Frederic Middlebrook Richards | |
Birth Date: | 19 August 1925 |
Birth Place: | New York, New York |
Death Place: | Guilford, Connecticut[1] |
Citizenship: | United States |
Fields: | Biophysics, Biochemistry |
Workplaces: | Yale University |
Alma Mater: | MIT (BS) 1948 Harvard University (PhD) 1952 |
Thesis Title: | Studies on the density and composition of some protein crystals, including a preliminary investigation of the crystal structure of zinc diglycinate monohydrate[2] |
Thesis Year: | 1952 |
Doctoral Advisor: | Barbara Low[3] |
Academic Advisors: | Edwin Joseph Cohn Kaj Ulrik Linderstrøm-Lang |
Doctoral Students: | Jorge Allende |
Notable Students: | Cyrus Chothia Louise Johnson Wendell Lim |
Known For: | Solving the 3rd-ever crystal structure of a protein – ribonuclease S; defining solvent-accessible surface |
Awards: | National Academy of Sciences American Academy of Arts and Sciences Guggenheim Fellowship |
Spouse: | Heidi Clarke Richards; Sarah (Sally) Wheatland Richards |
Frederic Middlebrook Richards (August 19, 1925 – January 11, 2009), commonly referred to as Fred Richards, was an American biochemist and biophysicist known for solving the pioneering crystal structure of the ribonuclease S enzyme in 1967 and for defining the concept of solvent-accessible surface. He contributed many key experimental and theoretical results and developed new methods, garnering over 20,000 journal citations in several quite distinct research areas. In addition to the protein crystallography and biochemistry of ribonuclease S, these included solvent accessibility and internal packing of proteins, the first side-chain rotamer library, high-pressure crystallography, new types of chemical tags such as biotin/avidin, the nuclear magnetic resonance (NMR) chemical shift index, and structural and biophysical characterization of the effects of mutations.
Richards spent his entire academic research career at Yale University, where he became Sterling Professor of Molecular Biophysics and Biochemistry in the department that he created and chaired, "one of the major centers in the world for the study of biophysics and structural biology".[4] He was elected to the National Academy of Sciences USA and the American Academy of Arts and Sciences, and received many other scientific awards. He served as head of the Jane Coffin Childs Memorial Fund for Medical Research and was elected as president both of the American Society for Biochemistry and Molecular Biology (ASBMB) and of the Biophysical Society.
Richards was born on August 19, 1925, in New York City to George H. Richards and Marianna Middlebrook Richards. Both parents were from old New England families who had settled in Fairfield and New London, Connecticut, in the 1600s. The family usually spent summers in Connecticut, giving Richards an early affinity for the area which continued through his career at Yale University. He had two older sisters, Marianna and Sarah. Marianna became a biochemist, and was a significant role model for Fred, who delighted in the smells and explosions produced by chemistry sets in that era.[5] He attended high school at Phillips Exeter Academy, and later recalled that "the excellent science department even permitted certain students the unsupervised run of the laboratories outside of class hours. This attitude played a strong role... in cementing our commitment to scientific careers." He learned glassblowing and electronics there, and tried to measure the universal gravitational constant using 100-pound cannonballs.
With strong science interests, Richards thwarted his family's expectations by choosing MIT (Massachusetts Institute of Technology) rather than Yale for college in 1943, majoring in chemistry. His undergraduate time was interrupted by two years in the army, which he described as "uneventful". He then joined the Biochemistry department at Harvard Medical School and the lab of Barbara Low. She had worked with Dorothy Crowfoot Hodgkin to solve the x-ray crystal structure of penicillin, and was later active in protein crystallography. The phase problem had not yet been solved to allow determination of protein structure, so his Ph.D. thesis (completed in 1952) studied the density and solvent content in crystals to help determine very accurate molecular weights for proteins. In 1954 he went to the Carlsberg Laboratory in Copenhagen to do postdoctoral research with Kaj Linderstrøm-Lang, where he started his classic work on the ribonuclease enzyme.[5] He also absorbed the scientific and mentorship style of Lang, who Richards called "a delightful individual, full of fun and jokes as well as science" exemplifying "simple, inexpensive, ingenious, and insightful experiments". In 1955 Richards joined the faculty at Yale University, where he stayed for the rest of his career.
