Expression of the insulin-like growth factor binding proteins during postnatal development of the murine mammary gland

IGF-I and IGF-II have known roles in postnatal development of the mammary gland. In contrast, the function of the high-affinity IGF binding proteins (IGFBPs) in mammary growth and differentiation is largely unknown. The goal of these studies was to determine the patterns and levels of IGFBP expression during postnatal growth of the murine mammary gland. IGFBP-1 to -5 proteins were detected in mammary tissue by immunoblotting during both pubertal and pregnancy-induced growth; however, the regulation of each IGFBP was distinct through these developmental periods. IGFBP-2 to -5 mRNAs were readily detectable in the developing gland by in situ hybridization analyses but were expressed in distinct cellular sites. IGFBP-3 and -5 mRNAs were expressed in the developing epithelial structures and in isolated stromal cells during ductal growth and alveolar differentiation. In the terminal end buds (TEBs), IGFBP-3 mRNA expression was consistent with its localization in the cap cells, whereas IGFBP-5 was highly expressed in the body cells of the TEB. In contrast, IGFBP-2 and -4 mRNAs were expressed predominantly in stromal cells. IGFBP-2 mRNA was localized to restricted sites in the neck of the TEB and along the ductal structures, whereas IGFBP-4 mRNA was widely expressed in the stroma surrounding the epithelial structures. Protein and mRNA expression for most of the IGFBPs decreased during lactational ages. Levels of IGFBP-2 and -5 protein increased after pup removal during forced involution. Taken together, these data suggest important functions for the family of IGFBPs during postnatal growth and differentiation of the mammary epithelium.     

Autocrine growth hormone prevents lactogenic differentiation of mouse mammary epithelial cells

We have examined the expression, postnatal ontogeny, and localization of mouse GH (mGH) and its relative expression during pregnancy, lactation, and weaning in the mouse. mGH mRNA and protein was expressed predominantly in the epithelial component of the mammary gland, and maximal expression was observed during the pubertal period. Autocrine mGH expression dramatically decreased during late pregnancy and lactation. Concordantly, autocrine mGH expression is repressed during forced differentiation of mouse HC11 mammary epithelial cells in culture. Forced expression of mGH in HC11 cells abrogated lactogenic differentiation as indicated by reduced expression of beta-casein and reduced expression and loss of lateral epithelial localization of E-cadherin. Forced expression of mGH in mouse mammary epithelial cells increased cell survival and proliferation and consequently increased the size of mammary acinar-like structures formed in three-dimensional Matrigel. Thus, autocrine mGH expression in the mouse mammary epithelial cell is maximal at puberty and prevents mammary epithelial cell differentiation. Autocrine GH will therefore participate in mammary morphogenic processes at puberty.     

Delayed mammary gland involution in mice with mutation of the insulin-like growth factor binding protein 5 gene

IGFs (IGF-I and IGF-II) are essential for development, and their bioactivities are tightly regulated by six related IGF-binding proteins (IGFBPs). IGFBP-5 is the most highly conserved binding protein and is expressed in several key developmental lineages as well as in multiple adult tissues including the mammary gland. To explore IGFBP-5 actions in vivo, we produced IGFBP-5 knockout (KO) mice. Whole-body growth, selected organ weights, and body composition were essentially normal in IGFBP-5 KO mice, presumably because of substantial compensation by remaining IGFBP family members. The IGFBP-5 KO mice also exhibited normal mammary gland development and were capable of nursing their pups. We then directly evaluated the proposed role of IGFBP-5 in apoptosis and remodeling of mammary gland during involution. We found that the process of involution after forced weaning was delayed in IGFBP-5 KO mice, with both the appearance of apoptotic cells and the reappearance of adipocytes retarded in mutant mice, compared with controls. We also determined the effects of IGFBP-5 deletion on mammary gland development in pubertal females after ovariectomy and stimulation with estradiol/progesterone. In this paradigm, IGFBP-5 KO mammary glands exhibited enhanced alveolar bud formation consistent with enhanced IGF-I action. These results demonstrate that IGFBP-5, although not essential for normal growth, is required for normal mammary gland involution and can regulate mammary gland morphogenesis in response to hormone stimulation.     

