Progestins used for hormonal contraception in Switzerland: study of their effects on the breast epithelium

Marie Shamseddin
EPFL, 2018
Thèse EPFL

Résumé

Breast cancer is the most commonly diagnosed cancer and the most common cause of cancer death among women. Hormones have been shown to have a key role in breast development and carcinogenesis. Repeated activation of progesterone receptor (PR) signaling as it occurs during menstrual cycles is important in cancer risk. Through hormonal contraception many women are exposed to synthetic PR agonists, progestins, either on their own or in combination with the synthetic estrogen receptor (ER) agonist, ethinyl estradiol (EE). Progestins vary in their chemical structures and biological activities. Epidemiological studies show that hormonal contraceptions increase the risk of breast cancer but to date there have been few studies that analyze specific progestins regarding the breast cancer risk they confer. We hypothesized that different progestins have distinct abilities to induce cell proliferation and to modulate gene expression in the breast epithelium and this may ultimately have different effects on breast cancer risk. To test the hypothesis that different progestins currently used in hormonal contraceptions in Switzerland have distinct abilities to induce the expression of important mediators of PR action, receptor activator of NF-ÎºB ligand (RANKL) and Wnt4, we employed mouse mammary gland organoids and human breast tissue microstructures. We find that androgenic progestins strongly induce RANKL and Wnt4 whereas anti-androgenic progestins fail to do so. To test the ability of different progestins currently used in hormonal contraceptions in Switzerland to induce cell proliferation in human breast epithelium, we humanized mouse mammary gland using intraductal injection of human breast epithelial cells obtained from reduction mammoplasty surgery. We show that breast epithelial cells maintain hormone receptor expression and remain hormone responsive in this approach. We find that the androgenic progestins, Gestodene and Levonorgestrel, promote cell proliferation over two months more than progesterone. Furthermore, we show that Androgen receptor (AR) inhibition abrogates promegestone-induced RANKL induction and reduces cell proliferation induced by androgenic progestin, LNG. We also show that activation of AR signaling through DHT exposure is sufficient to induce proliferation of human breast epithelial cells. Thus, different progestins have different biological effects on the breast epithelium that appear to be related to their androgenic activities.

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https://infoscience.epfl.ch/record/256105?ln=fr

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Marie Shamseddin
EPFL, 2018
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/256105?ln=fr

À propos de ce résultat

Concepts associés (25)

Concepts associés

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Publications associées (69)

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90 YEARS OF PROGESTERONE Progesterone receptor signaling in the normal breast and its implications for cancer

Cathrin Brisken, Valentina Scabia

Progesterone is considered as the pregnancy hormone and acts on many different target tissues. Progesterone receptor (PR) signaling is important for normal development and the physiologic function of the breast and impinges on breast carcinogenesis. Both systemically and locally, in the breast epithelium, there are multiple layers of complexity to progesterone action, many of which have been revealed through experiments in mice. The hormone acts via its receptor expressed in a subset of cells, the sensor cells, in the breast epithelium with different signaling outcomes in individual cells eliciting distinct cell-intrinsic and paracrine signaling involving different mediators for different intercellular interactions. PR expression itself is developmentally regulated and the biological outcome of PR signaling depends on the developmental stage of the mammary gland and the endocrine context. During both puberty and adulthood PR activates stem and progenitor cells through Wnt4-driven activation of the myoepithelium with downstream Adamts18-induced changes in extracellualr matrix (ECM) / basal membrane (BM). During estrous cycling and pregnancy, the hormone drives a major cell expansion through Rankl. At all stages, PR signaling is closely tied to estrogen receptor a (ER) signaling. As the PR itself is a target gene of ER, the complex interactions are experimentally difficult to dissect and still poorly understood. Ex vivo models of the human breast and studies on biopsy samples show that major signaling axes are conserved across species. New intraductal xenograft models hold promise to provide a better understanding of PR signaling in the normal breast epithelium and in breast cancer development in the near future.

