Actions of estrogens and endocrine disrupting chemicals on human prostate stem/progenitor cells and prostate cancer risk

Estrogen reprogramming of the prostate gland as a function of developmental exposures (aka developmental estrogenization) results in permanent alterations in structure and gene expression that lead to an increased incidence of prostatic lesions with aging. Endocrine disrupting chemicals (EDCs) with estrogenic activity have been similarly linked to an increased prostate cancer risk. Since it has been suggested that stem cells and cancer stem cells are potential targets of cancer initiation and disease management, it is highly possible that estrogens and EDCs influence the development and progression of prostate cancer through reprogramming and transforming the prostate stem and early stage progenitor cells. In this article, we review recent literature highlighting the effects of estrogens and EDCs on prostate cancer risk and discuss recent advances in prostate stem/progenitor cell research. Our laboratory has recently developed a novel prostasphere model using normal human prostate stem/progenitor cells and established that these cells express estrogen receptors (ERs) and are direct targets of estrogen action. Further, using a chimeric in vivo prostate model derived from these normal human prostate progenitor cells, we demonstrated for the first time that estrogens initiate and promote prostatic carcinogenesis in an androgen-supported environment. We herein discuss these findings and highlight new evidence using our in vitro human prostasphere assay for perturbations in human prostate stem cell self-renewal and differentiation by natural steroids as well as EDCs. These findings support the hypothesis that tissue stem cells may be direct EDC targets which may underlie life-long reprogramming as a consequence of developmental and/or transient adult exposures.     

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.     

Hormone and growth factor signaling in endometrial renewal: role of stem/progenitor cells

The human endometrium is a dynamic remodeling tissue undergoing more than 400 cycles of regeneration, differentiation and shedding during a woman's reproductive years. The co-ordinated and sequential actions of estrogen and progesterone direct these major remodeling events preparing a receptive endometrium for blastocyst implantation on a monthly basis. Adult stem/progenitor cells are likely responsible for endometrial regeneration. Functional approaches have been used to identify candidate endometrial stem/progenitor cells, as there are no specific stem cell markers. Rare populations of human endometrial epithelial and stromal colony-forming cells/units (CFU) and side population (SP) cells have been identified. Several growth factors are required for CFU activity: epidermal growth factor (EGF), transforming growth factor alpha (TGFalpha) and platelet-derived growth factor BB (PDGF-BB) for both epithelial and stromal CFU, and basic fibroblast growth factor (bFGF) for stromal, but not epithelial CFU. A sub-population of human endometrial stromal cells with mesenchymal stem cell properties of CFU activity and multilineage (fat, muscle, cartilage and bone) differentiation have been isolated by their co-expression of CD146 and PDGF-receptor beta. Candidate epithelial and stromal stem/progenitor cells have been identified in mouse endometrium as rare label retaining cells (LRCs) in the luminal epithelium and as perivascular cells at the endometrial-myometrial junction, respectively. While epithelial and most stromal LRC do not express estrogen receptor alpha (Esr1), they rapidly proliferate on estrogen stimulation, most likely mediated by neighbouring Esr1-expressing niche cells. It is likely that these newly identified endometrial stem/progenitor cells may play key roles in the development of gynecological diseases associated with abnormal endometrial proliferation such as endometriosis and endometrial cancer.     

A role for estrogen receptor beta in the regulation of growth of the ventral prostate