Elevated circulating IGF-I promotes mammary gland development and proliferation

Animal studies have shown that IGF-I is essential for mammary gland development. Previous studies have suggested that local IGF-I rather than circulating IGF-I is the major mediator of mammary gland development. In the present study we used the hepatic IGF-I transgenic (HIT) and IGF-I knockout/HIT (KO-HIT) mouse models to examine the effects of enhanced circulating IGF-I on mammary development in the presence and absence of local IGF-I. HIT mice express the rat IGF-I transgene under the transthyretin promoter in the liver and have elevated circulating IGF-I and normal tissue IGF-I levels. The KO-HIT mice have no tissue IGF-I and increased circulating IGF-I. Analysis of mammary gland development reveals a greater degree of complexity in HIT mice as compared to control and KO-HIT mice, which demonstrate similar degrees of mammary gland complexity. Immunohistochemical evaluation of glands of HIT mice also suggests an enhanced degree of proliferation of the mammary gland, whereas KO-HIT mice exhibit mammary gland proliferation similar to control mice. In addition, HIT mice have a higher percentage of proliferating myoepithelial and luminal cells than control mice, whereas KO-HIT mice have an equivalent percentage of proliferating myoepithelial and luminal cells as control mice. Thus, our findings show that elevated circulating IGF-I levels are sufficient to promote normal pubertal mammary epithelial development. However, HIT mice demonstrate more pronounced mammary gland development when compared to control and KO-HIT mice. This suggests that both local and endocrine IGF-I play roles in mammary gland development and that elevated circulating IGF-I accelerates mammary epithelial proliferation.     

Estrogen mediates mammary epithelial cell proliferation in serum-free culture indirectly via mammary stroma-derived hepatocyte growth factor

Epithelial-stromal cell interactions are important for normal development and function of the mouse mammary gland. The steroid hormone estrogen is required for epithelial cell proliferation and ductal development in vivo. Recent studies of estrogen receptor alpha knockout mice indicate that estrogen-induced proliferation is dependent upon the presence of estrogen receptor in mammary stromal cells, but not in epithelial cells. The purpose of the present study was to identify the underlying mechanism of estrogen-dependent stroma-derived effects on mammary epithelium. We have developed a minimally supplemented serum-free medium, collagen gel primary mammary coculture system to address the issue of stroma-derived, estrogen-dependent effects on epithelial cell proliferation. Conditioned medium from mammary fibroblasts or coculture with mammary fibroblasts caused increased epithelial cell proliferation and produced tubular/ductal morphology. Hepatocyte growth factor (HGF) was identified as the mediator of this effect, as the proliferative activity in fibroblast-conditioned medium was completely abolished by neutralizing antibody to HGF, whereas neutralizing antibodies to either epidermal growth factor or IGF-I had no effect. Treatment of mammary fibroblasts with estrogen increased the production of HGF. From these results we conclude that estrogen may indirectly mediate mammary epithelial cell proliferation via the regulation of HGF in mammary stromal cells and that HGF plays a crucial role in estrogen-induced proliferation in vivo.     

A novel method for growing human breast epithelium in vivo using mouse and human mammary fibroblasts

A novel system is described for studying the growth of normal human mammary epithelium in vivo as grafts in athymic nude mice. The key feature of this model is reconstitution of the epithelial-stromal interactions required for normal growth and differentiation of the human mammary epithelium, which produces ducts that are comparable to those in the normal human mammary gland. Human breast epithelial organoids were combined with mammary fibroblasts from mouse or human origin in collagen gels, which were subsequently transplanted under the renal capsule of female nude mice hosts. The resulting grafts showed an increase in the ductal density compared with that observed previously. These ducts expressed appropriate markers for luminal and myoepithelial cells and steroid receptors. Treatment of the host with diethylstilbestrol or estradiol and progesterone significantly increased the number of ducts observed and increased cell proliferation. The grafts also displayed production of beta-casein and milk fat globule membrane protein when the hosts were allowed to become pregnant. This model allows for a variety of epithelial and stromal cells to be used in combination, which would aid in understanding key factors that regulate normal human mammary gland development.     

Mammary gland development in adult mice requires epithelial and stromal estrogen receptor alpha

Complete mammary gland development takes place following puberty and depends on the estrogen receptor (ER)alpha and the progesterone receptor (PR) and is tightly regulated by the interaction of the mammary epithelium with the stromal compartment. Studies using mammary tissues of immature mice have indicated that stromal but not epithelial ER alpha is required for mammary gland growth. This study investigates whether these same tissue growth requirements of neonate tissue are necessary for mammary development and response in adult mice. Mammary epithelial cells were isolated from adult mice with a targeted disruption of the ER alpha gene (alpha ERKO) or from wild-type counterparts and injected into epithelial-free mammary fat pads of 3-wk-old female alpha ERKO or wild-type mice. Ten weeks after cell injection, analysis of mammary gland whole mounts showed that both stromal and epithelial ER alpha were required for complete mammary gland development in adult mice. However, when the mice were treated with high doses of estradiol (E2) and progesterone, stromal ER alpha was sufficient to generate full mammary gland growth. Surprisingly, ER alpha-deficient epithelial cells were able to proliferate and develop into a rudimentary mammary ductal structure in an ER alpha-negative stroma, indicating that neither stromal nor epithelial ER alpha are required for the mammary rudiment to form in the adult mouse, as confirmed by the phenotype of the alpha ERKO mammary gland. Use of this in vivo model system has demonstrated that neonatal and adult mammary tissues use a different tissue-specific role for ER alpha in mammary response. Immunostaining for ER alpha and PR in the mammary outgrowths supported the view that both stromal and epithelial ER alpha, in cooperation with epithelial PR, govern mammary gland development in adult mice.     

