Long-term label retaining cells localize to distinct regions within the female reproductive epithelium

The uterus is an extremely plastic organ that undergoes cyclical remodeling including endometrial regeneration during the menstrual cycle. Endometrial remodeling and regeneration also occur during pregnancy and following parturition, particularly in hemochorial implanting species. The mechanisms of endometrial regeneration are not well understood. Endometrial stem/progenitor cells are proposed to contribute to endometrial regeneration in both humans and mice. BrdU label retention has been used to identify potential stem/progenitor cells in mouse endometrium. However, methods are not available to isolate BrdU label-retaining cells (LRC) for functional analyses. Therefore, we employed a transgenic mouse model to identify H2B-GFP LRCs throughout the female reproductive tract with particular interest on the endometrium. We hypothesized that the female reproductive tract contains a population of long-term LRCs that persist even following pregnancy and endometrial regeneration. Endometrial cells were labeled (pulsed) either transplacentally/translactationally or peripubertally. When mice were pulsed transplacentally/translactationally, the label was not retained in the uterus. However, LRCs were concentrated to the distal oviduct and endocervical transition zone (TZ) following natural (i.e., pregnancy/parturition induced) and mechanically induced endometrial regeneration. LRCs in the distal oviduct and endocervical TZ expressed stem cell markers and did not express ERα or PGR, implying the undifferentiated phenotype of these cells. Oviduct and endocervical TZ LRCs did not proliferate during endometrial re-epithelialization, suggesting that they do not contribute to the endometrium in a stem/progenitor cell capacity. In contrast, when mice were pulsed peripubertally long-term LRCs were identified in the endometrial glandular compartment in mice as far out as 9 months post-pulse. These findings suggest that epithelial tissue of the female reproductive tract contains 3 distinct populations of epithelial cells that exhibit stem/progenitor cell qualities. Distinct stem/progenitor-like cells localize to the oviduct, endometrium, and cervix.     

Clonogenicity of human endometrial epithelial and stromal cells

The human endometrium regenerates from the lower basalis layer, a germinal compartment that persists after menstruation to give rise to the new upper functionalis layer. Because adult stem cells are present in tissues that undergo regeneration, we hypothesized that human endometrium contains small populations of epithelial and stromal stem cells responsible for cyclical regeneration of endometrial glands and stroma and that these cells would exhibit clonogenicity, a stem-cell property. The aims of this study were to determine 1) the clonogenic activity of human endometrial epithelial and stromal cells, 2) which growth factors support this clonogenic activity, and 3) determine the cellular phenotypes of the clones. Endometrial tissue was obtained from women undergoing hysterectomy. Purified single- cell suspensions of epithelial and stromal cells were cultured at cloning density (300-500/cm(2)) in serum medium or in serum- free medium supplemented with one of eight growth factors. Small numbers of epithelial (0.22%) and stromal cells (1.25%) initiated colonies in serum-containing medium. The majority of colonies were small, containing large, loosely arranged cells, and 37% of epithelial and 1 in 60 of stromal colonies were classified as large, comprising small, densely packed cells. In serum-free medium, transforming growth factor-alpha (TGF alpha), epidermal growth factor (EGF), platelet-derived growth factor-BB (PDGF-BB) strongly supported clonogenicity of epithelial cells, while leukemia-inhibitory factor (LIF), hepatocyte growth factor (HGF), stem-cell factor (SCF), insulin-like growth factor-I (IGF- I) were weakly supportive, and basic fibroblast growth factor (bFGF) was without effect. TGF alpha, EGF, PDGF-BB, and bFGF supported stromal cell clonogenicity, while HGF, SCF, LIF, and IGF- I were without effect. Small epithelial colonies expressed three epithelial markers but not stromal markers; however, large epithelial colonies showed little reactivity for all markers except alpha(6)-integrin. All stromal colonies contained fibroblasts, expressing stromal markers, and in some colonies, myofibroblasts were also identified. This analysis of human endometrium has demonstrated the presence of rare clonogenic epithelial and stromal cells with high proliferative potential, providing the first evidence for the existence of putative endometrial epithelial and stromal stem cells.     

