Sex hormone regulation of anti-bacterial activity in rat uterine secretions and apical release of anti-bacterial factor(s) by uterine epithelial cells in culture

In mature female rats, sex hormones regulate the reproductive (estrous) cycle to optimize mating and fertility. During the part of the estrous cycle when mating occurs, and when estrogen is the dominant sex hormone, the uterus is susceptible to infection with bacteria that can be deleterious for survival and fertility. The present study investigated whether sex hormones regulate innate immunity in the female reproductive tract by affecting the secretion of an anti-bacterial factor(s) in the rat uterus. Uterine fluids from intact rats at the proestrous stage of the estrous cycle significantly inhibited Staphylococcus aureus growth. When ovariectomized rats were treated with estradiol, anti-bacterial activity against both S. aureus and Escherichia coli increased in uterine secretions with hormone treatment. In contrast, rats injected with either progesterone and estradiol or progesterone alone displayed no bactericidal activity indicating that progesterone reversed the stimulatory effect of estradiol on anti-bacterial activity. In other studies, isolated uterine epithelial cells from intact animals were grown to confluence and high transepithelial resistance on cell inserts. Analysis of apical secretions indicated that a soluble factor(s) is released by polarized epithelial cells which inhibits bacterial growth. These results demonstrate that sex hormones influence the presence of a broad-spectrum bactericidal factor(s) in luminal secretions of the rat uterus. Further these studies suggest that epithelial cells which line the uterine lumen are a primary source of anti-bacterial activity.     

Estrogen in the adult male reproductive tract: A review

Testosterone and estrogen are no longer considered male only and female only hormones. Both hormones are important in both sexes. It was known as early as the 1930's that developmental exposure to a high dose of estrogen causes malformation of the male reproductive tract, but the early formative years of reproductive biology as a discipline did not recognize the importance of estrogen in regulating the normal function of the adult male reproductive tract. In the adult testis, estrogen is synthesized by Leydig cells and the germ cells, producing a relatively high concentration in rete testis fluid. Estrogen receptors are present in the testis, efferent ductules and epididymis of most species. However, estrogen receptor-α is reported absent in the testis of a few species, including man. Estrogen receptors are abundant in the efferent ductule epithelium, where their primary function is to regulate the expression of proteins involved in fluid reabsorption. Disruption of the α-receptor, either in the knockout (αERKO) or by treatment with a pure antiestrogen, results in dilution of cauda epididymal sperm, disruption of sperm morphology, inhibition of sodium transport and subsequent water reabsorption, increased secretion of Cl^-, and eventual decreased fertility. In addition to this primary regulation of luminal fluid and ion transport, estrogen is also responsible for maintaining a differentiated epithelial morphology. Thus, we conclude that estrogen or its α-receptor is an absolute necessity for fertility in the male.     

Prenatal programming of reproductive neuroendocrine function: the effect of prenatal androgens on the development of estrogen positive feedback and ovarian cycles in the ewe

Exposure of the female ovine fetus to male hormones during a sensitive window of in utero life causes disruption to reproductive function. In some animals, androgen exposure completely abolishes reproductive cycles, but in others, cycles are progressively lost with age. The present study tested two predictions: that noncycling, androgenized animals are unable to respond to estrogen with a preovulatory-like surge of LH (estrogen positive feedback), and that the androgenized animals that exhibit a progressive loss of cycles also show a progressive loss of estrogen positive feedback. Androgenized ewes were generated by injection of their mothers with testosterone propionate twice per week from Day 30 to Day 90 of pregnancy (term, 147 days). Control ewes received no injections. Whether ewes could exhibit estrogen positive feedback was tested on five occasions before puberty (30 wk) and once during the anestrous period. All control animals had repeated reproductive cycles in both the first and second breeding season, and all showed robust LH surges during test periods. Despite the fact that 64% of androgenized animals showed reproductive cycles, estrogen positive feedback could be demonstrated in only 6.1% of trials. Subsequent experiments revealed that the lack of response to estrogen in androgenized animals was not because of pituitary insensitivity to GnRH, a requirement for higher concentrations of estrogen, or a surge that was delayed relative to the time of estrogen administration. The mechanisms by which some androgenized ewes can produce normal reproductive cycles in the apparent absence of estrogen positive feedback are currently unknown.     