Disruption of prostate epithelial androgen receptor impedes prostate lobe-specific growth and function

Prostate development and maturation requires stromal-epithelial interactions and androgen action via the androgen receptor (AR) within these compartments. However, the specific roles of epithelial and stromal AR in postnatal prostate differentiation are unclear. We used Cre-LoxP technology to determine the prostate phenotype in mice with epithelial-selective genetic inactivation of the AR leaving the stromal AR functionally intact. We find that prostate development abolished in mice globally lacking a functional AR can be rescued by restricting the AR knockout to the postnatal prostate epithelium. We show that, at 8 wk of age, prostate epithelial AR knockout (PEARKO) mice exhibit prostate development with normal branching morphogenesis but lobe-specific decrease in prostate weight and hindered structural and functional differentiation of the mature prostate epithelium. No change was observed in PEARKO testis weight or serum testosterone compared with littermate controls. The most striking change was increased proliferation and abnormal lesions of epithelial cells predominantly in the anterior lobe of PEARKO mice. These findings highlight the vital role of stromal AR in postnatal prostate growth and structural differentiation and emphasize the requirement of epithelial AR in maintaining functional differentiation and restraining proliferation of epithelial cells in a lobe-specific manner. This unique PEARKO mouse provides a new paradigm with which to define the molecular mechanisms of the androgen signaling in mature prostate lobes in vivo and provides insight into the identification of better targets for treatment of prostate cancer and hyperplasia.     

The role of prolactin and growth hormone in mammary gland development

Development and differentiation of the mammary gland occur primarily during pregnancy. Females homozygous (-/-) for the null mutation of the PRL receptor (PRLR) gene are sterile due to a complete failure of blastocysts to implant. In progesterone-treated mice pregnancy is rescued but the mammary gland is severely underdeveloped. Interestingly, females hemizygous for the PRLR (+/-) in their first lactation show an almost complete failure to lactate. This phenotype disappears in the second and subsequent pregnancies in inbred 129/Sv mice but is maintained in inbred C57BL/6 mice. In GH receptor (GHR) KO mice litter size is markedly decreased, probably due to an ovarian defect. To assess the relevance of the GH and PRLRs in the mammary gland development, GHR and PRLR null epithelia were transplanted into cleared fat pads of wild-type mice. Such studies show that epithelial GHR is not required for functional mammary development. In contrast, epithelial PRLRs are required for mammary development and milk protein gene expression during pregnancy. Since ductal development is impaired in GHR -/- mice, it appears that GH signals through the stromal compartment. In summary, it is now established that GH and PRL activate Stat5 in separate compartments, reflecting their specific roles in ductal and alveolar development and differentiation.     

A paracrine role for the epithelial progesterone receptor in mammary gland development

Recently generated progesterone receptor (PR)-negative (PR^−/−) mice provide an excellent model for dissecting the role of progesterone in the development of the mammary gland during puberty and pregnancy. However, the full extent of the mammary gland defect in these mice caused by the absence of the PR cannot be assessed, because PR^−/− mice do not exhibit estrous cycles and fail to become pregnant. To circumvent this difficulty, we have transplanted PR^−/− breasts into wild-type mice, and we have demonstrated that the development of the mammary gland in the absence of the PR is arrested at the stage of the simple ductal system found in the young virgin mouse. Mammary transplants lacking the PR in the stromal compartment give rise to normal alveolar growth, whereas transplants containing PR^−/− epithelium conserve the abnormal phenotype. Chimeric epithelia in which PR^−/− cells are in close vicinity to PR wild-type cells go through complete alveolar development to which the PR^−/− cells contribute. Together, these results indicate that progesterone acts by a paracrine mechanism on a subset of mammary epithelial cells to allow for alveolar growth and that expression of the PR is not required in all the cells of the mammary epithelium in order for alveolar development to proceed normally.     