Involution and regeneration of the endometrium following parturition in the ewe

Involution and regeneration of the endometrium after parturition in the ewe, were studied by light- and electron microscopy. The luminal epithelium in intercaruncular regions of the endometrium remained intact at all stages, but degeneration and death of many glandular epithelial cells were observed on the day after parturition. Glandular regeneration had commenced by 8 d post partum, and the glands were substantially regenerated by 15 d. Caruncular epithelial cells on the maternal side of the placentomes, between the bases of the maternal septa, persisted during the period of degeneration of the foetal and maternal tissues of the placentomes. Epithelial cells from this source contributed to the regeneration of the caruncular epithelium following shedding of plaques of degenerate placental tissue from the caruncles, which commenced after 8 d and was completed before 31 d. Thus, ingrowth of epithelium from the edges of the caruncles, as previously proposed, was not the sole source of new caruncular epithelium. The additional source of regenerating epithelium identified here may account for the rapidity with which epithelium appears in the centres of some caruncles, several millimetres in diameter, during endometrial regeneration. However, in some caruncles, regeneration of the epithelium was not completed until after 31 d post partum.     

Human Endometrial Side Population Cells Exhibit Genotypic,Phenotypic and Functional Features of Somatic Stem Cells

During reproductive life, the human endometrium undergoes around 480 cycles of growth, breakdown and regeneration should pregnancy not be achieved. This outstanding regenerative capacity is the basis for women''s cycling and its dysfunction may be involved in the etiology of pathological disorders. Therefore, the human endometrial tissue must rely on a remarkable endometrial somatic stem cells (SSC) population. Here we explore the hypothesis that human endometrial side population (SP) cells correspond to somatic stem cells. We isolated, identified and characterized the SP corresponding to the stromal and epithelial compartments using endometrial SP genes signature, immunophenotyping and characteristic telomerase pattern. We analyzed the clonogenic activity of SP cells under hypoxic conditions and the differentiation capacity in vitro to adipogenic and osteogenic lineages. Finally, we demonstrated the functional capability of endometrial SP to develop human endometrium after subcutaneous injection in NOD-SCID mice. Briefly, SP cells of human endometrium from epithelial and stromal compartments display genotypic, phenotypic and functional features of SSC.     

CA 125 is an excretory product of human endometrial glands

The present investigation was undertaken to study the cellular localization and kinetics of synthesis of CA 125 in the endometrium. CA 125 was localized by immunohistochemistry to the infranuclear region of epithelial cells during the proliferative phase and to the apical luminal border during the secretory phase. In gestational endometrium, both the cytoplasm and the apical luminal border of epithelial cells were intensely positive. No staining was seen in endometrial stromal cells during the normal cycle or in decidualized endometria. Results obtained from in vitro cultures of separated glandular and stromal cells were similar to those obtained by immunohistochemistry. That is, epithelial cells released between 5 and 25 times more CA 125 into the culture medium than did stromal cells. The release of CA 125 was highest in epithelial and stromal cells obtained during the early secretory phase. CA 125 concentrations were markedly elevated in endometrial aspirations obtained during the secretory phase or in endometria with crumbling stroma compared to plasma levels. Plasma levels of CA 125 were slightly elevated during menses. These results suggest that CA 125 is an exocrine product of endometrial epithelial cells. Plasma levels of CA 125 may be of endometrial origin only when the membrane barriers, which normally prevent its entry into the circulation, are damaged.     