TLR3 activation evokes IL-6 secretion, autocrine regulation of Stat3 signaling and TLR2 expression in human bronchial epithelial cells

Human bronchial epithelial cells exposed to synthetic double-stranded RNA (poly I:C) exhibited increased IL-6 and RANTES secretion and TLR2 expression that was inhibited following TLR3 silencing. Increased NF-κB and Stat3 phosphorylation were detected after poly I:C exposure and pretreatment with neutralizing antibody targeting IL-6 receptor α (IL-6Rα -nAb) or blocking Jak2 and Stat3 activity inhibited Stat3 phosphorylation. TLR2 up-regulation by poly I:C was also reduced by IL-6Rα-nAb and inhibitors of Jak2, Stat3 and NF-κB phosphorylation, whereas RANTES secretion was unaffected, but abolished following NF-κB inhibition. Treatment with exogenous IL-6 failed to increase TLR2. These findings demonstrate that TLR3 activation differentially regulates TLR expression through autocrine signaling involving IL-6 secretion, IL-6Rα activation and subsequent phosphorylation of Stat3. The results also indicate that NF-κB and Stat3 are required for TLR3-dependent up-regulation of TLR2 and that its delayed expression was due to a requirement for IL-6-dependent Stat3 activation.     

Progesterone action and responses in the alphaERKO mouse

Ovarian steroids have important inter-related roles in many systems and processes required for mammalian reproduction. The female reproductive tract, ovaries, and mammary glands are all targets for both estrogen and progesterone. In addition, the actions of these hormones are intertwined in that, for example, progesterone attenuates the proliferative effect of estrogen in the uterus, whereas estrogen also induces the progesterone receptor (PR) mRNA and protein, thus enhancing progesterone actions. The generation of mice that lacks the progesterone receptor (PRKO) or the estrogen receptoralpha (alphaERKO) has provided numerous insights into the interacting roles of these hormones. The mammary glands of the PRKO mice develop with full epithelial ducts that lack side branching and lobular alveolar structures, whereas the alphaERKO mice develop only an epithelial rudiment. This indicates that estrogen is important for ductal morphogenesis, whereas progesterone is required for ductal branching and alveolar development. Both the alphaERKO and PRKO mice are also anovulatory, but exhibit different causal pathologies. The alphaERKO ovary seems to possess follicles up to the preantral stage and shows a polycystic phenotype as a result of chronic hyperstimulation by LH. The PRKO follicles seem to develop to an ovulatory stage, but are unable to rupture, indicating a role for progesterone in ovulation. The uteri of these two strains seem to develop normally; however, the function and hormone responses are abnormal in each. Because estrogen is known to induce PRs in the uterus, the progesterone responsiveness of the alphaERKO uterus was characterized. PR mRNA was detected but was not up-regulated by estrogen in the alphaERKO tissue. PRs are present in the alphaERKO tissue at 60% of the level in wild-type tissue and show a similar amount of A and B isoforms when measured by R5020 binding and detected by Western blotting. The PRs were able to mediate induction of two progesterone-responsive uterine genes: calcitonin and amphiregulin. The alphaERKO uterine tissue was also able to undergo a decidual reaction in response to hormonal and intraluminal treatments to mimic implantation; however, unlike normal wild-type uteri, this response was estrogen independent in the alphaERKO uterine tissue.     