In normal rats and mice, immunostaining with specific antibodies revealed that nuclei of most prostatic epithelial cells harbor estrogen receptor beta (ERbeta). In rat ventral prostate, 530- and 549-aa isoforms of the receptor were identified. These sediment in the 4S region of low-salt sucrose gradients, indicating that prostatic ERbeta does not contain the same protein chaperones that are associated with ERalpha. Estradiol (E(2)) binding and ERbeta immunoreactivity coincide on the gradient, with no indication of ERalpha. In prostates from mice in which the ERbeta gene has been inactivated (BERKO), androgen receptor (AR) levels are elevated, and the tissue contains multiple hyperplastic foci. Most epithelial cells express the proliferation antigen Ki-67. In contrast, prostatic epithelium from wild-type littermates is single layered with no hyperplasia, and very few cells express Ki-67. Rat ventral prostate contains an estrogenic component, which comigrates on HPLC with the testosterone metabolite 5alpha-androstane-3beta,17beta-diol (3betaAdiol). This compound, which competes with E(2) for binding to ERbeta and elicits an estrogenic response in the aorta but not in the pituitary, decreases the AR content in prostates of wild-type mice but does not affect the elevated levels seen in ERbeta knockout (BERKO) mice. Thus ERbeta, probably as a complex with 3betaAdiol, is involved in regulating the AR content of the rodent prostate and in restraining epithelial growth. These findings suggest that ligands specific for ERbeta may be useful in the prevention and/or clinical management of prostatic hyperplasia and neoplasia.     

Estrogen receptors alpha and beta in the normal, hyperplastic and carcinomatous human prostate

Two different estrogen receptors (ER-alpha and ER-beta) have been described, which are differentially involved in regulating the normal function of reproductive tissues. ER-alpha was considered for a long time to be the only estrogen receptor, and it has been detected in the stromal cells of the human prostate but not in the epithelium. To obtain new information about the differential effects of both receptor types, we have investigated their localization in normal prostates, benign prostatic hyperplasia (BPH), and prostatic cancer (PC) by immunohistochemistry, ELISA and Western blot. Epithelial immunostaining was absent in normal prostates and was present in BPH (10% of cells) and PC (80% of cells), whereas about 15% of stromal cells were positively immunostained for ER-alpha in the three types of prostatic specimens studied. Epithelial immunostaining for ER-beta was detected in normal prostates (13% of cells), BPH (30% of cells) and PC (79% of cells), whereas stromal immunostaining for ER-beta was absent in normal and hyperplastic prostates and was present in PC (12% of cells). The complementary presence of both receptor types in the normal prostate (ER-beta in the epithelium and ER-alpha in the stroma) might explain the mechanism of estrogen action in the development of BPH. The increased epithelial immunostaining for both ER-alpha and ER-beta in BPH and PC suggests that the involvement of estrogen receptors in hyperplasia and cancer concerns mainly the epithelium.     

Aging of the prostate epithelial stem/progenitor cell

Maintenance of the prostatic epithelial cell compartment is ensured by proliferation of adult epithelial progenitor or stem cells. These cells are characterized by an undifferentiated state, high proliferative capacity and long life span. Prostate progenitor/stem cells are localized in their stem cell-niche in the basal cell compartment in close contact to the basement membrane and the stromal cell compartment and are characterized by expression of the basal cytokeratins 5 and 14, high levels of integrins, CD44, the stem cell markers CD133 and ABCG2, and AR negativity. They give rise to secretory luminal (cytokeratins 8/18, CD57, AR, p27, PSA, PAP) and neuroendocrine cells (cytokeratins 8/18, CD57, CgA, NSE, NEPs), the two major cell types observed in the glandular epithelium. A growing body of experimental evidence has identified the amplifying progenitor/stem cell (CD44(+), alpha(2)beta(1)(hi), CD133(+)), as a putative origin of prostate cancer. Differentiation of this cell type can be affected by mutations in the intrinsic genetic program, by age-related changes in stromal-epithelial interactions or in the basement membrane/ECM composition. All these stochastic events occur during aging and can transform a normal prostate progenitor/stem cell into a cancer stem cell, a source of androgen-dependent and independent tumor cell clones. Thus, the heterogeneous and multifocal nature of prostatic cancer with a pleora of different tumor cell clones clearly reflects the differentiation capacity of the prostatic epithelial progenitor cells.     

Neonatal estrogen exposure induces lobe-specific alterations in adult rat prostate androgen receptor expression.

