Hartmann F. Stähelin

Hartmann F. Stähelin, M.D. (born October 20, 1925) is a Swiss pharmacologist with an outstanding record in basic and applied cancer and immunology research. He discovered two important drugs: etoposide and cyclosporine A.

Early life

Both Stähelin's parents were medical doctors. After preparatory school and a classical education with the emphasis on Greek and Latin, Stähelin studied medicine in Basel, Zürich and Florence (1944–1950). His first position after graduation was at the Institute of Microbiology of the University of Basel (1951–1954) where he investigated the morphology and sporulation of anthrax bacilli with the help of the then-new phase contrast microscope. In May 1951, Stähelin was the first to observe naked anthrax bacilli protoplasts, called gymnoplasts, which had left behind their empty cell walls. A year later, during his studies of their osmotic behavior, he discovered and described the occasional fusion of naked protoplasts. [cite journal |author=Stähelin H |title= [Osmotic behavior and fusion of naked protoplasts of "Bacillus anthracis"] |language=German |journal=Schweiz Z Pathol Bakteriol |volume=17 |issue=3 |pages=296–310 |year=1954 |pmid=13205171 |doi=] This seminal paper in German immediately caught the attention of the bacterial geneticist Joshua Lederberg, who personally requested a copy.

Early career

In 1954, Stähelin successfully applied for a 12-month postdoctoral fellowship sponsored by the Swiss National Foundation (SNF) to work on a project on phagocytosis inspired by Emanuel Suter (then at Harvard, later second Dean of the University of Florida Medical School). In 1955, Stähelin rediscovered the respiratory burst in leucocytes in Manfred L. Karnovsky's laboratory at the Department of Bacteriology and Immunology, Harvard Medical School, Boston, U.S.A. [H. Stähelin, E. Suter, M.L. Karnovsky J, "Studies on the interaction between phagocytes and tubercle bacilli" Exp. Med. 104, 121–136 & 137–150, 1956; 105, 265–277, 1957. PMID 13332184, PMID 13332185 and PMID 13406183.] His experiments stirred the interest of Karnovsky, who was at the time unaware of this metabolic phenomenon (which had first been described more than twenty years earlier in 1933 by C. W. Baldridge and R. W. Gerard). Stähelin's elegant work subsequently paved the way for the famous investigations of A.J. Sbarra and Karnovsky on the role of oxygen in the defense against microorganisms. [cite journal |author=Sbarra AJ, Karnovsky ML |title=The biochemical basis of phagocytosis. I. Metabolic changes during the ingestion of particles by polymorphonuclear leukocytes |journal=J Biol Chem |volume=234 |issue=6 |pages=1355–62 |year=1959 |pmid=13654378 |doi= PDFlink| [http://www.jbc.org/cgi/reprint/234/6/1355 Free full text] |991 KiB; see also references related to Stähelin's work in: ISI Citation Classic CC/27:25–25, July 4, 1983]

While at Boston, the biomedical talent of the 27-year-old Stähelin was spotted by the director of the pharmacology department of the Sandoz Corp. (now Novartis AG.) Basel, who visited Suter's Harvard Medical School laboratory. After 6 months of training in the state-of-the art tissue-culture techniques in John F. Enders' laboratory in Boston, sponsored by Sandoz, Stähelin joined its pharmacology department in Basel to head the newly created laboratory, then a research group working on cancer and immunology (1955–1979).

Discovery of "Podophyllum" derivatives

Stähelin quickly assumed the leading role in the discovery and development of "Podophyllum" compounds; four of them, including etoposide (Vepesid), were later marketed. He was able to detect in a partially purified, chemically modified extract of the "Podophyllum" plant the presence of a then-unknown agent with interesting properties, which had at first been considered by the chemists to be "dirt". The chemists, under the direction of A. von Wartburg, analysed this impurity. Guided by Stähelin's "in-vitro" and "in-vivo" assays, [cite journal |author=Stähelin H |title=A simple quantitative test for cytostatic agents using non-adhering cells "in vitro" |journal= Med Exp Int J Exp Med |volume=7 |issue= |pages=92–102 |year=1962 |pmid=13978705 |doi=] they found the active compound responsible for the good antitumor activity of SP-G (Proresid oral) and SP-I (Proresid intravenous; discovered in April 1959, commercialized 1963). [cite journal |author=Stähelin H, Cerletti A |title= [Experimental results with the Podophyllum-cytostatics SP-1 AND SP-G.] |language=German |journal=Schweiz Med Wochenschr |volume=94 |issue= |pages=1490–502 |year=1964 |pmid=14318344 |doi=] Further chemical modifications led to the well-known thenylidene derivative VM-26 (teniposide, Vumon, discovered in October 1965, commercialized by Sandoz in 1976) and to the ethylidene derivative VP-16-213 (etoposide, Vepesid, discovered on October 21, 1966), which remains very clinically successful.

Teniposide and etoposide were found by Stähelin to have a new mechanism of action: they blocked the entry of cells into mitosis (with arrest in late S or G2 phase), in contrast to SP-G and SP-I, which were spindle poisons. His subsequent investigations showed that the early biochemical effect of the two epipodophyllotoxins on proliferating cells "in vitro" differed from that of the alkylating agents, antimetabolites and Vinca alkaloids. After a landmark clinical comparative analysis by F. Muggia and M. Rozencweig, [cite journal |author=Rozencweig M, Von Hoff DD, Henney JE, Muggia FM |title=VM 26 and VP 16-213: a comparative analysis |journal=Cancer |volume=40 |issue=1 |pages=334–42 |year=1977 |pmid=328129 |doi=] etoposide and teniposide were licenced to Bristol-Myers in 1978 for further clinical development. A few years later, in November 1983, etoposide was approved by the US FDA.

