ^ a b Hargittai, István (April 1999). "Interview: Frederick Sanger". The Chemical Intelligencer. New York: Springer-Verlag. 4 (2): 6–11.. This interview, which took place on 16 September 1997, was republished in Hargittai, István (2002). "Chapter 5: Frederick Sanger". Candid science II: conversations with famous biomedical scientists. London: Imperial College Press. pp. 73–83. ISBN 978-1-86094-288-4.
  45. ^ a b Ahuja, Anjana (12 January 2000). . The Times. London. p. 40. Archived from the original on 11 December 2008. Retrieved 18 October 2010 – via warwick.ac.uk.
  46. ^ Bhattachjee, Yudhijit, ed. (2007). "Newsmakers: A Life in Science". Science. 317 (5840): 879. doi:10.1126/science.317.5840.879e. S2CID 220092058.
  47. ^ "Frederick Sanger: Nobel Prize winner dies at 95". BBC.co.uk. 20 November 2013. Retrieved 20 November 2013.
  48. ^ "Frederick Sanger: Unassuming British biochemist whose pivotal and far-reaching discoveries made him one of a handful of double Nobel prizewinners". The Times. London. 21 November 2013. p. 63.
  49. ^ "Frederick Sanger's achievements cannot be overstated". The Conversation. 21 November 2013.

Bibliography

  • Brownlee, George G. (2014). Fred Sanger, double Nobel laureate: a biography. Cambridge, UK: Cambridge University Press. ISBN 978-1-107-08334-9. Chapters 4-6 contain the 1992 interview that the author conducted with Sanger.
  • Finch, John (2008), A Nobel Fellow on every floor: a history of the Medical Research Council Laboratory of Molecular Biology, Cambridge: Medical Research Council, ISBN 978-1-84046-940-0.
  • García-Sancho, Miguel (2010). "A new insight into Sanger's development of sequencing: from proteins to DNA, 1943–1977" (PDF). Journal of the History of Biology. 43 (2): 265–323. doi:10.1007/s10739-009-9184-1. hdl:20.500.11820/e4febe48-772a-4f47-a1c5-a5ca89505367. PMID 20665230. S2CID 1134280.
  • Sanger, F.; Dowding, M. (1996), Selected Papers of Frederick Sanger: with commentaries, Singapore: World Scientific, ISBN 978-981-02-2430-1.
  • Interviews with Nobel Prize–winning scientists: Dr Frederick Sanger, British Broadcasting Corporation, c. 1985. Interviewed by Lewis Wolpert. Duration 1 hour.

External links

 
Wikimedia Commons has media related to Frederick Sanger.
  • The Sanger Institute
  • About the 1958 Nobel Prize
  • About the 1980 Nobel Prize
  • 2001 Video Documentary by The Vega Science Trust
  • Portraits of Frederick Sanger at the National Portrait Gallery, London  
  • Frederick Sanger interviewed by Alan Macfarlane, 24 August 2007 (video), also available on Video on YouTube. Duration 57 minutes.
  • Frederick Sanger archive collection – Wellcome Library finding aid for the digitised collection.
  • Frederick Sanger on Nobelprize.org  

January 08, 2023
frederick, sanger, august, 1918, november, 2013, english, biochemist, received, nobel, prize, chemistry, twice, faaborn, 1918, august, 1918rendcomb, gloucestershire, englanddied19, november, 2013, 2013, aged, cambridge, england, alma, materuniversity, cambridg. Frederick Sanger OM CH CBE FRS FAA ˈ s ae ŋ er 13 August 1918 19 November 2013 was an English biochemist who received the Nobel Prize in Chemistry twice Frederick SangerOM CH CBE FRS FAABorn 1918 08 13 13 August 1918Rendcomb Gloucestershire EnglandDied19 November 2013 2013 11 19 aged 95 Cambridge England 1 Alma materUniversity of Cambridge PhD Known forDetermining the amino acid sequence of insulin Sanger sequencing Sanger CentreAwardsNobel Prize in Chemistry 1958 Foreign Associate of the National Academy of Sciences 1967 Royal Medal 1969 Gairdner Foundation International Award 1971 William Bate Hardy Prize 1976 Copley Medal 1977 Louisa Gross Horwitz Prize 1979 Nobel Prize in Chemistry 1980 Scientific careerFieldsBiochemistryInstitutionsUniversity of Cambridge Laboratory of Molecular BiologyThesisThe metabolism of the amino acid lysine in the animal body 1943 Doctoral advisorAlbert Neuberger 2 Doctoral studentsGeorge Brownlee 3 Elizabeth Blackburn Rodney PorterHe won the 1958 Chemistry Prize for determining the amino acid sequence of insulin and numerous other proteins demonstrating in the process that each had a unique definite structure this was a foundational discovery for the central dogma of molecular biology At the newly constructed Laboratory of Molecular Biology in Cambridge he developed and subsequently refined the first ever DNA sequencing technique which vastly expanded the number of feasible experiments