Richards was an avid and enthusiastic sailor. In addition to sailing on Long Island Sound, he voyaged north along the Canadian coast, south to Bermuda, and even across the Atlantic several times with a small crew of family and friends.[4] [6] He and his wife had sailboats (Hekla 1 and 2) and an outboard-motor utility boat known as "Sally's Baage" (the spelling presumably a comment on her Maine accent), which he had built himself.[6] Chris Anfinsen, Richards's friend and his colleague as editors of Advances in Protein Chemistry[6] and who recommended the Carlsberg Lab to him, was also an avid sailor, and they sometimes joined forces.[6] Wendell Lim wrote that, "a dedicated sailor since childhood, Fred almost always took a month off each summer to captain a major sailing excursion, returning to lab afterwards refreshed and ready to work. His sailing adventures included several transatlantic voyages. He was also an avid ice hockey player."[5]
Richards lived in Guilford, Connecticut, a coastal town about 10 miles east of New Haven, situated between the Metacomet Ridge and Long Island Sound. Fred was married twice, to Heidi Clark Richards, daughter of biochemist Hans Clarke,[7] and in 1959 to Sarah (Sally) Wheatland Richards, a marine biologist. He had three children – Sarah, Ruth, and George – and four grandchildren. His daughter Sarah described him as "a lifelong scientist and sailor.... His main loves were his scientific work which he finished at Yale University, sailing, working in his shop, and helping in the community."[7] Fred and Sally were a major presence in local land conservation efforts, both on committees and in working projects out on the land and water.[8] [9] He donated a 41-acre shoreline property to the Yale Peabody Museum Natural Areas, which they described as "one of the few natural forest areas left in the state." The property now has long-term protection for use in biological and geological research.[10]
On December 2, 1957, at Yale University, Richards performed a simple experiment on the protein Ribonuclease A (RNase A) that helped change the scientific community's view of the physical nature of protein molecules. Using a particular protease (Subtilisin), RNase A was converted into a split protein (RNase S), which is composed of two parts called S-peptide and S-protein . Richards had developed that cleavage system as a postdoc at the Carlsberg Laboratory in Copenhagen, Denmark, using purified ribonuclease protein that had been donated to Christian Anfinsen by the Armour Company and that Anfinsen shared with Richards and other researchers.[4] Richards found that, when separated, S-protein and S-peptide had no RNase activity, but that the RNase enzymatic activity was restored when the parts were recombined in the test tube.[11] In an autobiographical piece, Richards wrote that "this discovery came as a surprise to the scientific community at that time.... In retrospect, this may have been the high point of my career in terms of excitement."[12] This experiment showed that proteins maintain 3-dimensional order and tight binding between their interacting parts and that the structural information is inherent in the protein itself, foreshadowing both Anfinsen's later work showing that sequence determines structure[13] and also the idea that hormones or other small molecules can bind tightly and specifically to proteins,[12] a concept basic to how pharmaceutical companies design drugs today. Two years later, the protein structure of myoglobin confirmed such specific 3D relationships.[14] Later, with Marilyn Doscher and Flo Quiocho, Richards demonstrated that ribonuclease S as well as carboxypeptidase were enzymatically active in the crystals, important evidence to silence doubts that the conformations of proteins in crystals are directly relevant to their biological activity in cells.[5] [15] [16]
Along with colleague Harold W. Wyckoff, who had worked on early research toward the myoglobin structure,[17] the effort to solve the RNase S 3-dimensional structure was spearheaded by Richards. Done in 1966 and published in 1967, the analyses of RNase S [18] and RNase A[19] jointly made ribonuclease the third distinct protein structure to be determined by X-ray diffraction of crystals, after myoglobin/hemoglobin and hen-egg lysozyme,[20] and the first to be done in the United States. Later, the Yale group collected more diffraction data, and in 1970 published the RNase S structure in full detail at 2.0 Å resolution . Coordinates for ribonuclease S were deposited into the international Protein Data Bank in 1973 as, among the first small set of macromolecular structures.[21]
The black-and-white ribbon drawing above shows the large, twisted beta sheet (arrows) of ribonuclease, flanked by several alpha-helices (spirals). The shorter S-peptide piece is behind, starting at upper left with a helix and ending with the chain break (between residues 20-21) at lower right. The active site for RNA cleavage (in the groove at center front in this drawing) involves one histidine side chain from the S-peptide fragment and another from the S-protein part.[18] The computer image shows superimposed structures of ribonuclease S and A, with the S-peptide in gold and the active site histidines in hot pink. The close match of the 3D structures shows that the 2-fragment S system does indeed fold to the active form .