Brief administration of estrogen to newborn rats results in permanent suppression of prostate growth and reduced prostatic responsiveness to testosterone in adulthood. To determine whether this imprinting may be a result of alterations in androgen receptor (AR) expression, the separate adult prostate lobes of neonatally estrogenized rats were examined for AR concentration and distribution. Sprague-Dawley rat pups were given 25 micrograms estradiol benzoate or oil alone on days 1, 3, and 5 and were killed on day 90. Half of the animals received 2-cm testosterone implants 10 days before death to assess the activational response to androgen. In a separate series, neonatally estrogenized rats were given prepubertal dihydrotestosterone pellets for 3 weeks as well as testosterone implants in adulthood to determine if the observed effects of neonatal estrogen on the adult prostate were an indirect result of androgen deprivation during developmentally critical periods. The ventral, dorsal, and lateral prostate lobes were processed for nuclear AR quantitation by [3H]dihydrotestosterone exchange binding assay and for indirect immunocytochemical localization of AR. Weights and DNA contents of the three prostate lobes were significantly reduced in neonatally estrogenized rats, and this decrease was only partially reversed by prepubertal and/or adult androgen replacement. Histologically, the hypoplastic ventral and dorsal lobes exhibited a relative increase in interacinar stromal tissue, disorganized acini with epithelial hyperplasia, luminal sloughing, and an apparent lack of differentiation. The hypoplastic lateral lobe also showed a relative increase in the stromal fraction; however, the acinar epithelium appeared differentiated, with normal basal/apical orientation and luminal secretions. The AR concentration was significantly reduced in the ventral and dorsal prostates of estrogenized rats, but was unaltered in the lateral lobe. Immunocytochemistry revealed a marked reduction or absence of epithelial AR in ventral and dorsal lobes from estrogenized rats, whereas the lateral lobe epithelial cells expressed AR similarly to controls. The incidence of AR-positive fibroblastic stromal cells increased in lateral prostates from 5% in controls to approximately 25% in estrogenized rats. Neonatally estrogenized rats given testosterone for 10 days in adulthood showed increased levels of AR in the ventral and dorsal lobes compared to nonstimulated rats; however, these levels remained well below control values. Lateral lobe epithelial histology and AR expression appeared relatively unchanged in estrogenized rats given testosterone during adulthood, whereas an increased proportion of stromal cells (approximately 35%) were AR positive. In summary, neonatal estrogen administration permanently altered prostatic growth and produced lobe-specific changes in AR expression in the adult gland.(ABSTRACT TRUNCATED AT 400 WORDS)     

Neonatal estrogen exposure induces lobe-specific alterations in adult rat prostate androgen receptor expression.

Brief administration of estrogen to newborn rats results in permanent suppression of prostate growth and reduced prostatic responsiveness to testosterone in adulthood. To determine whether this imprinting may be a result of alterations in androgen receptor (AR) expression, the separate adult prostate lobes of neonatally estrogenized rats were examined for AR concentration and distribution. Sprague-Dawley rat pups were given 25 micrograms estradiol benzoate or oil alone on days 1, 3, and 5 and were killed on day 90. Half of the animals received 2-cm testosterone implants 10 days before death to assess the activational response to androgen. In a separate series, neonatally estrogenized rats were given prepubertal dihydrotestosterone pellets for 3 weeks as well as testosterone implants in adulthood to determine if the observed effects of neonatal estrogen on the adult prostate were an indirect result of androgen deprivation during developmentally critical periods. The ventral, dorsal, and lateral prostate lobes were processed for nuclear AR quantitation by [3H]dihydrotestosterone exchange binding assay and for indirect immunocytochemical localization of AR. Weights and DNA contents of the three prostate lobes were significantly reduced in neonatally estrogenized rats, and this decrease was only partially reversed by prepubertal and/or adult androgen replacement. Histologically, the hypoplastic ventral and dorsal lobes exhibited a relative increase in interacinar stromal tissue, disorganized acini with epithelial hyperplasia, luminal sloughing, and an apparent lack of differentiation. The hypoplastic lateral lobe also showed a relative increase in the stromal fraction; however, the acinar epithelium appeared differentiated, with normal basal/apical orientation and luminal secretions. The AR concentration was significantly reduced in the ventral and dorsal prostates of estrogenized rats, but was unaltered in the lateral lobe. Immunocytochemistry revealed a marked reduction or absence of epithelial AR in ventral and dorsal lobes from estrogenized rats, whereas the lateral lobe epithelial cells expressed AR similarly to controls. The incidence of AR-positive fibroblastic stromal cells increased in lateral prostates from 5% in controls to approximately 25% in estrogenized rats. Neonatally estrogenized rats given testosterone for 10 days in adulthood showed increased levels of AR in the ventral and dorsal lobes compared to nonstimulated rats; however, these levels remained well below control values. Lateral lobe epithelial histology and AR expression appeared relatively unchanged in estrogenized rats given testosterone during adulthood, whereas an increased proportion of stromal cells (approximately 35%) were AR positive. In summary, neonatal estrogen administration permanently altered prostatic growth and produced lobe-specific changes in AR expression in the adult gland.(ABSTRACT TRUNCATED AT 400 WORDS)     

