Proven value of translational research with appropriate animal models to advance breast cancer treatment and save lives: the tamoxifen tale
2014; Wiley; Volume: 79; Issue: 2 Linguagem: Inglês
10.1111/bcp.12440
ISSN1365-2125
Autores Tópico(s)Pharmacogenetics and Drug Metabolism
ResumoBritish Journal of Clinical PharmacologyVolume 79, Issue 2 p. 254-267 Historial PerspectiveFree Access Proven value of translational research with appropriate animal models to advance breast cancer treatment and save lives: the tamoxifen tale V. Craig Jordan, Corresponding Author V. Craig Jordan Departments of Oncology and Pharmacology, Lombardi Comprehensive Cancer Center, Georgetown University, Washington, DC, USA Correspondnece Professor V. Craig Jordan OBE PhD DSc FMedSc, Departments of Oncology and Pharmacology, Vincent T. Lombardi Professor of Translational Cancer Research, Lombardi Comprehensive Cancer Center, Georgetown University Medical Center, 3970 Reservoir Road NW, Research Building, Suite E501, Washington, DC, 20057, USA. Tel.: +1 202 687 2897 Fax: +1 202 687 6402 E-mail: vcj2@georgetown.eduSearch for more papers by this author V. Craig Jordan, Corresponding Author V. Craig Jordan Departments of Oncology and Pharmacology, Lombardi Comprehensive Cancer Center, Georgetown University, Washington, DC, USA Correspondnece Professor V. Craig Jordan OBE PhD DSc FMedSc, Departments of Oncology and Pharmacology, Vincent T. Lombardi Professor of Translational Cancer Research, Lombardi Comprehensive Cancer Center, Georgetown University Medical Center, 3970 Reservoir Road NW, Research Building, Suite E501, Washington, DC, 20057, USA. Tel.: +1 202 687 2897 Fax: +1 202 687 6402 E-mail: vcj2@georgetown.eduSearch for more papers by this author First published: 10 June 2014 https://doi.org/10.1111/bcp.12440Citations: 9AboutSectionsPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat Introduction Our current healthcare system is the beneficiary of the landmark successes of earlier pioneers who struggled, but persevered, to save lives. In the 19th century, two individuals stand out. Dr Louis Pasteur, a PhD basic scientist who luckily was 'encouraged' to conduct applied research and saved a life. Professor Paul Erhlich, a medically qualified research pathologist and winner of the Nobel Prize for antitoxin research, would create a model for successful synthetic drug development that would save thousands of lives. In my generation, it was my friend and supporter Sir James Black, Nobel laureate, who would advance the selectivity implied by receptor theory to treat patients for long periods with pathological conditions. Infectious diseases were cured within months but chronic heart disease, elevated blood pressure and gastric acid secretion were stabilized for years. Lives were saved and the practice of medicine changed to become evidence based. The key to success throughout was the creation and use of appropriate animal models. In this article, I will focus on the essential aspects of animal models in the unanticipated development of an orphan medicine tamoxifen, used initially to treat late stage breast cancer. The results from the animal models taught the medical profession how to use tamoxifen effectively to save lives, how to detect life-threatening side effects, or provided clues about a new group of medicines that now have multiple applications in women's health. But first, what did our pioneers do and how did they do it? A perspective on pioneers Dr Louis Pasteur had already had a prestigious career studying crystal structure, inventing 'pasteurization' for milk and wine to stop spoilage and a vaccine to protect sheep from anthrax, when he turned his attention to the fatal disease rabies. He used a rabbit model to attenuate the rabies virus and a dog model to test the vaccine 1. His initial goal was to develop an experimental vaccine for study in animals until the fateful day the mother of 9-year-old Joseph Meister pleaded with Pasteur to save her son from a slow and painful death. He had been severely bitten by a rabid dog and death was assured. The unexpected arrival of the young Joseph Meister at that moment was critical, as Pasteur had recently revised his method to prepare attenuated rabies virus and the strategy to treat dogs to protect them from rabies. Pasteur found through his earlier experiments that passing the virus through monkeys, was not optimal and he selected passage through rabbits and collected the infected spinal cords. He fixed them by drying inside flasks protected from moisture. Two weeks of drying reduced the extracted virus to become harmless to dogs who were now immune to rabies once inoculated with preparations of increasing virulence based on less dessication time. The young Meister was injected over a period of 11 days with a total of 13 injections of increasing rabies virulence. He escaped certain death. Following Pasteur's death and burial in the crypt of the Pasteur