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  • The Lock and Key of Medicine: Monoclonal Antibodies and the Transformation of Healthcare by Lara V. Marks
  • Scott H. Podolsky
KEYWORDS

patents, biotechnology, biomedical marketplace, therapeutics

Lara V. Marks. The Lock and Key of Medicine: Monoclonal Antibodies and the Transformation of Healthcare. New Haven, Yale University Press, 2015. xxv, 316 pp., illus., $40.00.

Forty years ago, in the summer of 1975, César Milstein and Georges Kohler first reported on the production of “monoclonal antibodies” (Mabs) in the lab. At the [End Page 235] time, Britain’s National Research Development Corporation (responsible for patenting innovations arising from the Medical Research Council laboratories, wherein Milstein and Kohler worked) failed to “identify any immediate practical applications which could be pursued as a commercial venture” (27). In the summer of 2015, as I write this review, the Food and Drug Administration has just approved a new class of anti-cholesterol medications, PSCK9 inhibitors, Mabs targeted against a protein involved in cholesterol uptake. Technological marvels, the drugs are likewise potential budget-breaking blockbusters, estimated to be priced at $7,000–$12,000 per year and reported as quickly in the business literature as in the biomedical literature. How did Mabs get from point A to point B in the span of four decades? In this volume, Lara Marks examines the complex interplay of science and commerce in the making and remaking of magic bullets and their roles.

After a somewhat muddled prehistory of the search for immunological “magic bullets” (it should be noted that antipneumococcal antiserum-based pneumonia control programs were not initiated until the 1930s, rather than the 1920s, and that Macfarlane Burnet garnered the Nobel Prize in 1960 for his role in formulating immunological tolerance, rather than for the development of the clonal selection theory), Marks hits her stride thereafter, extending from the work of Alberto Cambrosio and Peter Keating. Research in support of the clonal selection theory in the 1960s had demonstrated that the immune system’s antibody-secreting cellular lymphocytes were monospecific, i.e., that they secreted a single type of antibody generally coinciding with a particular antigen (the lock and key of the book’s title). The diverse lymphocytes of immunized animals and humans generate a diverse population of antibodies, even to a single immunogenic challenge, with resulting immune sera historically falling short of pure, uniform magic bullets. But myelomas—cancerous lymphocytes unable to be turned off in nature—served as a model (and substrate) for researchers looking for antibodies of a single specificity; and by 1975, Milstein and Kohler were able to fuse myeloma cells with spleen cells taken from immunized mice to generate an immortal cell line (what would come to be termed a “hybridoma”) capable of secreting Mabs against a known antigen.

In the modest, early days of Mabs, Milstein was personally sending out cell lines to researchers while wrestling with the difficult production of such novel biologicals. After a “hesitant start” (to use Marks’s term), however, researchers on both sides of the Atlantic were imaginatively exploring their uses. At the bench, they quickly turned to identifying novel cell markers (perhaps most famously, the CD4 antigen on the surface of certain T cells), altering the very characterization of the immune and nervous systems in the process. While the dissection of the immune system would come to play a critical role in confronting the HIV epidemic, more immediately obvious clinical applications of Mabs were likewise apparent. These ranged from their use in purifying such similarly emerging biologicals as recombinant interferon, to their use in blood typing, in identifying (and standardizing the measurement of) novel tumor markers like PSA, CEA, and CA-125, and, as millions around the world would come to appreciate in the comfort of their home, in the measurement [End Page 236] of HCG and hence pregnancy determination. But the holy grail of magic bullets was their therapeutic use, and this entailed engineering difficulties of scaling up the production of such biologicals, as well as eventually rendering them less recognizable by the human immune system and hence less apt to cause unwanted side effects. From a modest beginning in 1986 with the approval of Orthoclone to prevent the rejection of kidney...

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