Atish Mukherjee

The RANKL signaling axis is sufficient to elicit ductal side-branching and alveologenesis in the mammary gland of the virgin mouse.

Receptor of Activated NF-kappaB Ligand (RANKL) is implicated as one of a number of effector molecules that mediate progesterone and prolactin signaling in the murine mammary epithelium. Using a mouse transgenic approach, we demonstrate that installation of the RANKL signaling axis into the mammary epithelium results in precocious ductal side-branching and alveologenesis in the virgin animal. These morphological changes occur due to RANKL-induced mammary epithelial proliferation, which is accompanied by increases in expression of activated NF-kB and cyclin D1. With age, prolonged RANKL exposure elicits limited mammary epithelial hyperplasia. While these transgenics exhibit RANKL-induced salivary gland adenocarcinomas, palpable mammary tumors are not observed due to RANKL-suppression of its own signaling receptor (RANK) in the mammary epithelium. Together, these studies reveal not only that the RANKL signaling axis can program many of the normal epithelial changes attributed to progesterone and prolactin action in the normal mammary gland during early pregnancy, but underscore the necessity for tight control of this signaling molecule to avoid unwarranted developmental changes that could lead to mammary hyperplasia in later life.

Steroid receptor coactivator 2 is critical for progesterone-dependent uterine function and mammary morphogenesis in the mouse

ABSTRACT Although the essential involvement of the progesterone receptor (PR) in female reproductive tissues is firmly established, the coregulators preferentially enlisted by PR to mediate its physiological effects have yet to be fully delineated. To further dissect the roles of members of the steroid receptor coactivator (SRC)/p160 family in PR-mediated reproductive processes in vivo, state-of-the-art cre-loxP engineering strategies were employed to generate a mouse model (PRCre/+SRC-2flox/flox) in which SRC-2 function was abrogated only in cell lineages that express the PR. Fertility tests revealed that while ovarian activity was normal, PRCre/+SRC-2flox/flox mouse uterine function was severely compromised. Absence of SRC-2 in PR-positive uterine cells was shown to contribute to an early block in embryo implantation, a phenotype not shared by SRC-1 or -3 knockout mice. In addition, histological and molecular analyses revealed an inability of the PRCre/+SRC-2flox/flox mouse uterus to undergo the necessary cellular and molecular changes that precede complete P-induced decidual progression. Moreover, removal of SRC-1 in the PRCre/+SRC-2flox/flox mouse uterus resulted in the absence of a decidual response, confirming that uterine SRC-2 and -1 cooperate in P-initiated transcriptional programs which lead to full decidualization. In the case of the mammary gland, whole-mount and histological analysis disclosed the absence of significant ductal side branching and alveologenesis in the hormone-treated PRCre/+SRC-2flox/flox mammary gland, reinforcing an important role for SRC-2 in cellular proliferative changes that require PR. We conclude that SRC-2 is appropriated by PR in a subset of transcriptional cascades obligate for normal uterine and mammary morphogenesis and function.

Targeting RANKL to a specific subset of murine mammary epithelial cells induces ordered branching morphogenesis and alveologenesis in the absence of progesterone receptor expression

Despite support for receptor of activated NF‐kB ligand (RANKL) as a mediator of mammary progesterone action, the extent to which this cytokine can functionally contribute to established progesterone‐induced mammary morphogenetic responses in the absence of other presumptive effectors is still unclear. To address this uncertainty, we developed an innovative bigenic system for the doxycycline‐inducible expression of RANKL in the mammary epithelium of the progesterone receptor knockout (PRKO) mouse. In response to acute doxycycline exposure, RANKL is specifically expressed in the estrogen receptor a (ER) positive/progesterone receptor negative (ER+/PR−) cell type in the PRKO mammary epithelium, a cell type that is equivalent to the ER+/PR+ cell type in the wild‐type (WT) mammary epithelium. Notably, the ER+/PR+ mammary cell normally expresses RANKL in the WT mammary epithelium during pregnancy. In this PRKO bigenic system, acute doxycycline‐induced expression of RANKL results in ordered mammary ductal side branching and alveologenesis, morphological changes that normally occur in the parous WT mouse. This mammary epithelial expansion is accompanied by significant RANKL‐induced luminal epithelial proliferation, which is driven, in part, by indirect induction of cyclin D1. Collectively, our findings support the conclusion that RANKL represents a critical mediator of mammary PR action and that restricted expression of this effector to the ER+/PR+ mammary cell‐type is necessary for a spatially ordered morphogenetic response to progesterone.—Mukherjee, A., Soyal, S. M., Li, J., Ying, Y., He, B., DeMayo, F.J., Lydon, J. P. Targeting RANKL to a specific subset of murine mammary epithelial cells induces ordered branching morphogenesis and alveologenesis in the absence of progesterone receptor expression. FASEB J. 24, 4408–4419 (2010). www.fasebj.org

Steroid receptor coactivator 2 is required for female fertility and mammary morphogenesis: insights from the mouse, relevance to the human.

Although the importance of the progesterone receptor (PR) to female reproductive and mammary gland biology is firmly established, the coregulators selectively co-opted by PR in these systems have not been clearly delineated. A selective gene-knockout approach applied to the mouse, which abrogates gene function only in cell types that express PR, recently disclosed steroid receptor coactivator 2 (SRC-2, also known as TIF-2 or GRIP-1) to be an indispensable coregulator for uterine and mammary gland responses that require progesterone. Uterine cells positive for PR (but devoid of SRC-2) were found to be incapable of facilitating embryo implantation, a necessary first step toward the establishment of the materno-fetal interface. Importantly, such an implantation defect is not exhibited by knockouts for SRC-1 or SRC-3, underscoring the unique coregulator importance of SRC-2 in peri-implantation biology. Moreover, despite normal levels of PR, SRC-1 and SRC-3, progesterone-dependent branching morphogenesis and alveologenesis fails to occur in the murine mammary gland in the absence of SRC-2, thereby establishing a critical coregulator role for SRC-2 in signaling cascades that mediate progesterone-induced mammary epithelial proliferation. Finally, the recent detection of SRC-2 in the human endometrium and breast suggests that this coregulator may represent a new clinical target for the future management of female reproductive health and/or breast cancer.