Institute in Paris, Joseph Meister became the faithful custodian to this medical pioneer's memory until the German occupation of Paris in 1940. It is said he chose suicide rather than surrender the keys to the crypt and the memorial to the scientist who saved his life and changed medicine. Professor Paul Ehrlich devised the drug discovery and development system used today 2. Earlier in his career as a pathologist he was fascinated to find that organic dyes would specifically bind to bacterial and not human tissue. This gave him the clue to devise chemical therapy. Ehrlich's primary interest was vaccines and antitoxins for which he received the Nobel Prize. Ehrlich believed in the fidelity of the immune system to neutralize and destroy infectious disease. However with the expansion of European colonial interests into Africa came new challenges. It became obvious that the immune system could not kill tropical diseases such as malaria and sleeping sickness whose cause was protozoal. The immune system was overwhelmed by the sheer bulk of the infectious agent. Ehrlich stated 'an attempt must be made to kill the parasites within the body by chemical agents. In other words chemical agents must be used when serum therapy is impossible. French scientists Alphonse Laurier (awarded the Nobel prize for the discovery of the causative agent of malaria) and Mesnel found they could transfer trypanasomes from mouse to mouse to replicate human disease. Progression of the disease could be monitored through blood tests. Ehrlich used the model to show that dyes could be 'parasitotropic' in mice. Trypan red could cure infected mice. However, when Ehrlich identified the nitrogen-containing azo group in trypan red this brought him to organic arsenicals. An arsenical para-aminophenyl arsenic acid (atoxyl) was marketed already but the compound was ineffective in their model. They had discovered arsenical resistance. A fortunate series of scientific advances in microbiology in 1905 occurred with the chance observation by others, that syphilis was associated with spirochetes that occupied a position between protozoans and bacteria. This was followed by the validation of animal models by scientists in Italy in 1906. At this point Ehrlich appears to have integrated a study of syphilis and a study of resistance to trypanosomes to arsenicals into his laboratory strategic plan. The key to success for the eventual discovery of compound 606 (Salvarsan), through methodical structure activity relationship, was the recruitment of Sahachiro Hata from Tokyo to screen all the compounds in the appropriate models of human disease. Salvarsan was discovered in June 1909. Following toxicology in animals, clinical trials were conducted with the drug manufactured by the Hoechst Company in Germany. Another deadly infectious disease was cured and thousands lived. Sir James Black (of β-adrenoceptor blocker fame) 3 worked in the laboratories of Imperial Chemical Industries (ICI) Pharmaceuticals Division, Alderley Park, near Macclesfield, Cheshire. He had left ICI by the time I was a summer student at ICI in 1967. Alderley Park was 10 miles from my home and I was then an undergraduate in the Pharmacology Department at Leeds University, keen to do research in cancer drug discovery. There was none of significance then at ICI but the cell biologist Dr Steven Carter (of cytochalasin B fame) 4 was looking at the effects of compounds on mouse cancer cells in culture. It was a start! Coincidentally, the Head of the Fertility control programme, Dr Arthur Walpole had his laboratory opposite Dr Carter's. He had just published a paper 5 on the effects of ICI 46 474 as a 'morning after pill' in rats – but nobody cared! We will meet ICI 46 474 (tamoxifen) later. Although this was a prescient meeting with Dr Walpole as he would later be the examiner of my PhD on 'failed morning after pills' at Leeds in 1972, the critical players at the start of our tale were being assembled. I met Dr Michael Barrett (of atenolol fame) 6 whose laboratory was next to Dr Carter's at ICI. He had taken over the β-adrenoceptor blocker programme after Jim Black left. Dr Barrett was to talent spot me for a faculty position at Leeds when he became the Professor of Pharmacology in 1970. Also at ICI in the summer of 1967, I had the privilege to meet Dr James Raventos who was studying gastric acid secretion in dogs with histamine. Jim later told me that the known antihistamines did not block histamine stimulated gastric acid secretion in the dog model. Based on Jim's pioneering studies on the regulation of accelerated cardiac function and arrhythmias in the dog model with his new β-adrenoceptor blockers, he reasoned that the 'antihistamine anomaly' must be because there was a second subtle histamine receptor modulating mechanism 3 – and so it was. The H2-receptor blockers were born at Smith, Kline and French and long term treatment with H2–receptor blocker 'antacids' was