Hormone and growth factor signaling in endometrial renewal: Role of stem/progenitor cells

The human endometrium is a dynamic remodeling tissue undergoing more than 400 cycles of regeneration, differentiation and shedding during a woman's reproductive years. The co-ordinated and sequential actions of estrogen and progesterone direct these major remodeling events preparing a receptive endometrium for blastocyst implantation on a monthly basis. Adult stem/progenitor cells are likely responsible for endometrial regeneration. Functional approaches have been used to identify candidate endometrial stem/progenitor cells, as there are no specific stem cell markers. Rare populations of human endometrial epithelial and stromal colony-forming cells/units (CFU) and side population (SP) cells have been identified. Several growth factors are required for CFU activity: epidermal growth factor (EGF), transforming growth factor α (TGFα) and platelet-derived growth factor BB (PDGF-BB) for both epithelial and stromal CFU, and basic fibroblast growth factor (bFGF) for stromal, but not epithelial CFU. A sub-population of human endometrial stromal cells with mesenchymal stem cell properties of CFU activity and multilineage (fat, muscle, cartilage and bone) differentiation have been isolated by their co-expression of CD146 and PDGF-receptor β. Candidate epithelial and stromal stem/progenitor cells have been identified in mouse endometrium as rare label retaining cells (LRCs) in the luminal epithelium and as perivascular cells at the endometrial–myometrial junction, respectively. While epithelial and most stromal LRC do not express estrogen receptor α (Esr1), they rapidly proliferate on estrogen stimulation, most likely mediated by neighbouring Esr1-expressing niche cells. It is likely that these newly identified endometrial stem/progenitor cells may play key roles in the development of gynecological diseases associated with abnormal endometrial proliferation such as endometriosis and endometrial cancer.     

Suppressor role of androgen receptor in proliferation of prostate basal epithelial and progenitor cells

Early studies have reported the differential roles of androgen receptor (AR) in different types (luminal, basal intermediate, and stromal) of prostate cancer cells. In vivo mouse model tumor studies using the total prostate epithelial knockout mice (pes-ARKO) also revealed that AR played a suppressive role in proliferation of the CK5(+)/CK8(+) progenitor/intermediate cells but a positive role in the CK5(-)/CK8(+) luminal epithelial cells. Using three different resources (one human basal epithelial cell line, one mouse basal epithelial originated progenitor cell line, and a basal epithelium-specific ARKO mouse model), we here demonstrated that the AR in basal epithelial cells of normal prostate plays a suppressive role in their proliferation but a positive role in differentiation into luminal epithelial cells. These results led us to conclude that ARs may play a negative role to suppress CK5(+) basal epithelial and progenitor cell proliferation, yet play an essential role to drive basal epithelial cells into more differentiated states. These results may explain why differential AR expression in different cell types within normal prostate is needed and suggest that ARs in prostate basal epithelial cells, although expressed at a very low level, are necessary to maintain the balance between progenitor cells and differentiated luminal epithelial cells.     

