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CHAPTER ONE
Communal Form of DNA Research
In the summer of 1959, Arthur Kornberg, along with five of his former colleagues at Washington University, St. Louis, arrived at Stanford University in California. They became faculty members of the newly established Department of Biochemistry at the Stanford Medical School, with Kornberg as its chair. Kornberg had accepted the chairmanship of the new biochemistry department two years earlier; since then, he had the unique opportunity to assemble his faculty members, organize research programs, and help design the departmentâs laboratory space in the new building at the medical school on the Palo Alto campus. Kornberg had complete freedom to choose new faculty members, and in a short letter to Robert Alway, acting dean of the Stanford Medical School, he recommended sixâMelvin Cohn at the rank of professor; Paul Berg and Robert L. Baldwin as associate professors; and David Hogness, A. Dale Kaiser, and I. Robert Lehman as assistant professors. There were no other explanations about his recommendations, except his admission that âthe [application] forms are rather short on detail, but I think it should be realized that each of these men is being sought after now by excellent universities throughout the country.â1
The Stanford Biochemistry Department, assembled de novo under the strong leadership of Kornberg, was literally a âKornbergâ department. The entire faculty, except for Baldwin who came from the University of Wisconsin, had previously been recruited to Kornbergâs Microbiology Department at Washington University as his postdoctoral fellows or junior faculty. As Kornberg characterized, they were an âextended family.â2 Moreover, they had been, according to Kornberg, âworking as a âteam,â in the loosest sense of this term, in trying to understand heredity and differentiation at a chemical and molecular level.â3 Kornberg, who was awarded the Nobel Prize in 1959 for his research on the synthesis of DNA, was at the forefront of exploring the biochemical basis of heredity as DNA became widely understood as the cellâs most important component, its âmaster planâ that would direct production of its other, various molecular structures. Kornberg had already isolated an enzymeâDNA polymeraseâthat was believed to direct the chemical synthesis of DNA; this was the work for which he was awarded the Nobel Prize. The group of scientists he had assembled at Washington University in the early 1950s had been examining the chemical and biological properties of DNA. When most of them accompanied Kornberg to Stanford, he formed a âDNAâ department as well.
The establishment of the Stanford Biochemistry Department, chaired by the Nobel laureate Kornberg, exemplified the universityâs commitment to a new vision for biomedicine. The importation of a strong group of scientists in biochemistry and molecular biology to the Stanford Medical School was a key part of its ambitious effort to establish a center for biomedical and clinical research. In July 1953, Stanford president John E. Wallace Sterling, along with members of the board of trustees, had reached a conclusion that the medical school should be an integral part of the university, both geographically and intellectually. The decision to relocate the medical school from San Francisco to the main campus at Palo Alto, in addition to Stanfordâs vision of a research-oriented medical school, reflected the boardâs recognition of the significance of biomedical research and its rising cultural, scientific, and financial status in postâWorld War II research universities.4 According to Sterlingâs plan, Stanfordâs new medical school would establish its basic biomedical departments along with the reorganized clinical departments, and the proximity of both to the main campus would facilitate a new style of biomedicine in which a broad array of conceptual and technical tools in the experimental life sciences could contribute to medical education and research. Sterling noted also that the faculty of the Stanford Medical School underlined the significance of research:
We place great emphasis on the creation within the Medical School of the stimulating and exciting environment which stems from maximum productivity and diversity of research. Although patient care is the backbone of the practice of medicine, the great advances in medicine must necessarily come from experimental and clinical investigation. It is an integral part of the responsibility of the medical school to the Nation to expand the horizons of scientific medicine and to break new ground in the conquest and prevention of disease.5
The rise of biomedical research at Stanford was orchestrated by administrators, including the universityâs first provost, Frederick Terman, and the dean of the medical school, Windsor Cutting; the dean shared the universityâs strategic pursuit for âsteeples of excellenceâ in a few key areas of research with the highest growth potentials.6 At a time when the federal government, especially the National Institutes of Health (NIH), drastically expanded its support for biomedical research, Stanford administrators opportunistically took advantage of this postâWorld War II trend to build up their profile in that area.7 At one level, Stanfordâs integration of its medical school with the main university reflected a broader postâWorld War II realignment in the relationship between medicine and biology, namely the rise of biomedicine as a âhybrid form of research and therapy that combines the normal and pathological.â8 At another level, Stanfordâs new biochemistry department, with its obstinate focus on basic research as opposed to clinical care, reflected the postâWorld War II disciplinary consolidation of biochemistry, biophysics, microbiology, genetics, and molecular biology into the broad framework of basic biomedical research. For example, biochemistry, or a minor medical specialty called âmedical chemistry,â had been a service discipline inside the medical school, providing a basic biological and biochemical training necessary for medical students. However, after World War II, biochemistry emerged as an autonomous and powerful subject area of biomedical research.9 With the postwar expansion of the biomedical research enterprise, other included disciplines, such as genetics and molecular biology, began to proliferate as autonomous fields in research universities, attracting ample funding to support their laboratory operations.10
In this chapter, I examine the development of Stanford biochemistsâ communal form of laboratory life.11 I first show how Stanfordâs strategic appropriation of the expansion of federal patronage for biomedical research led to the establishment of the new biochemistry department, one that strongly focused on DNA as its research subject. Under Kornbergâs influence, Stanford biochemists developed their shared research interests in DNA, especially in its biochemical replication and biological activities like genetic expression and regulationâthe central problems in molecular biology in the 1960s and 1970s. Stanford biochemists in turn formed a particular style of research community at the local level by cultivating distinctive communal practices among its faculty members. I analyze how Stanford biochemists tried to foster a research community with distinctive moral and political economies of science by sharing laboratory space, research instruments and materials, and even monies.12 At one level, their sharing practices were embedded in their distinctive moral economy of scienceâcommunal views about proper ways of organizing their laboratory life; about social norms and obligations in scientific exchange and knowledge production; and about customs and rules in the distribution of resources in the community life. At another level, their communal mode of the departmentâs financial and managerial operations was reflected in their particular, local political economy of scienceâa small, tight-knit political economic sphere devised through pooling its resources communally while maintaining its broader, rational economic relationship with federal funding for biomedical research. As I show, the moral and political economies of science embedded in the Biochemistry Department evolved from their efforts to sustain a vibrant flow of ideas, materials, and technologies that could sustain the productivity and independence of their research in the increasingly competitive world of biomedical research in the 1960s.