BIOSCIENTIFICA LTD2020

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Estrogens and progesterones are major drivers of breast development but also promote carcinogenesis in this organ. Yet, their respective roles and the mechanisms underlying their action in the human breast are unclear. Receptor activator of nuclear factor kappa B ligand (RANKL) has been identified as a pivotal paracrine mediator of progesterone function in mouse mammary gland development and mammary carcinogenesis. Whether the factor has the same role in humans is of clinical interest because an inhibitor for RANKL, denosumab, is already used for the treatment of bone disease and might benefit breast cancer patients. We show that progesterone receptor (PR) signaling failed to induce RANKL in PR+ breast cancer cell lines and in dissociated, cultured breast epithelial cells. In clinical specimens from healthy donors and intact breast tissue microstructures, hormone response was maintained and RANKL expression was under progesterone control, which increased RNA stability. RANKL was sufficient to trigger cell proliferation and was required for progesterone-induced proliferation. The findings were validated in vivo where RANKL protein expression in the breast epithelium correlated with serum progesterone levels and the protein was expressed in a subset of luminal cells that express PR. Thus, important hormonal control mechanisms are conserved across species, making RANKL a potential target in breast cancer treatment and prevention.

American Association for the Advancement of Science2013

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The female reproductive hormones estrogens, progesterone, and prolactin control postnatal breast development and are important to breast carcinogenesis. In particular, exposure to progesterone is tightly linked to breast cancer risk. Using the mouse as a model system to study the mechanisms through which hormones elicit morphogenetic changes in the mammary gland in vivo, we demonstrated that progesterone acts by a paracrine mechanism and identified Wnt4 as a target of progesterone important in mediating side branch formation. The mechanisms underlying Wnt4 function remains poorly understood. To understand the pattern of canonical Wnt signaling activation during mammary gland development and to address which cellular compartment of the mammary gland is activated by canonical Wnt signaling, a reporter mouse model was utilized in which the lacZ gene is under the control of endogenous Axin2 promoter, classical target promoter of canonical Wnt signaling. Analysis of reporter mice at different developmental stages of mammary gland development showed the highest reporter activity during early pregnancy which correlated with the time of side branch formation. At this stage, β-galactosidase activity was found exclusively in myoepithelial cells. Overexpression of Wnt1 from MMTV promoter increases reporter activity in the myoepithelium. Gene expression analysis on FACS sorted luminal and myoepithelial cells shows that known canonical Wnt signaling pathway components such as receptors and co receptors as well as targets are specifically expressed in the myoepithelial compartment further supporting the notion that myoepithelial cells are the target cells for Wnt1 and Wnt4 secreted by luminal cells. Consistent with a model whereby progesterone induced Wnt4 secretion results in canonical Wnt signaling activation, reporter activity was induced by progesterone treatment and lacZ expression increased during diestrus when serum progesterone levels are high under physiological conditions. Analysis of contralateral mammary glands engrafted with PR-/-.Axin2 lacZ and PR+/-.Axin2 lacZ epithelium during pregnancy revealed that intact PR signaling is required to activate canonical Wnt signaling. Similar experiments with Wnt4-/-.Axin2 lacZ and Wnt4+/+.Axin2 lacZ mammary epithelium showed that reporter activation relies on Wnt4. Histological analysis on mammary glands in which β-catenin was ablated using MMTV-Cre revealed that β-catenin deleted cells were present only in the luminal epithelial compartment and showed that β-catenin deleted myoepithelial cells cannot participate in side branch formation. Similarly, ectopic expression of dominant negative β-catenin in wt MECs reduced side branching indicating that canonical Wnt signaling mediated by β-catenin is required for side branching. Furthermore, constitutive activation of β-catenin in the mammary epithelium was sufficient to induce side branch formation in virgin mice. In Wnt4 mutant epithelium, proliferation of progesterone receptor positive and negative cells were significantly reduced in response to progesterone treatment. Wnt signaling has been implicated in stem/progenitor activation in several tissues including mammary gland. Consistent with Wnt4 activating stem/progenitors, serial transplantation assays revealed that Wnt4-/- epithelium failed to reconstitute already at 2nd to 3rd generation when the wt has the ability to reconstitute up to seven generations indicating that Wnt4 is required for stem cell function while Wnt4 is dispensable for embryonic and rudimentary mammary gland formation. Histology and gene expression analysis in late pregnancy showed that Wnt4 mutant epithelia were able to differentiate and produce milk proteins, further supporting the thought that Wnt4 function is important for stem/progenitor cell activity and not required for differentiation. Taken together, I report that Wnt4 induces canonical Wnt signaling in myoepithelial cells and activation of canonical Wnt signaling is required and sufficient for side branching. Moreover, Wnt4 function is essential for mammary stem/progenitor cells.

EPFL2010

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EPFL2010