Evidence that estrogens directly alter androgen-regulated prostate development

Neonatal exposure to high doses of estrogen results in permanent suppression of prostate growth and reduced sensitivity to androgens in adulthood. It is unclear whether alterations in prostate growth are due to a direct effect of estrogens on the gland or are the result of hypothalamic-pituitary-gonadal axis suppression and a subsequent reduction in androgen levels. Therefore, the aim of this study was to determine whether estrogens have a direct effect on the prostate using a defined method of culturing neonatal prostates. Newborn rat ventral prostates were microdissected and cultured in the presence of testosterone, which resulted in branching morphogenesis and ductal canalization. Solid cords of epithelium differentiated into acini lined by tall columnar epithelial cells; these acini were surrounded by stromal cells, expressing smooth muscle alpha-actin. When cultured in the presence of 17beta-estradiol or diethylstilbestrol in addition to testosterone, androgen-induced prostatic growth was reduced, and differentiation was altered. Although estrogen-treated explants were smaller than controls, quantification of epithelial, stromal, and luminal volumes using unbiased stereology revealed significant changes; the proportion of epithelial cells and lumen decreased, and the proportion of stroma increased compared with control values. Concurrent with this reduced growth rate, we observed a disturbance in the branching pattern and a reduction in ductal canalization. Specifically, stromal differentiation and organization were disrupted, so that a discontinuous smooth muscle layer was observed around the epithelial ducts, and epithelial differentiation was altered. The effects of estrogens were not accompanied by a decrease in androgen response via the androgen receptor, because immunolocalization of this receptor remained constant. These data demonstrate that high doses of estrogens are growth inhibitory and have direct effects on prostate development in vitro, which may occur in vivo in addition to indirect effects via suppression of the hypothalamic-pituitary-gonadal axis.     

Trop2 identifies a subpopulation of murine and human prostate basal cells with stem cell characteristics

The epithelium of the adult prostate contains 3 distinct cell types: basal, luminal, and neuroendocrine. Tissue-regenerative activity has been identified predominantly from the basal cells, isolated by expression of CD49f and stem cell antigen-1 (Sca-1). An important question for the field is whether all basal cells have stem cell characteristics. Prostate-specific microarray databases were interrogated to find candidate surface antigens that could subfractionate the basal cell population. Tumor-associated calcium signal transducer 2 (TACSTD2/Trop2/M1S1/GA733-1) was identified because it was enriched after castration, in prostate sphere cells and in the basal fraction. In the murine prostate, Trop2 shows progenitor characteristics such as localization to the region of the gland proximal to the urethra and enrichment for sphere-forming and colony-forming cells. Trop2 subfractionates the basal cells into 2 populations, both of which express characteristic basal cell markers by quantitative PCR. However, only the basal cells expressing high levels of Trop2 were able to efficiently form spheres in vitro. In the human prostate, where Sca-1 is not expressed, sphere-forming progenitor cells were also isolated based on high expression of Trop2 and CD49f. Trop2-expressing murine basal cells could regenerate prostatic tubules in vivo, whereas the remaining basal cells had minimal activity. Evidence was found for basal, luminal, and neuroendocrine cells in prostatic tubules regenerated from Trop2^hi basal cells. In summary, functionally distinct populations of cells exist within the prostate basal compartment and an epithelial progenitor can give rise to neuroendocrine cells in vivo.     