in molecular biology and remains in widespread use today The breakthrough earned him the 1980 Nobel Prize in Chemistry which he shared with Walter Gilbert and Paul Berg He is one of only three people to have won multiple Nobel Prizes in the same category the others being John Bardeen in physics and Karl Barry Sharpless in chemistry 4 and one of five persons with two Nobel Prizes Contents 1 Early life and education 2 Research and career 2 1 Sequencing insulin 2 2 Sequencing RNA 2 3 Sequencing DNA 2 4 Postgraduate students 2 5 Sanger s rule 2 6 Awards and honours 3 Personal life 3 1 Marriage and family 3 2 Later life 4 Selected publications 5 References 5 1 Citations 5 2 Bibliography 6 External linksEarly life and education EditFrederick Sanger was born on 13 August 1918 in Rendcomb a small village in Gloucestershire England the second son of Frederick Sanger a general practitioner and his wife Cicely Sanger nee Crewdson 5 He was one of three children His brother Theodore was only a year older while his sister May Mary was five years younger 6 His father had worked as an Anglican medical missionary in China but returned to England because of ill health He was 40 in 1916 when he married Cicely who was four years younger Sanger s father converted to Quakerism soon after his two sons were born and brought up the children as Quakers Sanger s mother was the daughter of an affluent cotton manufacturer and had a Quaker background but was not a Quaker 6 When Sanger was around five years old the family moved to the small village of Tanworth in Arden in Warwickshire The family was reasonably wealthy and employed a governess to teach the children In 1927 at the age of nine he was sent to the Downs School a residential preparatory school run by Quakers near Malvern His brother Theo was a year ahead of him at the same school In 1932 at the age of 14 he was sent to the recently established Bryanston School in Dorset This used the Dalton system and had a more liberal regime which Sanger much preferred At the school he liked his teachers and particularly enjoyed scientific subjects 6 Able to complete his School Certificate a year early for which he was awarded seven credits Sanger was able to spend most of his last year of school experimenting in the laboratory alongside his chemistry master Geoffrey Ordish who had originally studied at Cambridge University and been a researcher in the Cavendish Laboratory Working with Ordish made a refreshing change from sitting and studying books and awakened Sanger s desire to pursue a scientific career 7 In 1935 prior to heading off to college Sanger was sent to Schule Schloss Salem in southern Germany on an exchange program The school placed a heavy emphasis on athletics which caused Sanger to be much further ahead in the course material compared to the other students He was shocked to learn that each day was started with readings from Hitler s Mein Kampf followed by a Sieg Heil salute 8 In 1936 Sanger went to St John s College Cambridge to study natural sciences His father had attended the same college For Part I of his Tripos he took courses in physics chemistry biochemistry and mathematics but struggled with physics and mathematics Many of the other students had studied more mathematics at school In his second year he replaced physics with physiology He took three years to obtain his Part I For his Part II he studied biochemistry and obtained a 1st Class Honours Biochemistry was a relatively new department founded by Gowland Hopkins with enthusiastic lecturers who included Malcolm Dixon Joseph Needham and Ernest Baldwin 6 Both his parents died from cancer during his first two years at Cambridge His father was 60 and his mother was 58 As an undergraduate Sanger s beliefs were strongly influenced by his Quaker upbringing He was a pacifist and a member of the Peace Pledge Union It was through his involvement with the Cambridge Scientists Anti War Group that he met his future wife Joan Howe who was studying economics at Newnham College They courted while he was studying for his Part II exams and married after he had graduated in December 1940 Sanger although brought up and influenced by his religious upbringing later began to lose sight of his Quaker related ways He began to see the world through a more scientific lens and with the growth of his research and scientific development he slowly drifted farther from the faith he grew up with He has nothing but respect