possible as was β-adrenoceptor blocker treatment for heart conditions before. Regulations for the safety of medicines Pasteur, Ehrlich and Black each chose not to conform to the dogma that disease and death were inevitable. Each chose to question Nature through experimental animal models. Their persistence was translated to patient care. However, success in one area of therapeutics demands regulations imposed by society on claims in other areas thereby preventing Charlatans peddling 'cures' that are neither evidenced based nor safe. The elected representatives of the people in our democratic society are charged with the responsibility to enact laws and regulations that ensure the safety of any new medicine. A strict protocol of appropriate animal toxicology is enforced by acts of government to prevent unanticipated injury or deaths. It is not necessary to expand further as the concepts of safety and the documented worth of a medicine for patient care should be obvious to all. Nevertheless, a couple of examples will be given to illustrate instances when an inadequate system of protection can fail or a warning model appears to do so. It is axiomatic that one should always err on the side of caution with safety and side effects of medicines. Thalidomide taught us that lesson so why was there no caution? The reason that the tragedy occurred was that there was no legal requirement to test for teratogenicity in the 1950s 7. The toxicology concern was first raised by observation in humans 8. Tragically, the value of thalidomide was seen to be in the control of nausea in pregnant women during the first trimester 9, exactly when limb development is occurring in the foetus. It is now known that thalidomide can stop blood vessel formation and limb formation is particularly vulnerable. Now there is rigorous teratogenesis testing of medicines to be used in women of childbearing age. It is important to note that thalidomide used in a cancer context, to treat a fatal disease, can produce improvements in multiple myeloma deployed as an anti-angiogenic agent. The thalidomide tragedy and introduction of teratogenic testing is why women taking the anti-oestrogen tamoxifen during their childbearing years to treat breast cancer, must use barrier contraception to prevent pregnancy. However, there was an apparent anomaly in the toxicology testing of tamoxifen when it transitioned from cancer therapy with a requirement for only liberal toxicity testing for a fatal disease, to a chemopreventive in disease-free women only at risk for breast cancer. This toxicological surprise in rats given tamoxifen for years was hepatocellular carcinoma that was first reported 10 nearly 20 years after tamoxifen had been used by perhaps a million women worldwide. Tamoxifen was discovered to be a rat liver carcinogen at high doses given for a lifetime 10 but increases in human hepatocellular carcinoma were not noted either in the 1990s 11, 12 when the toxicological issue was raised initially or indeed now 13. Millions of women have benefited from tamoxifen with its long term use. However, tamoxifen would not have been knowingly developed by any company had the toxicological knowledge been available at the beginning of the tamoxifen tale in 1973 14. Without the success of tamoxifen as a lifesaving medicine there were no agents waiting as the 'first reserve' anti-oestrogen – nobody cared. Without the success of tamoxifen, there would have been no financial incentive to develop aromatase inhibitors 15 and there would have been no selective oestrogen receptor modulators (SERMs) 16, 17. So this would seem to argue against animal testing? Certainly not. The toxicological requirements for an anticancer therapy to delay a fatal disease are rightly less draconian than for the treatment of a subject with an infection or no life-threatening disease. The fact the rat liver carcinogenesis was discovered after 20 years of tamoxifen use, allowed the clinical and toxicological community also to evaluate 'real world' experience in women 11, 12 No increase in liver cancer was noted. Scientists were able to determine that the rat is particularly susceptible with its metabolism of tamoxifen to producing a carcinogen but the human rapidly repairs DNA damage 18. The system for protecting human safety for the introduction of an unknown drug to prevent a disease worked with appropriate toxicology testing in animals. Cancer patients lived because of appropriate testing and risk management for treatment of a fatal disease. The early years of the tamoxifen tale Cancer therapeutics and cancer prevention are a particular challenge as we seek to destroy renegade cells that are 'self'. Ehrlich chose to explore the development of appropriate animal models of human disease to address cancer chemical therapy (chemotherapy) at the dawn of the 20th century. In the year before he died in 1916 he declared 'I have wasted 15 years of my life on experimental cancer