Regulation of gene expression and cellular localization of prostaglandin synthase by oestrogen and progesterone in the ovine uterus

Expression of the gene for prostaglandin synthase (PGS) was examined in whole endometrial tissue derived from ewes during the oestrous cycle (Days 4-14), on Day 15 of pregnancy and following ovariectomy and treatment with ovarian steroid hormones. Whilst no significant differences were seen in PGS mRNA concentrations analysed by Northern blot analysis in endometrial tissue during the oestrous cycle or in early pregnancy, treatment of ovariectomized (OVX) ewes with oestradiol-17 beta markedly reduced endometrial PGS mRNA concentration. There was no difference in PGS mRNA concentration in ewes treated with progesterone, either alone or in conjunction with oestrogen, from that in OVX controls. In contrast, differences in immunolocalization of PGS observed in uterine tissue from OVX-steroid-treated ewes were much more marked and reflected similar changes seen previously in the immunocytochemical distribution of endometrial PGS during the oestrous cycle. In OVX ewes and those treated with oestrogen, immunocytochemical staining for PGS was seen in stromal cells, but little immunoreactive PGS was located in the endometrial epithelial cells. However, in ewes treated with progesterone alone or with oestrogen plus progesterone, PGS was found in luminal and glandular epithelial cells and in stromal cells. Intensity of immunostaining for PGS in endothelial cells and myometrium did not differ between the treatments. Thus, whilst oestrogen lowers PGS mRNA in the endometrium, presumably in stroma, it may also increase the stability of the enzyme itself in the stromal cells. Although oestradiol-17 beta has no effect on PGS in endometrial epithelium, progesterone stimulates the production of PGS in endometrial epithelial cells without altering the overall abundance of PGS mRNA in the endometrium as a whole. Conceptus-induced changes in PGF-2 alpha release by ovine endometrium would not appear to be mediated via effects on PGS gene expression or protein synthesis.     

Expression of metalloproteinases and their inhibitors in blood vessels in human endometrium.

Matrix metalloproteinases (MMPs) are zinc-requiring enzymes that can degrade components of the extracellular matrix and that are implicated in tissue remodeling. Their role in the onset of menstruation in vivo has been proven; however, the expression and functions of MMPs and tissue inhibitors of metalloproteinases (TIMPs) in vascular structures are poorly understood. We determined by immunocytochemistry, using characterized monoclonal antibodies, the distribution of MMPs and of their inhibitors TIMP-1 and TIMP-2 in the endometrium during the menstrual cycle. MMP-1, MMP-2, MMP-3, MMP-9, TIMP-1, and TIMP-2 had differing distributions and patterns of expression. In addition to the localization of MMP-9 in the epithelium and of MMP-2, MMP-3, and MMP-1 in the stromal tissue, these MMPs were detected in the vascular structures. MMP-2 (72-kDa gelatinase) and tissue inhibitors TIMP-1 and TIMP-2 were detectable in vessels throughout the cycle. In contrast, MMP-3 (stromelysin-1) was detected only in late-secretory and menstrual endometrial vessels, while MMP-9 (92-kDa gelatinase) was detected in spiral arteries during the secretory phase and in vascular structures during the midfollicular and menstrual phases. The expression of MMP-2 and MMP-9 in endometrial vessels during the proliferative and secretory periods suggests their relationship to vascular growth and angiogenesis. The pronounced expression of MMP-3 (stromelysin-1) in the vessels situated in the superficial endometrial layer during menses suggests that this metalloproteinase initiates damage in the vascular wall during menstrual breakdown. The finding of an intense expression of TIMP-1 and TIMP-2 in the vessels delineating necrotic from non-necrotic areas during menses also suggests that they could limit tissue damage, allowing regeneration of the endometrium after menses. These data indicate that, in addition to expression in epithelial cells and stromal tissue, MMPs are expressed in endometrial vascular cells in a cycle-specific pattern, consistent with regulation by steroid hormones and with specific roles in the vascular remodeling processes occurring in the endometrium during the cycle.     