for the religious and states he took two things from it truth and respect for all life 9 Under the Military Training Act 1939 he was provisionally registered as a conscientious objector and again under the National Service Armed Forces Act 1939 before being granted unconditional exemption from military service by a tribunal In the meantime he undertook training in social relief work at the Quaker centre Spicelands Devon and served briefly as a hospital orderly 6 Sanger began studying for a PhD in October 1940 under N W Bill Pirie His project was to investigate whether edible protein could be obtained from grass After little more than a month Pirie left the department and Albert Neuberger became his adviser 6 Sanger changed his research project to study the metabolism of lysine 10 and a more practical problem concerning the nitrogen of potatoes 11 His thesis had the title The metabolism of the amino acid lysine in the animal body He was examined by Charles Harington and Albert Charles Chibnall and awarded his doctorate in 1943 6 Research and career Edit Amino acid sequence of bovine insulin with disulfide bridges shown in red Sequencing insulin Edit Neuberger moved to the National Institute for Medical Research in London but Sanger stayed in Cambridge and in 1943 joined the group of Charles Chibnall a protein chemist who had recently taken up the chair in the Department of Biochemistry 12 Chibnall had already done some work on the amino acid composition of bovine insulin 13 and suggested that Sanger look at the amino groups in the protein Insulin could be purchased from the pharmacy chain Boots and was one of the very few proteins that were available in a pure form Up to this time Sanger had been funding himself In Chibnall s group he was initially supported by the Medical Research Council and then from 1944 until 1951 by a Beit Memorial Fellowship for Medical Research 5 Sanger s first triumph was to determine the complete amino acid sequence of the two polypeptide chains of bovine insulin A and B in 1952 and 1951 respectively 14 15 Prior to this it was widely assumed that proteins were somewhat amorphous In determining these sequences Sanger proved that proteins have a defined chemical composition 6 To get to this point Sanger refined a partition chromatography method first developed by Richard Laurence Millington Synge and Archer John Porter Martin to determine the composition of amino acids in wool Sanger used a chemical reagent 1 fluoro 2 4 dinitrobenzene now also known as Sanger s reagent fluorodinitrobenzene FDNB or DNFB sourced from poisonous gas research by Bernhard Charles Saunders at the Chemistry Department at Cambridge University Sanger s reagent proved effective at labelling the N terminal amino group at one end of the polypeptide chain 16 He then partially hydrolysed the insulin into short peptides either with hydrochloric acid or using an enzyme such as trypsin The mixture of peptides was fractionated in two dimensions on a sheet of filter paper first by electrophoresis in one dimension and then perpendicular to that by chromatography in the other The different peptide fragments of insulin detected with ninhydrin moved to different positions on the paper creating a distinct pattern that Sanger called fingerprints The peptide from the N terminus could be recognised by the yellow colour imparted by the FDNB label and the identity of the labelled amino acid at the end of the peptide determined by complete acid hydrolysis and discovering which dinitrophenyl amino acid was there 6 By repeating this type of procedure Sanger was able to determine the sequences of the many peptides generated using different methods for the initial partial hydrolysis These could then be assembled into the longer sequences to deduce the complete structure of insulin Finally because the A and B chains are physiologically inactive without the three linking disulfide bonds two interchain one intrachain on A Sanger and coworkers determined their assignments in 1955 17 18 Sanger s principal conclusion was that the two polypeptide chains of the protein insulin had precise amino acid sequences and by extension that every protein had a unique sequence It was this achievement that earned him his first Nobel prize in Chemistry in 1958 19 This discovery was crucial for the later sequence hypothesis of Crick for developing ideas of how DNA codes for proteins 20 Sequencing RNA Edit From 1951 Sanger was a