research' 19. The banner of progress in therapeutics was picked up in the 1940s using a process of translational research i.e. first validation of an antitumour response in animal models and then a clinical trial. Sir Alexander Haddow FRS discovered 20 that high dose synthetic oestrogen treatment could produce a 30% response rate in breast cancer patients more than 5 years after their menopause 21. This was the first chemical therapy to treat any cancer successfully and was proven in clinical trials. However, high dose oestrogen treatment is a paradox as all other approaches before the Haddow breakthrough caused regression of breast cancer by endocrine ablation (oophorectomy, adrenelectomy), i.e. taking away oestrogen just as tamoxifen blocks oestrogen from stimulating tumour growth. High dose oestrogen therapy remained the treatment of choice for breast cancer after the menopause for the next 30 years until the introduction of tamoxifen (1973 UK, 1977 USA) with fewer side effects 22, 23. The only randomized trial 23 of high dose oestrogen vs. tamoxifen in unselected (no oestrogen receptor (ER) selection) post-menopausal patients with metastatic breast cancer was quite small with 74 patients and 69 patients, respectively. Response rates were both about 30% and disease control was similar over a 2 year period. Only the increased side effects noted with high dose oestrogen led the authors to recommend tamoxifen 23. It is interesting to note that all the early events in the story of breast cancer 'chemical therapy' are actually connected. Haddow's experimental oestrogens were synthesized by ICI 20. Walpole was specifically interested in cancer research. He tried unsuccessfully to discover why only some tumours responded to oestrogen therapy 24 and successfully developed an early 'chemotherapy' 25 but was directed to create a safer 'morning after pill'. The discovery by scientists in America that synthetic oestrogens could be converted to anti-oestrogens through the skill of the medicinal chemist 26 that were also effective 'morning after pills' in the rat which could potentially now create another 'blockbuster' in the wake of the success of oral contraceptives. My connection with the anti-oestrogen research team at ICI throughout the 1970s has recently been told 27 and the clinical development of tamoxifen explained 28, 29. However, tamoxifen is not about a single medicine but the pioneer in a group of medicines now called SERMs. Forty years ago there were no SERMs, today there are five but with a sixth, lasofoxifene, approved in the European Union a few years ago. This approval has lapsed (Figure 1). The SERMs were predicted to treat multiple diseases in post-menopausal women simultaneously 26. The currently approved SERMs treat breast cancer, prevent breast cancer, prevent osteoporosis and preparations prevent menopausal symptoms including dyspareunia. The general outline of the development of the two principal SERMs, tamoxifen and raloxifene, are illustrated and explained in Figures 2 and 3 and a current view of the molecular mechanism of action illustrated for target sites in Figure 4. These stories have been explained recently in detail 30, 31. However, none of the SERM story would have occurred but for the appropriate use of animal models to guide clinical trials, to understand patient safety and finally to define a new biology of oestrogen-induced apoptosis. This cascade of knowledge answered the question 'how can oestrogen stimulate breast cancer growth (which is the basis of all successful anti-oestrogenic therapy for the past 40 years 32) but also cause apoptosis as a breast cancer therapy 22, 23 '. It is animal models that aided the understanding of 'Haddow's paradox' 21 that oestrogen can kill correctly prepared breast cancer cells. That knowledge and the molecular mechanism again have clinical significance. Figure 1Open in figure viewerPowerPoint The approvals of individual selective oestrogens receptor modulators (SERMs) in the United States of America through the evaluation system of the Food and Drug Adminisration (FDA). Approvals were specifically for indications at the highest level of toxicologic safety for women without disease but as a new hormone replacement therapy with conjugated oestrogen (HRT + CE) to prevent disease i.e. chemoprevention of osteoporosis, breast cancer (BC), menopausal symptoms or dyspareunia. One SERM, lasofoxifene, was approved for use in the European Union (EU) but was never launched or marketed despite the fact that clinical trials demonstrated a reduction in breast cancer (BC), osteoporosis fracture, strokes, endometrial cancer (EC) and coronary heart disease (CHD) 92 Figure 2Open in figure viewerPowerPoint A trickle to tamoxifen (ICI 46 474). During the 1960s, a number of triphenylethylene derivatives were discovered that were excellent novel post-coital antifertility agents in rats but induced ovulation in subfertile women (clomiphene