Paracrine regulation of endometrial function: interaction between progesterone and corticotropin-releasing factor (CRF) and activin A

Under the influence of ovarian steroid hormones, endometrial cells aer able to produce a wide variety of growth factors and peptide hormones that area believed to promote: (1) physiological growth and differentiation during the endometrial cycle; (2) decidualization, an essential preparative event for establishment of pregnancy; and (3) pathological growth and differentiation in endometriosis and cancer. Among the local factors produced by the human endometrium, corticotropin-releasing factor (CRF) and activin A have been evaluated in terms of localization and effects. CRF is a neuropeptide expressed by the epithelial and stromal cells of the human endometrium in increasing amounts from the endometrial proliferative to the secretory phase. CRF expression also increases in the pregnant endometrium, from early in the pregnancy until term. CRF-type 1 receptor mRNA is only expressed by stromal cells. Progesterone induces CRF gene expression and release from decidualized cells and CRF decidualizes cultured stromal endometrial cells. Urocortin, a CRF-related peptide, has been identified in endometrial epithelial and stromal cells, and its function is still under investigation. Activin A is a growth factor expressed in increasing amounts throughout endometrial phases by both epithelial and stromal cells. This growth factor is secreted into the uterine cavity with higher levels in the secretory phase. Maternal decidua expresses activin A mRNA in increasing amounts from early pregnancy until term. Human endometrium also expresses activin-A receptors and follistatin, its binding protein. Activin A decidualizes cultured human endometrial stromal cells (an effect reversed by follistatin) and modulates embryonic trophoblast differentiation and adhesion. Activin A is expressed in endometriosis and endometrial adenocarcinoma.     

Two pathways of progesterone action in the human endometrium: implications for implantation and contraception

The endometrium is the site of implantation and pregnancy. Preparation for this important biological event relies primarily on progesterone, which takes the estrogen-primed endometrium toward a state of receptivity. As a steroid target tissue, the endometrium is also prone to abnormal growth sometimes leading to the development of hyperplasia or cancer. It is the balance between estrogen and progesterone that maintains the endometrium in a state of health and provides the synchronous timing necessary for a successful implantation to occur. In our efforts to understand the role of progesterone in the endometrium we have focused on the use of specific protein biomarkers. Based on examination of a cell adhesion molecule, the alphavbeta3 integrin, and its ligand, osteopontin, we have come to conclude that progesterone action can be direct or indirect. Progesterone acting on the stromal compartment provides paracrine mediators that influence epithelial gene expression. Conversely, acting directly, progesterone may primarily stimulate gene expression of the endometrial epithelium. The complexity of the system is extended since progesterone itself works through two different receptor isoforms. Regulated differential expression of PR-A versus PR-B also appears to fine tune the effect of progesterone on specific genes. Progesterone may also inhibit specific genes that undergo cyclic variation during the menstrual cycle. Together, using in vitro models we have shown that progesterone dynamically regulates gene expression in the endometrium and that imbalances between estrogen and progesterone may have far reaching consequences on normal cycle fecundity and on the balance between health and disease in this hormone-target tissue.     

Expression of the chemokine eotaxin and its receptor, CCR3, in human endometrium

Eosinophils are present in human endometrium only immediately before and during menstruation, suggesting a role in that process. The expression of the eosinophil chemoattractant, eotaxin, and its receptor, CCR3, within the human endometrium were investigated by immunohistochemical analysis of tissue sections spanning the entire menstrual cycle. Eotaxin was localized to perivascular cells in the late secretory phase, and it was also identified in eosinophils. However, the highest levels of this chemokine were present in both luminal and glandular epithelial cells during the proliferative and secretory phases of the cycle. Treatment of endometrial tissue with monensin, which blocks protein secretion, increased epithelial immunoreactive eotaxin, substantiating synthesis in these cells. Although the CCR3 receptor was expressed by eosinophils, it was also strongly expressed by endometrial epithelial cells. The CCR3 receptor on purified, cultured endometrial epithelial cells was functional, as assessed by a transient Ca(2+) flux in response to eotaxin. These analyses demonstrate that eotaxin is expressed by endometrial cells and may therefore be involved in the recruitment of eosinophils into this tissue premenstrually. However, the observation that this chemokine and the CCR3 molecule are strongly expressed by epithelial cells throughout the cycle suggests that these proteins may have additional important functions within the endometrium.     