Androgen receptor signalling in prostate: effects of stromal factors on normal and cancer stem cells

The prostate gland is the most common site for cancer in males within the developed world. Androgens play a vital role in prostate development, maintenance of tissue function and pathogenesis of prostate disease. The androgen receptor signalling pathway facilitates that role in both the epithelial compartment and in the underlying stroma. Stroma is a key mediator of androgenic effects upon the epithelium and can regulate both the fate of the epithelial stem cell and potentially the initiation and progression of prostate cancer. Different groups of growth factors are expressed by stroma, which control proliferation, and differentiation of prostate epithelium demonstrating a critical role for stroma in epithelial growth and homeostasis. Paracrine stromal proteins may offer the possibility to control tumour stem cell growth and could permit prostate specific targeting of both therapies and of androgen responsive proteins. The effect of 5alpha-dihydrotestosterone, the more potent metabolite of testosterone, on expression of androgen-regulated genes in stroma from benign prostatic hyperplasia is a key mediator of epithelial cell fate. Global gene expression arrays have recently identified new candidate genes in androgen responsive stroma, some of which have androgen receptor binding sites in their promoter regions. Some of these genes have direct androgen receptor binding ability.     

BRCA1 regulates human mammary stem/progenitor cell fate

Although it is well established that women with germ-line mutations in the BRCA1 gene have a greatly increased lifetime incidence of breast and ovarian cancer, the molecular mechanisms responsible for this tissue-specific carcinogenesis remain undefined. The majority of these breast cancers are of the basal-like phenotype characterized by lack of expression of ER, PR, and ERBB2. Because this phenotype has been proposed to resemble that of normal breast stem cells, we examined the role of BRCA1 in human mammary stem cell fate. Using both in vitro systems and a humanized NOD/SCID mouse model, we demonstrate that BRCA1 expression is required for the differentiation of ER-negative stem/progenitor cells to ER-positive luminal cells. Knockdown of BRCA1 in primary breast epithelial cells leads to an increase in cells displaying the stem/progenitor cell marker ALDH1 and a decrease in cells expressing luminal epithelial markers and estrogen receptor. In breast tissues from women with germ-line BRCA1 mutations, but not normal controls, we detect entire lobules that, although histologically normal, are positive for ALDH1 expression but are negative for the expression of ER. Loss of heterozygosity for BRCA1 was documented in these ALDH1-positive lobules but not in adjacent ALDH1-negative lobules. Taken together, these studies demonstrate that BRCA1 plays a critical role in the differentiation of ER-negative stem/progenitor cells to ER-positive luminal cells. Because BRCA1 also plays a role in DNA repair, our work suggests that loss of BRCA1 may result in the accumulation of genetically unstable breast stem cells, providing prime targets for further carcinogenic events.     

Local aromatase expression in human prostate is altered in malignancy

Tissue-specific aromatase production is significant in breast cancer and osteoporosis. Prostatic aromatase expression has been equivocal, and any local actions of estrogens are considered secondary to centrally mediated androgen suppression. We examine local aromatase expression and estrogen biosynthesis in the human prostate. Pure samples of stroma and epithelia from biopsy tissues were isolated by laser capture microdissection. Aromatase protein was detected by Western blot analysis, mRNA by RT-PCR, and enzyme activity by tritiated water assay, whereas promoter use was examined by real-time PCR. In nonmalignant prostate tissues, aromatase mRNA expression was absent from epithelium, but did localize to stroma. Presence of protein was confirmed, and expression was driven by promoter PII. Aromatase was expressed and active in LNCaP, PC3, and DU145 cells in addition to microdissected epithelial tumor cells; benign prostate epithelial cells showed no expression or activity. Promoter use in LNCaP and microdissected tumor cells was via PII, whereas PC3 and DU145 cells used promoter I.4. This study demonstrates local estrogen biosynthesis in prostate-induced aromatase gene expression in malignancy and potential alteration of aromatase promoter use with disease progression. These data provide a basis for continued investigation of local estrogen production and its potential role in prostate disease.     