In 1968, while on sabbatical with David Phillips at Oxford, Richards developed a large optical comparator device called a "Richards' box" (or "Fred's Folly") which enabled crystallographers to build physical models of protein structures by viewing the stacked sheets of electron density through a half-silvered mirror (see photo).[22] [23] Once the Folly had been constructed, he built an all-atom brass model of RNase S quite rapidly.[12] This was the method of choice for building protein crystallographic models into electron density until the late 1970s, when it was superseded by molecular computer graphics programs such as Grip-75[24] and then Frodo.[25]
Richards showed his sense of humor in a later review of developments in the use and construction of Richards boxes.[26] He provided a "correction to the Original Bibliographic Citations," complete with diagrams, for a theatrical stage technique that used selective illumination and a sheet of plate glass inclined at 45° to give an illusion of the nymph Amphitrite rising from the sea and floating in air, or of an audience volunteer dissolving to a skeleton and back again. Richards ended that section by noting that "had this reference been known to the author in 1968 no further description of the 'folly' would have been required."[26]
Richards' most enduring long-term scientific interest was in protein folding and packing, studied both experimentally and theoretically, and mostly from a geometrical perspective. As summarized by George Rose, "protein folders can be divided into 'minimizers' and 'packers'. The former seek to minimize the interaction energy among atoms or groups of atoms, whereas the latter concentrate on probable geometry, guided by both excluded volume limitations and structural motifs seen in proteins of known structure." Fred was a founding influence for the packers, who built on his observations about packing density, areas, and volumes.[6]
In 1971, with Byungkook Lee, Richards introduced the concept and a quantitative measure for the solvent-accessible surface (SAS) of amino acid residues in folded protein structures . The surface is constructed by tracing the center of an imaginary ball, its radius that of a water molecule (taken as 1.4 Å), as it rolls over the van der Waals surfaces of the proteins. Thus defined, the surface is continuous and each point on it is unambiguously associated with a specific protein atom (the nearest). The Lee & Richards definition has been widely adopted as the standard measure for solvent accessibility, for instance to evaluate exposure per residue as a percentage of accessible vs total surface area,[27] and as the basis of the buried-surface-area method for estimating the energetics of protein/protein contacts.[28]
introduced the Voronoi polyhedra construction to protein chemistry, a contribution reviewed more recently by Gerstein and Richards.[29] This approach has been adopted by many others[30] [31] and has been put on a firm mathematical footing by the work of Herbert Edelsbrunner.[32] With Jay Ponder in 1987, as part of an exploration of using internal packing of sidechains to enumerate the possible sequences compatible with a given protein backbone structure (a foreshadowing of protein engineering and design), Richards developed the first side-chain rotamer library. Increasingly detailed rotamer libraries, such as the Backbone-dependent rotamer library, have been made since then by other research groups, with some used primarily for structure validation[33] and others for homology modeling or protein design.[34] With Craig Kundrot, Richards investigated the effects of high pressure (1000 atmospheres) on protein structure, using hen-egg lysozyme crystals,[35] finding that the structure was robust to such pressures apart from a quite modest compaction in size. In the 1990s, Richards and collaborators used a combination of theory and experiment to investigate how the well-packed interior of proteins can nevertheless accommodate mutations.[36] [37] [38]
In the 1970s, with a succession of students and postdocs, the lab developed a series of chemical,[39] photochemical,[40] and cross-link labels for determining the position and relationships of proteins in biological membranes, including glutaraldehyde[41] and what was one of the two first general uses of the exceptionally tight interaction of biotin with avidin,[12] anchored to ferritin for use in electron microscopy.[42] [43] [44] The biotin–avidin system quickly became a central method in cell biology, immunology, and protein engineering, as well as electron microscopy.[45]
With David Wishart and Brian Sykes, he developed the chemical shift index for NMR assignment of protein secondary structure (&). This is still considered a standard tool in the NMR field.[46] Separately, around 1990, Homme Hellinga, with Richards, developed computational tools to design metal-binding sites into proteins,[47] and used them to build a new metal site into thioredoxin.[48]
Richards is named as a depositor on 27 crystal structure entries in the Protein Data Bank, including the now-obsoleted ribonuclease S, hen egg lysozyme, SH3 domains, the ion-channel-forming alamethicin, and mutants of ribonuclease S (e.g., ;), of Staphylococcal nuclease (e.g., ;), and of lambda repressor in complex with DNA .
The Department of Molecular Biophysics and Biochemistry ("MB&B")[49] that Richards founded and chaired at Yale, which amalgamated the medical school Biochemistry and the university Molecular Biophysics departments, was considered to have "quickly gained pre-eminent stature."[6] Many of those faculty became members of the National Academy of Sciences,[4] [6] and Tom Steitz shared the Nobel Prize in 2009 for crystal structures of the ribosome.[50] Richards was known as a highly valued mentor and friend to students, faculty, and colleagues, including a very supportive approach to women and African–Americans, according to Norma Allewell, quoted in a remembrance by Jim Staros.[51] His colleague George D. Rose wrote that Richards' lectures were insightful, delivered with clarity and humor, and often deliberately provocative, and that Richards worked to improve the scientific community in general.[6] For instance, in the late 1980s, he was the primary author, and the first of many signers, of a widely circulated letter that successfully urged a policy of depositing 3D atomic coordinates on scientific journals, on the NIH, and on individual crystallographers.[12] [52] He also lobbied, less successfully, for a let-up in overall publication pressure but an increased emphasis on a few first-class papers, by having promotion committees only consider a list of 12 key papers.[12]
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