member of the external staff of the Medical Research Council 5 and when they opened the Laboratory of Molecular Biology in 1962 he moved from his laboratories in the Biochemistry Department of the university to the top floor of the new building He became head of the Protein Chemistry division 6 Prior to his move Sanger began exploring the possibility of sequencing RNA molecules and began developing methods for separating ribonucleotide fragments generated with specific nucleases This work he did while trying to refine the sequencing techniques he had developed during his work on insulin 20 The key challenge in the work was finding a pure piece of RNA to sequence In the course of the work he discovered in 1964 with Kjeld Marcker the formylmethionine tRNA which initiates protein synthesis in bacteria 21 He was beaten in the race to be the first to sequence a tRNA molecule by a group led by Robert Holley from Cornell University who published the sequence of the 77 ribonucleotides of alanine tRNA from Saccharomyces cerevisiae in 1965 22 By 1967 Sanger s group had determined the nucleotide sequence of the 5S ribosomal RNA from Escherichia coli a small RNA of 120 nucleotides 23 Sequencing DNA Edit Main article DNA sequencing Sanger then turned to sequencing DNA which would require an entirely different approach He looked at different ways of using DNA polymerase I from E coli to copy single stranded DNA 24 In 1975 together with Alan Coulson he published a sequencing procedure using DNA polymerase with radiolabelled nucleotides that he called the Plus and Minus technique 25 26 This involved two closely related methods that generated short oligonucleotides with defined 3 termini These could be fractionated by electrophoresis on a polyacrylamide gel and visualised using autoradiography The procedure could sequence up to 80 nucleotides in one go and was a big improvement on what had gone before but was still very laborious Nevertheless his group were able to sequence most of the 5 386 nucleotides of the single stranded bacteriophage fX174 27 This was the first fully sequenced DNA based genome To their surprise they discovered that the coding regions of some of the genes overlapped with one another 3 In 1977 Sanger and colleagues introduced the dideoxy chain termination method for sequencing DNA molecules also known as the Sanger method 26 28 This was a major breakthrough and allowed long stretches of DNA to be rapidly and accurately sequenced It earned him his second Nobel prize in Chemistry in 1980 which he shared with Walter Gilbert and Paul Berg 29 The new method was used by Sanger and colleagues to sequence human mitochondrial DNA 16 569 base pairs 30 and bacteriophage l 48 502 base pairs 31 The dideoxy method was eventually used to sequence the entire human genome 32 Postgraduate students Edit During the course of his career Sanger supervised more than ten PhD students two of whom went on to also win Nobel Prizes His first graduate student was Rodney Porter who joined the research group in 1947 3 Porter later shared the 1972 Nobel Prize in Physiology or Medicine with Gerald Edelman for his work on the chemical structure of antibodies 33 Elizabeth Blackburn studied for a PhD in Sanger s laboratory between 1971 and 1974 3 34 She shared the 2009 Nobel Prize in Physiology or Medicine with Carol W Greider and Jack W Szostak for her work on telomeres and the action of telomerase 35 Sanger s rule Edit anytime you get technical development that s two to threefold or more efficient accurate cheaper a whole range of experiments opens up 36 This rule should not be confused with Terence Sanger s rule which is related to Oja s rule Awards and honours Edit As of 2015 update Sanger is one of the only two people to have been awarded the Nobel Prize in Chemistry twice the other being Karl Barry Sharpless in 2001 and 2022 and one of only five two time Nobel laureates The other four were Marie Curie Physics 1903 and Chemistry 1911 Linus Pauling Chemistry 1954 and Peace 1962 John Bardeen twice Physics 1956 and 1972 and Karl Barry Sharpless twice Chemistry 2001 and 2022 4 Elected Fellow of the Royal Society FRS in 1954 3 Commander of the Order of the British Empire 1963 3 Order of the Companions of Honour 1981 3 Order of Merit 1986 3 Corresponding Fellow of the Australian Academy of Science 1982 3 William Bate Hardy Prize 1976 3 Nobel Prize in Chemistry 1958 1980 19 29 Corday Morgan Medal 1951 3 Royal Medal 1969 