Endometrial regeneration and endometrial stem/progenitor cells

The functional layer of the human endometrium is a highly regenerative tissue undergoing monthly cycles of growth, differentiation and shedding during a woman??s reproductive years. Fluctuating levels of circulating estrogen and progesterone orchestrate this dramatic remodeling of human endometrium. The thin inactive endometrium of postmenopausal women which resembles the permanent basal layer of cycling endometrium retains the capacity to respond to exogenous sex steroid hormones to regenerate into a thick functional endometrium capable of supporting pregnancy. Endometrial regeneration also follows parturition and endometrial resection. In non menstruating rodents, endometrial epithelium undergoes rounds of proliferation and apoptosis during estrus cycles. The recent identification of adult stem cells in both human and mouse endometrium suggests that epithelial progenitor cells and the mesenchymal stem/stromal cells have key roles in the cyclical regeneration of endometrial epithelium and stroma. This review will summarize the evidence for endometrial stem/progenitor cells, examine their role in mouse models of endometrial epithelial repair and estrogen-induced endometrial regeneration, and also describe the generation of endometrial-like epithelium from human embryonic stem cells. With markers now available for identifying endometrial mesenchymal stem/stromal cells, their possible role in gynecological diseases associated with abnormal endometrial proliferation and their potential application in cell-based therapies to regenerate reproductive and other tissues will be discussed.     

Estrogen receptor beta expression in human prostate tissue

Estrogen receptor subtype beta (ERbeta) is highly expressed in rat prostate epithelium, but its presence in human prostate needs to be confirmed. Here we investigated the expression of ERbeta in five benign (normal and/or hyperplastic) and 10 malignant (Gleasons' score 2-7) prostate tissue specimens using immunohistochemistry. Immunohistochemistry was performed on formalin-fixed, paraffin-embedded tissue sections, using a commercially available ERbeta polyclonal antibody developed against the C-terminal amino acid residue. Nuclear ERbeta expression was found in the nuclei of glandular epithelium of benign prostate tissue specimens; faint nuclear ERbeta positivity was also present in a few stromal cells around normal epithelium. Nuclear ERbeta specific immunostaining was undetectable in all prostate cancer sections.     

The metaplastic effects of estrogen on mouse prostate epithelium: proliferation of cells with basal cell phenotype

The exogenous administration of estrogens to male mice alters the hypothalamic-pituitary-gonadal axis and reduces androgen levels, leading to a regression of the prostatic epithelium. As well, a specific direct response to estrogens is the induction of epithelial squamous metaplasia. The aims of this study were to identify the process by which the prostatic epithelium is transformed in intact adult male mice using the synthetic estrogen, diethylstilbestrol. A comparison of the effects of diethylstilbestrol in the three lobes revealed a hierarchy of response, with the anterior lobe being the most responsive, the dorsolateral lobe less responsive, and the ventral lobe the least responsive. The effect of castration was used to distinguish between the epithelial responses to estrogen administration and androgen deprivation. The results demonstrate that transformation of the epithelium involved proliferation of cells with a basal cell phenotype, the onset of cytokeratin 10 expression, up-regulation of progesterone receptor expression, and loss of the cell cycle inhibitor, p27(Kip1) expression; none of these changes was observed after castration. Mice lacking functional estrogen receptor alpha failed to respond, demonstrating a requirement for estrogen receptor alpha in the epithelium and/or stroma to mediate the proliferative response to estrogen in the prostate gland.     

Androgen induces differentiation of a human papillomavirus 16 E6/E7 immortalized prostate epithelial cell line.

Androgen signaling is crucial for the growth and development, as well as for tumorigenesis of the prostate. However, many of the prostate epithelial cell lines developed previously, either normal or tumorigenic, do not express androgen receptor (AR) or respond to androgen. In order to advance our understanding on how androgen signaling regulates the growth and the differentiation status, and affects tumorigenicity of the epithelial cell, we performed experiments on HPr-1, a prostate cell line recently immortalized from normal human prostate epithelial cells. In the present study, AR was stably transfected into HPr-1 cells by replication-defective retrovirus. Treatment of HPr-1AR cells with androgen resulted in cell differentiation and growth retardation accompanied with up-regulation of cytokeratins K8 and K18, prostate specific antigen, p21 and p27, and down-regulation of c-myc, bcl-2 and telomerase activity. Our results suggest that androgen promotes the process of differentiation in a human papillomavirus 16 E6/E7 immortalized prostate epithelial cell line which may reflect the normal effects of androgen on prostate cells.