and tamoxifen) 26. Tamoxifen moved forward as a palliative treatment for metastatic breast cancer, only after being all but abandoned as a commercially viable enterprise. It was then rescued as an orphan drug in 1972 93. Laboratory models informed about possible applications as a long term adjuvant therapy or as a chemopreventive agent 27. Clinical trials demonstrated major survival advantages for women with ER positive breast cancer who received long term (>5 years) tamoxifen therapy and tamoxifen was tested and was the first medicine to be approved for the reduction of breast cancer in high risk women 93 Figure 3Open in figure viewerPowerPoint Rush to raloxifene. The success of tamoxifen for the treatment of breast cancer created potential opportunities to develop drugs to correct toxicological issues of concern i.e. the increase in endometrial cancer. Trioxifene was developed as a potential competitor for tamoxifen but failed to demonstrate either increased efficacy in the treatment of metastatic breast cancer or decrease in serious side effects. In the wake of the discovery that tamoxifen was metabolically activated to 4-hydroxytamoxifen with high binding affinity for the ER (Figure 2) 70, 94 a compound LY156758 or keoxifene was developed that had high binding affinity for the ER and did not have oestrogen-like activity in the uterus 95. Keoxifene failed to become a breast cancer therapy and was abandoned in 1987. However, the discovery that keoxifene prevented bone loss and mammary cancer in rats 51, 75 ultimately resulted in the resurrection of the molecule as raloxifene. The clinical testing resulted in the approval of raloxifene to treat and prevent osteoporosis in post-menopausal women in 1997 and for the reduction of the incidence in breast cancer in high risk post-menopausal women in 2006. This was the Study of Tamoxifen and Raloxifene (STAR). Unlike tamoxifen, raloxifene does not increase the incidence of endometrial cancer 78 Figure 4Open in figure viewerPowerPoint The oestrogen target tissue decision network for selective oestrogen receptor modulation. The shape of the ligands that bind to the oestrogen receptors (ERs) α and β programmes the complex to become an oestrogenic or anti-oestrogenic signal. The context of the ER complex (ERC) can influence the expression of the response through the numbers of co-repressors (CoR) or co-activators (CoA). In simple terms, a site with few CoAs or high levels of CoRs might be a dominant anti-oestrogenic site. However, the expression of oestrogenic action is not simply the binding of the receptor complex to the promoter of the oestrogen-responsive gene, but a dynamic process of CoA complex assembly and destruction. A core CoA, for example, steroid receptor coactivator protein 3 (SRC3), and the ERC are influenced by phosphorylation cascades that phosphorylate target sites on both complexes. The core CoA then assembles an activated multiprotein complex containing specific co-co-activators (CoCo) that might include p300, each of which has a specific enzymatic activity to be activated later. The CoA complex (CoAc) binds to the ERC at the oestrogen-responsive gene promoter to switch on transcription. The CoCo proteins then perform methylation (Me) or acetylation (Ac) to activate dissociation of the complex. Simultaneously, ubiquitiylation by the bound ubiquitin-conjugating enzyme (Ubc) targets ubiquitin ligase (UbL) destruction of protein members of the complex through the 26S proteasome. The ERs are also ubiquitylated and destroyed in the 26S proteasome. Therefore, a regimented cycle of assembly, activation and destruction occurs on the basis of the preprogrammed ER complex. However, the co-activator, specifically SRC3, has ubiquitous action and can further modulate or amplify the ligand-activated trigger through many modulating genes that can consolidate and increase the stimulatory response of the ERC in a tissue. Therefore, the target tissue is programmed to express a spectrum of responses between full oestrogen action and anti-oestrogen action on the basis of the shape of the ligand and the sophistication of the tissue-modulating network. NFkB, nuclear factor kB. Reprinted with permission from the Nature Publishing Group, Jordan 96 The role of appropriate animal models in breast cancer research to save lives In 1972, just 2 months after my successful PhD examination with Dr Arthur Walpole on the topic of 'failed morning after pills' entitled A study of the oestrogenic and anti-oestrogenic activities of some substituted triphenylethylenes and triphenylethanes, I found myself at the Worcester Foundation for Experimental Biology in Shrewsbury, Massachusetts, USA. I discovered I was to be an independent investigator working in the 'home of the oral contraceptive' but I chose to explore the possibility with ICI of contributing to the development of their orphan drug ICI 46 474 (but not yet tamoxifen). During the time I was at