Toward a Biomedical School
In his presentation to Stanfordâs Board of Trustees in June 1953, President Sterling argued that the medical school should undertake a bold move that would benefit both itself and the university:
It was argued that the future of medical education is dependent on the course of medical science, and that, in turn, medical science has become increasingly dependent upon the basic physical sciences and upon the social sciences. This key relationship of medical education and science to other scientific fields can best be strengthened and advanced by bringing the Medical School into the closest possible physical and intellectual relationship to the whole University. This is a view to which I subscribe.13
The move to the main campus at Palo Alto would be both âphysical and spiritualâ (figure 1.1). When concluding his study of the Stanford medical school in San Francisco in 1952, Sterling pointed out that the deteriorating educational and clinical facilities were in major need of replacement and refurbishment (figure 1.2). In addition to the âhopeless jumbleâ of the medical school and Lane Hospital, the formerâs financial woes were growing worse; it had been losing four hundred thousand dollars annually by 1950.
More problematically, the relative lack of medical research facilities and professors meant that the medical school was in danger of failing to take part in the postwar development of biomedical research and the expansion of its federal support. At Stanford, a memo circulated in the late 1950s stressed the urgent need to emphasize research in the newly relocated medical school. Pointing to the fact that the NIHâs grants for training and research had increased by 5 times to 7.5 times in eight years following 1950, it was suggested in the memo that the new medical school should âput an emphasis on education, on attracting more doctors (M.D. + Ph.D.) into academic and investigative training careersâ as a way to finance the new medical school (figure 1.3).14 Sterling, along with the dean of the medical school, Windsor Cutting, emphasized that the intellectual and geographic division between preclinical disciplines of the university, such as biology, biochemistry, chemistry, and genetics, and clinical departments of the medical school, such as anatomy, pathology, and physiology, was no longer tenable. Pointing to the âessential unity of biology and the basic medical sciences,â and its implications for both medical practice and medical education, Sterling and Cutting further asserted that the progress of medicine increasingly depended on advances in the basic biochemical and biophysical sciences. The geographic and academic integration of the medical school with the rest of the university, they concluded, could provide an unparalleled opportunity for Stanford to institute biomedical research in a truly academic medical school.15
The relocation of the medical school to Stanfordâs main campus also provided a chance to empower dispersed medicine-related faculty members in the biology and chemistry departments at the university. At Stanford, biochemistry had played a traditional service role to medical education, reflecting the state of the discipline since the early twentieth century.16 For example, most Stanford biochemists, such as J. Murray Luck and Laurence Pilgeram, resided in the chemistry department and were more oriented toward chemistry rather than biochemistry. Moreover, immediately after World War II, Stanford lost one of the pioneers of biochemical genetics when George Beadle moved to Caltech.17 He was partly attracted to Caltech on account of the pervasive cooperative research among biologists, chemists, and physicists, who were supported by a flow of grant funds to biochemistry and molecular biology.18 Beadle was further disappointed by Stanford biochemist Hubert Loringâs lack of appreciation for the novel approach based in molecular genetics that Beadle had developed in his Neurospora experimental system.19 Loring, a student of Wendell M. Stanley, preferred a structural approach to biochemistry based on the crystallization and analytical ultracentrifugation of virus particles.20 Additionally, Edward Tatum, a biochemist from the Department of Biology at Stanford who collaborated with Beadle on their Nobel prizeâwinning experiment, had also left to join the Rockefeller Institute in 1956, despite having received Stanfordâs hasty offer of the chairmanship of a new biochemistry department that was then still a âpaper organization.â21
Frederick Terman, newly appointed in 1955 as academic provost at Stanford, played a key role in establishing two new basic biomedical departments (the Biochemistry and Genetics Departments); he accomplished this, along with Dean Cutting, by coordinating the integration of the medical school with the university.22 The two men...