Immunohistochemical assessment of prostaglandin H-synthase in bovine endometrial biopsy samples collected throughout the oestrous cycle

The study was designed to determine the distribution of prostaglandin H-synthase (PGS) also known as cyclooxygenase in specific uterine cell populations during the oestrous cycle. Endometrial biopsy samples were obtained from a total of 10 clinically healthy cows at days 1 (initiation of behavioural oestrus), 8, 15, and 19 of the oestrous cycle. All animals conceived after biopsy regimen. Data of semiquantitatively scored immunoreactivities were analysed using analyses of variance, t-tests for paired data and correlation analyses. Biotin-streptavidin-peroxidase immunostaining technique was employed to localise PGS. Specific staining was consistently present in endothelial cells of arteries but not capillaries and venules. A gradient of staining intensity was clearly apparent within the endometrium: surface epithelial cells and stromal cells located near the endometrial surface are consistently stained more intensely than glandular epithelial cells and stromal cells lying deeper in the endometrium. Days of oestrous cycle also influenced PGS immunoreactivities. Generally, higher immunoreactivities were recorded in surface epithelium, uterine glands and endometrial stromal cells at cycle days 1 and 19 as compared to cycle days 8 and 15. Minimal scoring values were mainly found at cycle day 8. The results of the present study suggest that the amount of bovine endometrial PGS varies considerably with the day of cycle in the above mentioned cell-type- and location-restricted manner. Therefore, the capacity of the bovine uterine mucosa for prostaglandin production may—amongst other factors—depend on the cycle-restricted availability of the respective enzyme systems.     

Cellular turnover in the rat uterine cervix and its relationship to estrogen and progesterone receptor dynamics

Histoarchitectural changes of the uterine cervix allow its successful adaptation to different physiological conditions. In this study, we evaluated cell turnover in each cellular compartment of the uterine cervix in association with steroid hormone receptor expression in order to establish the range of physiological changes. Proliferation, apoptosis, and progesterone receptor (PR) and estrogen receptor alpha (ERalpha) expression were evaluated in cycling, pregnant, and postpartum rats. In estrus and diestrus II, ERalpha and PR expression exhibited variations according to the region evaluated. Proliferation and apoptosis showed a reciprocal pattern, the epithelium being the region with higher cell turnover. High apoptotic index (AI) in estrus was associated with the lowest ERalpha and the highest PR scores. During pregnancy, proliferation of the epithelium was the predominant event and AI was low. On Postpartum Day 1 (PPD1), proliferation decreased while apoptosis increased. As described for the estrous cycle, during pregnancy and PPD1, AI and ERalpha were negatively correlated. In the fibroblastic stroma, low proliferation was observed throughout pregnancy; however, there was a net increase in cell number because very few cells underwent apoptosis. No difference in ERalpha was observed in fibroblastic cells during pregnancy and postpartum; however, a great decrease of this receptor in the epithelial compartment was observed after delivery. Unlike cervical epithelium, PR was highly expressed in stromal cells. At term, a dramatic increase in epithelial PR was observed. While epithelial PR remained high on PPD1, a decrease was observed in muscle stroma. These results show that, in all stages studied, 1) ERalpha and PR have different patterns of expression with differential responses to signals that modulate proliferation and/or apoptosis depending on the cellular compartment, and 2) even though the epithelium is the region with the highest cell turnover, the fibroblastic and muscle stroma are active regions that have their own patterns of behavior.     

蛋白激酶H11基因在小鼠子宫中的表达及其性激素调节

为研究蛋白激酶H11基因在生殖系统中的作用,我们采用半定量RT-PCR和原位杂交方法,研究了蛋白激酶H11基因在小鼠中的组织特异性表达,在妊娠初始期胚胎植入位点、妊娠期子宫和胎盘以及正常动情周期子宫中的表达及其受性激素的调节。结果发现:蛋白激酶H11基因在小鼠多种组织中都有表达,在卵巢及子宫等一些生殖相关的组织中表达水平较高;妊娠初始期,蛋白激酶H11基因在小鼠子宫内膜植入位点处有明显的高表达,其mRNA定位于腔上皮细胞和基质细胞中。在动情周期中,蛋白激酶H11基因在动情前期子宫中表达水平较低;卵巢切除模型显示雌激素和孕激素均可显著上调蛋白激酶H11基因的表达。以上结果提示蛋白激酶H11可能参与了胚胎植入过程中腔上皮细胞凋亡和基质细胞增殖与蜕膜化以及动情周期小鼠子宫内膜细胞的功能调节[动物学报51(3):462-468,2005]。     