Requirement for IGF-I in epidermal growth factor-mediated cell cycle progression of mammary epithelial cells

Induction of cyclin proteins is required for progression of cells through the G(1)-S and G(2)-M cell cycle checkpoints and is a primary mechanism by which mitogens regulate cell cycle progression. IGF-I and the epidermal growth factor (EGF)-related ligands are mitogens for mammary epithelial cells in vitro and are essential for growth of the mammary epithelium during development. We report here that IGF-I in combination with EGF or TGFalpha is synergistic in promoting DNA synthesis in mammary epithelial cells in the intact mammary gland cultured in vitro. We further investigated the role of IGF-I and EGF in cyclin expression and cell cycle progression in the mammary gland and demonstrate that IGF-I and EGF induce expression of early G(1) cyclins. However, we show that IGF-I, but not EGF, induces late G(1) and G(2) cyclins and is required for mammary epithelial cells to overcome the G(1)-S checkpoint. These data demonstrate that IGF-I is essential for cell cycle progression in mammary epithelial cells and that it is required for EGF-mediated progression past the G(1)-S checkpoint in these cells.     

Retinoid prevents mammary gland transformation by carcinogenic hydrocarbon in whole-organ culture.

The mouse mammary gland in whole-organ culture, an in vitro system that is capable of alveolar development, differentiation, involution, and oncogenic transformation, has been used to examine the effects of the retinoid 2-retinylidene-5,5-dimethyl-1,3-cyclohexanedione (retinylidene dimedone) on epithelial transformation by a low concentration (10 nM) of the carcinogen 7,12-dimethylbenz[a]anthracene. The retinoid significantly prevented mammary gland transformation only when administered after the carcinogen. In addition, the phenotypes of the early transformed state of the mammary gland were suppressed for 20 days after removal of the retinoid. The retinoid was effective during both mammary alveolar development and regression in culture at concentrations as low as 1 nM, and itself had no significant transforming or cytotoxic activity. Mammary glands treated with both the carcinogen and the retinoid resembled, at the microscopic level, those given the solvent (dimethyl sulfoxide) only. The mouse mammary gland in whole-organ culture provides a promising model system in which to study the actions by which retinoids prevent and suppress the chemical transformation in vitro and oncogenesis in vivo of epithelial cells in general and of mammary gland in particular. The present findings support the suggestion that a search for suitable retinoids as chemopreventive agents against human breast cancer is warranted. This model system may be useful as initial indicator in that search.     

Decreased IGF type 1 receptor signaling in mammary epithelium during pregnancy leads to reduced proliferation, alveolar differentiation, and expression of insulin receptor substrate (IRS)-1 and IRS-2

The IGFs and the IGF type 1 receptor (IGF-1R) are essential mediators of normal mammary gland development in mice. IGF-I and the IGF-1R have demonstrated functions in formation and proliferation of terminal end buds and in ductal outgrowth and branching during puberty. To study the functions of IGF-1R during pregnancy and lactation, we established transgenic mouse lines expressing a human dominant-negative kinase dead IGF-1R (dnhIGF-1R) under the control of the whey acidic protein promoter. We provide evidence that the IGF-1R pathway is necessary for normal epithelial proliferation and alveolar formation during pregnancy. Furthermore, we demonstrate that the whey acidic protein-dnhIGF-1R transgene causes a delay in alveolar differentiation including lipid droplet formation, lumen expansion, and β-casein protein expression. Analysis of IGF-1R signaling pathways showed a decrease in P-IGF-1R and P-Akt resulting from expression of the dnhIGF-1R. We further demonstrate that disruption of the IGF-1R decreases mammary epithelial cell expression of the signaling intermediates insulin receptor substrate (IRS)-1 and IRS-2. No alterations were observed in downstream signaling targets of prolactin and progesterone, suggesting that activation of the IGF-1R may directly regulate expression of IRS-1/2 during alveolar development and differentiation. These data show that IGF-1R signaling is necessary for normal alveolar proliferation and differentiation, in part, through induction of signaling intermediates that mediate alveolar development.     

Intact and amino-terminally shortened forms of insulin-like growth factor I induce mammary gland differentiation and development.

Growth hormone (GH) plays a role in regulating growth and differentiation of immature glandular structures in the mammary gland, but the mechanisms by which the hormone exerts these effects are unknown. We have previously found that GH stimulates insulin-like growth factor I (IGF-I) I mRNA production within the mammary glands of hypophysectomized rats. In this study we set out to determine if IGF-I administration could mimic the action of GH in initiating mammary gland differentiation and development. Two forms of IGF-I, intact and amino-terminally shortened [des-(1-3)-IGF-I], were found to induce the development of terminal end buds and the formation of alveolar structures in the mammary glands of hypophysectomized, castrated, and estradiol-treated sexually immature male rats. The effect of both forms of IGF-I was similar to that obtained with human GH, but the truncated form was at least 5 times more potent than intact IGF-I. These findings suggest that the inductive effect of GH on glandular differentiation is mediated by the GH-induced production of IGF-I or a related molecule within the mammary gland itself.