3 Gairdner Foundation International Award 1971 3 Copley Medal 1977 3 G W Wheland Award 1978 3 Louisa Gross Horwitz Prize of Columbia University 1979 3 Albert Lasker Award for Basic Medical Research 1979 3 Association of Biomolecular Resource Facilities Award 1994 37 Golden Plate Award of the American Academy of Achievement 2000 38 39 Citation for Chemical Breakthrough Award from the Division of History of Chemistry of the American Chemical Society 2016 40 41 28 The Wellcome Trust Sanger Institute formerly the Sanger Centre is named in his honour 3 Personal life EditMarriage and family Edit Sanger married Margaret Joan Howe not to be confused with Margaret Sanger in 1940 She died in 2012 They had three children Robin born in 1943 Peter born in 1946 and Sally Joan born in 1960 5 He said that his wife had contributed more to his work than anyone else by providing a peaceful and happy home 42 Later life Edit The Sanger Institute Sanger retired in 1983 aged 65 to his home Far Leys in Swaffham Bulbeck outside Cambridge 3 In 1992 the Wellcome Trust and the Medical Research Council founded the Sanger Centre now the Sanger Institute named after him 43 The institute is on the Wellcome Trust Genome Campus near Hinxton only a few miles from Sanger s home He agreed to having the Centre named after him when asked by John Sulston the founding director but warned It had better be good 43 It was opened by Sanger in person on 4 October 1993 with a staff of fewer than 50 people and went on to take a leading role in the sequencing of the human genome 43 The Institute now when has over 900 people and is one of the world s largest genomic research centres Sanger said he found no evidence for a God so he became an agnostic 44 In an interview published in the Times newspaper in 2000 Sanger is quoted as saying My father was a committed Quaker and I was brought up as a Quaker and for them truth is very important I drifted away from those beliefs one is obviously looking for truth but one needs some evidence for it Even if I wanted to believe in God I would find it very difficult I would need to see proof 45 He declined the offer of a knighthood as he did not wish to be addressed as Sir He is quoted as saying A knighthood makes you different doesn t it and I don t want to be different In 1986 he accepted admission to the Order of Merit which can have only 24 living members 42 44 45 In 2007 the British Biochemical Society was given a grant by the Wellcome Trust to catalogue and preserve the 35 laboratory notebooks in which Sanger recorded his research from 1944 to 1983 In reporting this matter Science noted that Sanger the most self effacing person you could hope to meet was spending his time gardening at his Cambridgeshire home 46 Sanger died in his sleep at Addenbrooke s Hospital in Cambridge on 19 November 2013 42 47 As noted in his obituary he had described himself as just a chap who messed about in a lab 48 and academically not brilliant 49 Selected publications EditNeuberger A Sanger F 1942 The nitrogen of the potato Biochemical Journal 36 7 9 662 671 doi 10 1042 bj0360662 PMC 1266851 PMID 16747571 Neuberger A Sanger F 1944 The metabolism of lysine Biochemical Journal 38 1 119 125 doi 10 1042 bj0380119 PMC 1258037 PMID 16747737 Sanger F 1945 The free amino groups of insulin Biochemical Journal 39 5 507 515 doi 10 1042 bj0390507 PMC 1258275 PMID 16747948 Sanger F 1947 Oxidation of insulin by performic acid Nature 160 4061 295 296 Bibcode 1947Natur 160 295S doi 10 1038 160295b0 PMID 20344639 S2CID 4127677 Porter R R Sanger F 1948 The free amino groups of haemoglobins Biochemical Journal 42 2 287 294 doi 10 1042 bj0420287 PMC 1258669 PMID 16748281 Sanger F 1949a Fractionation of oxidized insulin Biochemical Journal 44 1 126 128 doi 10 1042 bj0440126 PMC 1274818 PMID 16748471 Sanger F 1949b The terminal peptides of insulin Biochemical Journal 45 5 563 574 doi 10 1042 bj0450563 PMC 1275055 PMID 15396627 Sanger F Tuppy H 1951a The amino acid sequence in the phenylalanyl chain of insulin 1 The identification of lower peptides from partial hydrolysates Biochemical Journal 49 4 463 481 doi 10 1042 bj0490463 PMC 1197535 PMID 14886310 Sanger F Tuppy H 1951b The amino acid sequence in the phenylalanyl chain of insulin 2 The investigation of peptides from enzymic hydrolysates Biochemical Journal 49 4 481 490 doi 10 1042 bj0490481 PMC 1197536 PMID 14886311 Sanger F Thompson E O P 1953a The amino acid sequence in the