The effects of Arcanobacterium pyogenes on endometrial function in vitro, and on uterine and ovarian function in vivo

Uterine bacterial infection after parturition causes endometritis, perturbs ovarian function and leads to infertility in cattle. Although endometritis is caused by mixed infections, endometrial pathology is associated with the presence of Arcanobacterium pyogenes. The aims of the present study were to determine the effects of A. pyogenes on endometrial function in vitro, and on uterine and ovarian function in vivo. Heat-killed A. pyogenes did not affect the production of prostaglandin F2alpha (PGF) or prostaglandin E(2) (PGE) from endometrial explants, or purified populations of endometrial epithelial or stromal cells. However, the explants produced more PGF and PGE than controls when treated with a bacteria-free filtrate (BFF) cultured from A. pyogenes. Similarly, BFF stimulated PGF and PGE production by epithelial and stromal cells, respectively. So, BFF or control PBS was infused into the uterus of heifers (n=7 per group) for 8 days, starting the day after estrus. Emergence of the follicle wave, dominant follicle or corpus luteum diameter, and peripheral plasma FSH, LH, estradiol, progesterone, PGFM, or acute phase protein concentrations were unaffected by the BFF infusion. In the live animal it is likely that the intact uterine mucosa limits the exposure of the endometrial cells to the exotoxin of A. pyogenes, whereas the cells are readily exposed to the toxin in vitro.     

Expression and action of hepatocyte growth factor in bovine endometrial stromal and epithelial cells in vitro.

Hepatocyte growth factor (HGF) is a pleiotropic growth factor that acts on various epithelial cells. The objectives of this study were to determine whether HGF altered the proliferation and prostaglandin (PG) secretion of bovine endometrial stromal and epithelial cells in vitro. We also observed HGF and HGF receptor (c-met) mRNA expression in cultured bovine endometrial stromal and epithelial cells by RT-PCR. Stromal and epithelial cells obtained from cows in early stage of the estrous cycle (days 2-5) were cultured in DMEM/Ham's F-12 supplemented with 10% calf serum. The cells were exposed to HGF (0-10 ng/ml) for 2, 4, or 6 days. HGF significantly increased the total DNA in epithelial (P < 0.05), but not stromal cells. In another experiment, when the cells reached confluence, the culture medium was replaced with fresh medium with 0.1% BSA containing HGF 0-100 ng/ml and the cells were cultured for 24 hr. The HGF stimulated PGF2alpha secretion in epithelial, but not stromal cells. RT-PCR revealed that mRNA of HGF is expressed only in stromal cells, and that c-met mRNA is expressed in both stromal and epithelial cells. These results suggest that HGF plays roles in the proliferation and the regulation of secretory function of bovine endometrial epithelial cells in a paracrine fashion.     

Fibroblastic growth factor receptor (FGF-R) expression during uterine involution in goat.

To investigate the possible participation of fibroblastic growth factors (FGFs) in endometrial involution, 20 multiparous goats, slaughtered on days 0, 1, 4, 10, 16 and 22 postpartum (pp), were used. Samples of different parts of the previous pregnant horns were taken and processed using streptoavidin-biotin-peroxidase complex method to analyse FGF receptor (FGF-R) expression. The percentage of positive cells in luminal epithelium, superficial and deep glands and stroma was evaluated. Epithelial, glandular and stromal cells exhibited FGF-R immunoreactivity. No differences between caruncular and inter-caruncular epithelium were observed and staining was most evident in the superficial glands. The greatest degree of FGF-R expression was seen on days 10 and 16 pp, coinciding with epithelial and stromal cellular regeneration. These results suggest that caprine uterine involution is associated with variations in the expression of FGF-R.