A mouse model to dissect progesterone signaling in the female reproductive tract and mammary gland.

Considering the regulatory complexities of progesterone receptor (PR) action throughout the female reproductive axis and mammary gland, we generated a mouse model that enables conditional ablation of PR function in a spatiotemporal specific manner. Exon 2 of the murine PR gene was floxed to generate a conditional PR allele (PRflox) in mice. Crossing the PRflox/flox mouse with the ZP3‐cre transgenic demonstrated that the PRflox allele recombines to a PR null allele (PRd). Mice homozygous for the recombined null PR allele (PRd/d) exhibit uterine, ovarian, and mammary gland defects that phenocopy those of our previously described PR knockout (PRKO) model. Therefore, this conditional mouse model for PR ablation represents an invaluable resource with which to further define in a developmental and/or reproductive stage‐specific manner the individual and integrative roles of distinct PR populations resident in multiple progesterone‐responsive target sites. genesis 48:106–113, 2010.

Steroid receptor coactivator 2 is essential for progesterone-dependent uterine function and mammary morphogenesis: insights from the mouse--implications for the human.

While the indispensability of the progesterone receptor (PR) in female reproduction and mammary morphogenesis is acknowledged, the coregulators preferentially recruited by PR to mediate its in vivo effects have yet to be fully delineated. To further parse the roles of steroid receptor coactivator (SRC)/p160 family members in P-dependent physiological processes, genetic approaches were employed to generate a mouse model (PR(Cre/+)SRC-2(flox/flox)) in which SRC-2 function was ablated specifically in cell-types that express the PR. Fertility evaluation revealed that while ovulation occurred normally in the PR(Cre/+)SRC-2(flox/flox) mouse, uterine function was markedly affected. Absence of SRC-2 in PR positive uterine cells contributed to an early block in embryo implantation, a phenotype not shared by knockouts for SRC-1 or -3. Although the PR(Cre/+)SRC-2(flox/flox) uterus could mount a partial decidual response, removal of SRC-1 in the PR(Cre/+)SRC-2(flox/flox) uterus resulted in a complete block in decidualization, confirming that uterine SRC-2 and -1 are both required for P-initiated transcriptional programs which lead to full decidualization. In the case of the mammary gland, whole-mount and histological analyses revealed the absence of significant branching morphogenesis in the hormone-treated PR(Cre/+)SRC-2(flox/flox) mammary gland, reinforcing an important role for mammary SRC-2 in cellular proliferative events that require PR. Based on the above and the observation that SRC-2 is expressed in many of the uterine and mammary cell-lineages in the human as observed in the mouse, we suggest that further investigations are warranted to gain additional insights into SRC-2s involvement in normal (and possibly abnormal) uterine and mammary cellular responses to progestins.

Progesterone-action in the murine uterus and mammary gland requires steroid receptor coactivator 2: relevance to the human.

The importance of the progesterone receptor (PR) in female reproductive and mammary gland biology is well recognized; however, the coregulators selectively enlisted by PR have yet to be comprehensively defined in vivo. To evaluate the involvement of steroid receptor coactivator (SRC)/p160 family members in these physiological systems, a mouse model (PRCre/+SRC-2flox/flox) was generated in which SRC-2 function was ablated specifically in cell-types that express the PR. Although PRCre/+SRC-2flox/flox ovarian activity was normal, uterine function was severely compromised. Absence of SRC-2 in PR positive uterine cells led to an early block in embryo implantation, a defect not ascribed to SRC-1 or -3 knockouts. While the PRCre/+SRC-2flox/flox uterus can display a partial decidual response, removal of SRC-1 in the PRCre/+SRC-2flox/flox uterus results in a block in decidualization, confirming that uterine SRC-2 and -1 are both necessary for PR-mediated transcriptional responses which lead to complete decidualization. The absence of significant branching and alveolar morphogenesis in the hormone-treated PRCre/+SRC-2flox/flox mammary gland establishes an important role for mammary SRC-2 in cellular proliferative programs that require PR. Finally, the observation that SRC-2 is also expressed in many of the same cell-types in the human, underscores the importance of further study of this coregulators role in both peri-implantation biology and mammary development.

Steroid Receptor Coactivator 2: An Essential Coregulator of Progestin-Induced Uterine and Mammary Morphogenesis

The importance of the progesterone receptor (PR) in transducing the progestin signal is firmly established in female reproductive and mammary gland biology; however, the coregulators preferentially recruited by PR in these systems have yet to be comprehensively investigated. Using an innovative genetic approach, which ablates gene function specifically in murine cell-lineages that express PR, steroid receptor coactivator 2 (SRC-2, also known as TIF-2 or GRIP-1) was shown to exert potent coregulator properties in progestin-dependent responses in the uterus and mammary gland. Uterine cells positive for PR (but devoid of SRC-2) led to an early block in embryo implantation, a phenotype not shared by knockouts for SRC-1 or SRC-3. In the case of the mammary gland, progestin-dependent branching morphogenesis and alveologenesis failed to occur in the absence of SRC-2, thereby establishing a critical coactivator role for SRC-2 in cellular proliferative programs initiated by progestins in this tissue. Importantly, the recent detection of SRC-2 in both human endometrium and breast suggests that this coregulator may provide a new clinical target for the future management of female reproductive health and/or breast cancer.