glycyl chain of insulin 1 The identification of lower peptides from partial hydrolysates Biochemical Journal 53 3 353 366 doi 10 1042 bj0530353 PMC 1198157 PMID 13032078 Sanger F Thompson E O P 1953b The amino acid sequence in the glycyl chain of insulin 2 The investigation of peptides from enzymic hydrolysates Biochemical Journal 53 3 366 374 doi 10 1042 bj0530366 PMC 1198158 PMID 13032079 Sanger F Thompson E O P Kitai R 1955 The amide groups of insulin Biochemical Journal 59 3 509 518 doi 10 1042 bj0590509 PMC 1216278 PMID 14363129 Ryle A P Sanger F Smith L F Kitai R 1955 The disulphide bonds of insulin Biochemical Journal 60 4 541 556 doi 10 1042 bj0600541 PMC 1216151 PMID 13249947 Brown H Sanger F Kitai R 1955 The structure of pig and sheep insulins Biochemical Journal 60 4 556 565 doi 10 1042 bj0600556 PMC 1216152 PMID 13249948 Sanger F 1959 Chemistry of Insulin determination of the structure of insulin opens the way to greater understanding of life processes Science 129 3359 1340 1344 Bibcode 1959Sci 129 1340G doi 10 1126 science 129 3359 1340 PMID 13658959 Milstein C Sanger F 1961 An amino acid sequence in the active centre of phosphoglucomutase Biochemical Journal 79 3 456 469 doi 10 1042 bj0790456 PMC 1205670 PMID 13771000 Marcker K Sanger F 1964 N formyl methionyl S RNA Journal of Molecular Biology 8 6 835 840 doi 10 1016 S0022 2836 64 80164 9 PMID 14187409 Sanger F Brownlee G G Barrell B G 1965 A two dimensional fractionation procedure for radioactive nucleotides Journal of Molecular Biology 13 2 373 398 doi 10 1016 S0022 2836 65 80104 8 PMID 5325727 Brownlee G G Sanger F Barrell B G 1967 Nucleotide sequence of 5S ribosomal RNA from Escherichia coli Nature 215 5102 735 736 Bibcode 1967Natur 215 735B doi 10 1038 215735a0 PMID 4862513 S2CID 4270186 Brownlee G G Sanger F 1967 Nucleotide sequences from the low molecular weight ribosomal RNA of Escherichia coli Journal of Molecular Biology 23 3 337 353 doi 10 1016 S0022 2836 67 80109 8 PMID 4291728 Brownlee G G Sanger F Barrell B G 1968 The sequence of 5S ribosomal ribonucleic acid Journal of Molecular Biology 34 3 379 412 doi 10 1016 0022 2836 68 90168 X PMID 4938553 Adams J M Jeppesen P G Sanger F Barrell B G 1969 Nucleotide sequence from the coat protein cistron of R17 bacteriophage RNA Nature 223 5210 1009 1014 Bibcode 1969Natur 223 1009A doi 10 1038 2231009a0 PMID 5811898 S2CID 4152602 Barrell B G Sanger F 1969 The sequence of phenylalanine tRNA from E coli FEBS Letters 3 4 275 278 doi 10 1016 0014 5793 69 80157 2 PMID 11947028 S2CID 34155866 Jeppesen P G Barrell B G Sanger F Coulson A R 1972 Nucleotide sequences of two fragments from the coat protein cistron of bacteriophage R17 ribonucleic acid Biochemical Journal 128 5 993 1006 doi 10 1042 bj1280993h PMC 1173988 PMID 4566195 Sanger F Donelson J E Coulson A R Kossel H Fischer D 1973 Use of DNA Polymerase I Primed by a Synthetic Oligonucleotide to Determine a Nucleotide Sequence in Phage f1 DNA Proceedings of the National Academy of Sciences USA 70 4 1209 1213 Bibcode 1973PNAS 70 1209S doi 10 1073 pnas 70 4 1209 PMC 433459 PMID 4577794 Sanger F Coulson A R 1975 A rapid method for determining sequences in DNA by primed synthesis with DNA polymerase Journal of Molecular Biology 94 3 441 448 doi 10 1016 0022 2836 75 90213 2 PMID 1100841 Sanger F Nicklen S Coulson A R 1977 DNA sequencing with chain terminating inhibitors Proceedings of the National Academy of Sciences USA 74 12 5463 5467 Bibcode 1977PNAS 74 5463S doi 10 1073 pnas 74 12 5463 PMC 431765 PMID 271968 According to the Institute for Scientific Information ISI database by October 2010 this paper had been cited over 64 000 times Sanger F Air G M Barrell B G Brown N L Coulson A R Fiddes C A Hutchinson C A Slocombe P M Smith M 1977 Nucleotide sequence of bacteriophage fX174 DNA Nature 265 5596 687 695 Bibcode 1977Natur 265 687S doi 10 1038 265687a0 PMID 870828 S2CID 4206886 Sanger F Coulson A R 1978 The use of thin acrylamide gels for DNA sequencing FEBS Letters 87 1 107 110 doi 10 1016 0014 5793 78 80145 8 PMID 631324 S2CID 1620755 Sanger F Coulson A R Barrell B G Smith A J Roe B A 1980 Cloning in single stranded bacteriophage as an aid to rapid DNA sequencing Journal of Molecular Biology 143 2 161 178 doi 10 1016 0022 2836 80 90196 5 PMID 6260957 Anderson S Bankier A T Barrell B G De Bruijn M H Coulson A R Drouin J Eperon I C Nierlich D P Roe B A Sanger F Schreier P H Smith A J Staden R Young I G 1981 Sequence and