Etoposide is still considered a potent, well-tolerated combination partner in innumerable hematologic and solid tumor treatment schedules, including those for malignant lymphomas and lung cancer. It is also indispensable in the cure of testicular carcinoma. [cite journal |author=Einhorn LH |authorlink=Lawrence Einhorn|title=Curing metastatic testicular cancer |journal=Proc Natl Acad Sci USA |volume=99 |issue=7 |pages=4592–5 |year=2002 |pmid=11904381 |doi=10.1073/pnas.072067999 [http://www.pnas.org/cgi/content/full/99/7/4592 Free full text] ] [cite journal |author=Schabel FM, Trader MW, Laster WR, Corbett TH, Griswold DP |title=cis-Dichlorodiammineplatinum(II): combination chemotherapy and cross-resistance studies with tumors of mice |journal=Cancer Treat Rep |volume=63 |issue=9–10 |pages=1459–73 |year=1979 |pmid=291480 |doi=]

New screening process and the discovery of immunosuppressants

Stähelin was also instrumental in the discovery process of several microbial products inhibiting cell proliferation, including cytochalasin B, brefeldin A, verrucarin A, anguinine and chlamydocin, which have played an important role in basic cancer research.

In 1969, Stähelin made the key decision to include a test system for immunosuppression into the general screening program at Sandoz for compounds and extracts. He invented a new procedure which permitted the use of the same mice for testing both anticancer activity (L-1210) and immunosuppression (inhibition of antibody formation) in an "all in one "in-vivo" test system". This considerably reduced both the number of experimental animals and the quantity of test substances required, and also decreased the labour involved. Stähelin's invention of this procedure initiated an innovative screening system for discovering immunosuppressant drugs lacking bone marrow toxicity – the first such screen to be discovered. This screening process was first used in the pharmacology department in January 1970, before Jean F. Borel joined Stähelin's group. [cite journal |author=Stähelin HF |title=The history of cyclosporin A (Sandimmune) revisited: another point of view |journal=Experientia |volume=52 |issue=1 |pages=5–13 |year=1996 |pmid=8575558 |doi=] [cite journal |author=Weibel ER |title=Who did what? The human side of the science enterprise |journal=Swiss Med Wkly |volume=131 |issue=21–22 |pages=289–90 |year=2001 |pmid=11584689 |doi=2001/21/smw-09767]

Stähelin had used a similar screen to discover the nonmyelotoxic immunosuppressant ovalicin. Applying the revised screen led to the discovery of the potent biological activity of cyclosporine A on January 31, 1972. [cite journal |author=Borel JF, Feurer C, Gubler HU, Stähelin H |title=Biological effects of cyclosporin A: a new antilymphocytic agent |journal=Agents Actions |volume=6 |issue=4 |pages=468–75 |year=1976 |pmid=8969 |doi=] This drug was to revolutionize organ transplantation in the 1970s and the paper became a citation classic (CC/6:16-16, February 6, 1984).

The "Stähelin Screen" was rapidly and very successfully adopted by the Japanese pharmaceutical company Fujisawa, which subsequently discovered tacrolimus (FK-506, Prograf), the second clinically used calcineurin inhibitor.

On receiving the American Association for Cancer Research Bruce F. Cain Award jointly with his colleage A. von Wartburg in 1990, Stähelin wrote:

"...there are an astonishing number of coincidences between etoposide and cyclosporine. The first coincidence was that etoposide and cyclosporine were both found and developed on the chemical and biological side by the same groups, those of the present authors and their specific biological effects were discovered by one of us; second, both compounds were approved by the United States Food and Drug Administration on the same day in November 1983, although they had been submitted by different companies; furthermore, both drugs act via an effect on an intranuclear isomerase, topoisomerase II, and peptide "cis-trans-"isomerase, respectively; both compounds are potent immunosuppressants; etoposide as well as cyclosporine are used in the treatment of leukemias or other malignancies; the latter after bone marrow transplantation to prevent graft-versus-host disease, the former also being used in conjunction with bone marrow transplantation; sometimes, the two compounds are used concomitantly, exploiting the capacity of cyclosporine to reduce certain types of multidrug resistance or to modify immunity against tumors cured by etoposide; in the development of both drugs, galenical problems arose, related to poor water solubility and absorption from intestinal tract, and experience gained with etoposide in this area was crucial for overcoming, several years later, difficulties of a similar type with cyclosporine. It is left to the reader to make assumptions about the heuristic aspects of these surprising coincidences..." [cite journal |author=Stähelin HF, von Wartburg A |title=The chemical and biological route from podophyllotoxin glucoside to etoposide: ninth Cain memorial Award lecture |journal=Cancer Res |volume=51 |issue=1 |pages=5–15 |year=1991 |pmid=1988106 |doi= [http://cancerres.aacrjournals.org/cgi/reprint/51/1/5 Free full text] ]

Personal and later life

Married to a distant cousin (Irene Staehelin, who is also a member of an old Basel family dating back to 1520) and the father of four adult children, Stähelin retired in 1990. He still occasionally writes about his discoveries. [ [http://www.sandimmune.ch/person_e.htm Sandimmune: Dr. Hartmann Stähelin: Person/Career/Development] . Retrieved on 2007-08-28.]

References

External links

* [http://www.sandimmune.ch/ Stähelin's personal website] Persondata
NAME = Stähelin, Hartmann F.
ALTERNATIVE NAMES = Stähelin, Hartmann
SHORT DESCRIPTION = 20th century Swiss pharmacologist
DATE OF BIRTH = October 20, 1925
PLACE OF BIRTH = Basel, Switzerland
DATE OF DEATH =
PLACE OF DEATH =