the Worcester Foundation (1972–1974) there were only two clinical reports 22, 33 of the use of tamoxifen to treat breast cancer, but these were not randomized trials, there was no correlation between tumour ER and endocrine ablation, that was to be published in 1975 34, and there was no mention of tamoxifen as it was not used in this context. A correlation between response and tumour ER was noted later 35, 36. Adjuvant tamoxifen therapy and chemoprevention were not on the clinical landscape. There was much to do at the beginning to develop a rationale to advance a 'failed morning after pill'. They funded my research proposal but how to start. I needed to train myself to find a model to evaluate and quantify the antitumour effect of ICI 46 474. No laboratory antitumour studies had been done by ICI (or anyone else) but as Ehrlich had taught an 'appropriate animal model of human disease was necessary' to convince the clinical cancer community to conduct clinical trials. The prowess of ICI 46 474 as an effective 'morning after pill in rats' would not suffice! I found my model in Chicago at the Ben May Cancer Research Laboratories of the University of Chicago. I visited at the invitation of the Director, the late Dr Elwood V. Jensen in the spring of 1973. I learned the 'Jensen method' of measuring the tumour ER, an enormous improvement over my 'Heath Robinson' approach alone in the basement of Leeds University Old Medical School during my PhD. I learned the dimethylbenzanthracene (DMBA)-induced rat mammary carcinoma model 37 and had the good fortune to meet and talk with Professor Charles Huggins, the former director of the Ben May laboratory for Cancer Research and Nobel Laureate for his work on hormone dependent prostate cancer. This readily reproducible mammary tumour model is hormone (ovarian) dependent for growth and the tumours contained the ER 38. It was the only appropriate model. For the next decade this model would be my medium to propose targeting the ER positive tumour 39 with long term adjuvant tamoxifen therapy 40-42 or use the animal model in the first step towards chemoprevention of breast cancer 43, 44. All of this would occur at the Worcester Foundation (1972–1974) and at the Department of Pharmacology of the University of Leeds (1974–1979). The next dimension in discovery for therapeutics would occur in the 1980s at the University of Wisconsin Clinical Cancer Center (Madison) (1980–1993) in the United States. The nu/nu athymic mouse model was found to be immune deficient so human tumours could be transplanted and therapies studied to seek cures for cancer 45. Of particular interest to my new embryonic tamoxifen team in the Department of Human Oncology at the Clinical Cancer Center were the observations that the ER positive human breast cancer cell line MCF-7 46, 47 inoculated into the axillary mammary fat pad was able to grow into tumours with oestrogen treatment 48, 49. Furthermore, tamoxifen prevented oestrogenic-stimulated tumour growth 50. Here was the new model we needed. Marco Gottardis was an extremely talented technician conducting animal studies in the Department of Human Oncology in the Cancer Center. He accepted my invitation to become a graduate student in my laboratory. His work and publications changed therapeutics and medical care multiple times as he expertly used carcinogen-induced rat mammary tumour models 51 and established our colony of MCF-7 tumour bearing athymic mice 52. The latter model revolutionized our understanding of acquired resistance to long term tamoxifen therapy 53 and what to do about it in the clinic 54. The athymic mouse model would provide the leads to the target site specificity of 'non-steroidal anti-oestrogens' 55, 56. Harper & Walpole 57 had discovered the unusual species specificity to ICI 46 474. The triphenylethylene was classified as an oestrogen in the mouse vagina and this classification was confirmed by Terenius in immature micee with uterine weight tests 58. ICI 46 474 was classified as an anti-oestrogen in the rat with partial agonist uterine action 5. However the fact that ICI 46 474 (tamoxifen) acted as an anti-oestrogen to block oestrogen stimulated tumour cell growth in athymic mice 55 was a first clue that tamoxifen was tissue, not species, specific. The development of this observation in different target tissues would give the insight into a new group of medicines in women's health, the SERMs that switch on or switch off oestrogen target sites around the body 59. This is a fascinating story in molecular pharmacology as the interpretation of the two known ERs, i.e. α and β with different coregulators and receptor processing at different gene promoters, can produce agonist or antagonist action. This multifaceted decision network is summarized in Figure 4. Marco is now the Vice President and Prostate Cancer Disease Area Stronghold Leader for the Oncology Thera
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