organization of the human mitochondrial genome Nature 290 5806 457 465 Bibcode 1981Natur 290 457A doi 10 1038 290457a0 PMID 7219534 S2CID 4355527 Anderson S De Bruijn M H Coulson A R Eperon I C Sanger F Young I G 1982 Complete sequence of bovine mitochondrial DNA Conserved features of the mammalian mitochondrial genome Journal of Molecular Biology 156 4 683 717 doi 10 1016 0022 2836 82 90137 1 PMID 7120390 Sanger F Coulson A R Hong G F Hill D F Petersen G B 1982 Nucleotide sequence of bacteriophage l DNA Journal of Molecular Biology 162 4 729 773 doi 10 1016 0022 2836 82 90546 0 PMID 6221115 Sanger F 1988 Sequences sequences and sequences Annual Review of Biochemistry 57 1 28 doi 10 1146 annurev bi 57 070188 000245 PMID 2460023 References EditCitations Edit Seven days 22 28 November 2013 Nature 503 7477 442 443 2013 Bibcode 2013Natur 503 442 doi 10 1038 503442a Allen A K Muir H M 2001 Albert Neuberger 15 April 1908 14 August 1996 Biographical Memoirs of Fellows of the Royal Society 47 369 382 doi 10 1098 rsbm 2001 0021 JSTOR 770373 PMID 15124648 S2CID 72943723 a b c d e f g h i j k l m n o p q r s Brownlee George G 2015 Frederick Sanger CBE CH OM 13 August 1918 19 November 2013 Biographical Memoirs of Fellows of the Royal Society 61 437 466 doi 10 1098 rsbm 2015 0013 a b Nobel Prize Facts Nobelprize org Retrieved 1 September 2015 a b c d The Nobel Prize in Chemistry 1958 Frederick Sanger biography Nobelprize org Retrieved 10 August 2020 a b c d e f g h i j A Life of Research on the Sequences of Proteins and Nucleic Acids Fred Sanger in conversation with George Brownlee Biochemical Society Edina Film amp Sound Online 9 October 1992 Archived from the original on 13 March 2014 Retrieved 29 April 2013 Subscription required A 200 min interview divided into 44 segments Notes give the content of each segment dead link Marks Lara Sanger s early life From the cradle to the laboratory The path to DNA sequencing The life and work of Fred Sanger What is Biotechnology Retrieved 1 September 2015 Jeffers Joe S 2017 Frederick Sanger Two Time Nobel Laureate in Chemistry Springer International Publishing The Nobel Prize in Chemistry 1980 Sanger Frederick 1944 The metabolism of the amino acid lysine in the animal body PhD thesis University of Cambridge Neuberger amp Sanger 1942 Neuberger amp Sanger 1944 Frederick Sanger Ph D Biography and Interview www achievement org American Academy of Achievement Chibnall A C 1942 Bakerian Lecture Amino Acid Analysis and the Structure of Proteins PDF Proceedings of the Royal Society B Biological Sciences 131 863 136 160 Bibcode 1942RSPSB 131 136C doi 10 1098 rspb 1942 0021 S2CID 85124201 Section on insulin starts on page 153 Sanger amp Tuppy 1951a Sanger amp Tuppy 1951b Sanger amp Thompson 1953a Sanger amp Thompson 1953b Sanger F 1958 Nobel lecture The chemistry of insulin PDF Nobelprize org retrieved 18 October 2010 Sanger s Nobel lecture was also published in Science Sanger 1959 Marks Lara Sequencing proteins Insulin The path to DNA sequencing The life and work of Fred Sanger What is Biotechnology Retrieved 1 September 2015 Ryle et al 1955 Stretton A O 2002 The first sequence Fred Sanger and insulin Genetics 162 2 527 532 doi 10 1093 genetics 162 2 527 PMC 1462286 PMID 12399368 a b The Nobel Prize in Chemistry 1958 Frederick Sanger Nobelprize org Retrieved 8 October 2010 a b Marks Lara The path to sequencing nucleic acids The path to DNA sequencing The life and work of Fred Sanger What is Biotechnology Retrieved 1 September 2015 Marcker amp Sanger 1964 Holley R W Apgar J Everett G A Madison J T Marquisee M Merrill S H Penswick J R Zamir A 1965 Structure of a Ribonucleic Acid Science 147 3664 1462 1465 Bibcode 1965Sci 147 1462H doi 10 1126 science 147 3664 1462 PMID 14263761 S2CID 40989800 Brownlee Sanger amp Barrell 1967 Brownlee Sanger amp Barrell 1968 Sanger et al 1973 Sanger amp Coulson 1975 a b Sanger F 1980 Nobel lecture Determination of nucleotide sequences in DNA PDF Nobelprize org Retrieved 15 September 2019 Sanger et al 1977 a b Sanger F Nicklen S Coulson A R 1977 DNA sequencing with chain terminating inhibitors Proceedings of the National Academy of Sciences USA 74 12 5463 5467 Bibcode 1977PNAS 74 5463S doi 10 1073 pnas 74 12 5463 PMC 431765 PMID 271968 a b The Nobel Prize in Chemistry 1980 Paul Berg Walter Gilbert Frederick Sanger Nobelprize org Retrieved 8 October 2010 Anderson et al 1981 Sanger et al 1982 Walker John 2014 Frederick Sanger 1918 2013 Double Nobel prizewinning genomics pioneer Nature 505 7481 27 Bibcode 2014Natur 505 27W doi 10 1038 505027a PMID 24380948 The Nobel Prize in Physiology or Medicine 1972 Nobelprize org Retrieved 1 September 2015 Blackburn E H 1974 Sequence studies on bacteriophage OX174 DNA by transcription PhD thesis University of Cambridge The Nobel Prize in Physiology or Medicine 2009 Nobelprize org Retrieved 1 September 2015 Schlessinger David PDF National Human Genome Research Institute NHGRI genome gov March 2018 The ABRF Award for Outstanding Contributions to Biomolecular Technologies Association of Biomolecular Resource facilities Archived from the original on 6 August 2020 Retrieved 11 August 2020 Golden Plate Awardees of the American Academy of Achievement www achievement org American Academy of Achievement Summit Overview Photo Awards Council member and Nobel Prize laureate Dr Charles H Townes presenting the American Academy of Achievement s Golden Plate Award to British biochemist Dr Frederick Sanger recipient of two Nobel Prizes in Chemistry at the 2000 Summit in Hampton Court 2016 Awardees American Chemical Society Division of the History of Chemistry University of Illinois at Urbana Champaign School of Chemical Sciences 2016 Retrieved 14 June 2017 Citation for Chemical Breakthrough Award PDF American Chemical Society Division of the History of Chemistry University of Illinois at Urbana Champaign School of Chemical Sciences 2016 Retrieved 14 June 2017 a b c Frederick Sanger OM The Telegraph 20 November 2013 Archived from the original on 12 January 2022 Retrieved 20 November 2013 a b c Frederick Sanger Wellcome Trust Sanger Institute Archived from the original on 7 April 2011 Retrieved 12 October 2010 a b Hargittai Istvan April 1999 Interview Frederick Sanger The Chemical Intelligencer New York Springer Verlag 4 2 6 11 This interview which took place on 16 September 1997 was republished in Hargittai Istvan 2002 Chapter 5 Frederick Sanger Candid science II conversations with famous biomedical scientists London Imperial College Press pp 73 83 ISBN 978 1 86094 288 4 a b Ahuja Anjana 12 January 2000 The double Nobel laureate who began the book of life The Times London p 40 Archived from the original on 11 December 2008 Retrieved 18 October 2010 via warwick ac uk Bhattachjee Yudhijit ed 2007 Newsmakers A Life in Science Science 317 5840 879 doi 10 1126 science 317 5840 879e S2CID 220092058 Frederick Sanger Nobel Prize winner dies at 95 BBC co uk 20 November 2013 Retrieved 20 November 2013 Frederick Sanger Unassuming British biochemist whose pivotal and far reaching discoveries made him one of a handful of double Nobel prizewinners The Times London 21 November 2013 p 63 Frederick Sanger s achievements cannot be overstated The Conversation 21 November 2013 Bibliography Edit Brownlee George G 2014 Fred Sanger double Nobel laureate a biography Cambridge UK Cambridge University Press ISBN 978 1 107 08334 9 Chapters 4 6 contain the 1992 interview that the author conducted with Sanger Finch John 2008 A Nobel Fellow on every floor a history of the Medical Research Council Laboratory of Molecular Biology Cambridge Medical Research Council ISBN 978 1 84046 940 0 Garcia Sancho Miguel 2010 A new insight into Sanger s development of sequencing from proteins to DNA 1943 1977 PDF Journal of the History of Biology 43 2 265 323 doi 10 1007 s10739 009 9184 1 hdl 20 500 11820 e4febe48 772a 4f47 a1c5 a5ca89505367 PMID 20665230 S2CID 1134280 Sanger F Dowding M 1996 Selected Papers of Frederick Sanger with commentaries Singapore World Scientific ISBN 978 981 02 2430 1 Interviews with Nobel Prize winning scientists Dr Frederick Sanger British Broadcasting Corporation c 1985 Interviewed by Lewis Wolpert Duration 1 hour External links Edit Wikimedia Commons has media related to Frederick Sanger The Sanger Institute About the 1958 Nobel Prize About the 1980 Nobel Prize Fred Sanger 2001 Video Documentary by The Vega Science Trust Portraits of Frederick Sanger at the National Portrait Gallery London Frederick Sanger interviewed by Alan Macfarlane 24 August 2007 video also available on Video on YouTube Duration 57 minutes Frederick Sanger archive collection Wellcome Library finding aid for the digitised collection Frederick Sanger on Nobelprize org Portals Biography Biology Viruses Retrieved from https en wikipedia org w index php title Frederick Sanger amp oldid 1129313193, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.