Sex hormone modulation of human uterine epithelial cell immune responses

Sexually transmitted infections are a major worldwide publichealth problem affecting millions of people. A number of bacteria,fungi, viruses, and protozoa can infect reproductive tissues,resulting in varying degrees of pathology ranging from littlediscomfort to death. The female reproductive tract has evolvedinnate and adaptive immune mechanisms that protect from microbialinfection, thereby reducing infection and disease. Central tothis protection are the epithelial cells that line the femalereproductive tract. In the uterus, columnar epithelial cellsprovide a physical barrier to microbial infection, possess toll-likereceptors that detect pathogens and secrete a number of constitutiveand induced factors that directly or indirectly hinder infection.For example, uterine epithelial cells secrete peptides thatdestroy pathogenic microbes. In addition, epithelial cells producechemokines and cytokines that attract and activate innate immunecells and serve as a link to the adaptive immune system. Further,uterine epithelial cells serve as a conduit for secretory antibodiesto enter the lumen and can present antigen to T cells. Theseprotective mechanisms contribute to an environment in the uterusthat is generally considered sterile, unlike the environmentin the lower female reproductive tract. The uterine environmentis in constant flux due to the concentration changes in sexhormones that occur in preparation for reproduction. The sexhormones estrogen and progesterone alter the local immune systemto prepare for conception, influence how well the immune systemwill tolerate antigenic sperm and a semi-allogeneic fetus andyet provide a network of protective immune mechanisms againstmicrobial pathogens. Understanding how sex hormones influenceuterine epithelial cell function will provide a basis for immuneprotection in the uterus.     

Estrogen and progestin receptors in the reproductive tract of male and female primates

With the aid of monoclonal antibodies specific to the estrogen and progestin receptors, we have examined the cellular localization of these proteins in the reproductive tract of male and female macaques. Two striking findings have resulted from our work with these new reagents. First, these receptors are detectable only in cell nuclei, regardless of hormonal treatment, and second, they are often detectable in stromal, but not epithelial cells when the epithelial cells undergo various estrogen or progestin-dependent events. The latter observation has led us to conclude that stromal cell-epithelial cell interactions may play previously unappreciated roles in the hormonal control of the primate reproductive tract. The lines of evidence that have drawn us to this conclusion will be reviewed.     

Immunocytochemical localization of atrial natriuretic factor (ANF) in rat female reproductive tract: evidence for a potential hormonal regulation

In the present studies atrial natriuretic factor (ANF) was characterized immunocytochemically in the reproductive tract of immature female rats, and changes of ANF levels in response to different hormonal conditions were demonstrated. Administration of pregnant mare serum gonadotropin (PMSG) to immature animals has shown to be a useful method to synchronize growth, differentiation and atresia of ovarian follicles. ANF immunoreactivity was investigated in rat uterus and oviduct during follicular growth and estrogenic dominance (48 h after PMSG treatment) and during follicular atresia and progesterone dominance (96 h after PMSG treatment). Our immunocytochemical results showed that in rat uterus ANF was localized in endometrial mucosal and glandular epithelium and smooth muscle cells of the myometrium. In the oviduct ANF immunoreactivity was observed in mucosal cells and muscle layers. Immunocytochemical staining patterns and Western blot analysis revealed that ANF levels in rat uterus and oviduct are modulated by the hormonal status. ANF immunoreactivity was elevated during estrogenic dominance (48 h after PMSG) in uterus and oviduct. However, during progesterone dominance (96 h after PMSG) elevation of ANF immunoreactivity was observed in the uterus only. These results raise the possibility that ANF expression in rat oviduct is positively controlled by estrogen and negatively by progesterone. ANF staining in uterus during progesterone phase provides evidence that both estrogen and progesterone regulate ANF levels in uterus. The observed staining patterns indicate that ANF may have intracellular functions as well as a role in priming the extracellular environment. Accordingly, the possibility that ANF might be an important regulatory molecule for autocrine/paracrine communication within the female reproductive tract should be considered.     

Stat4, a novel gamma interferon activation site-binding protein expressed in early myeloid differentiation.

Interferon regulation of gene expression is dependent on the tyrosine phosphorylation and activation of the DNA-binding activity of two related proteins of 91 kDa (STAT1) and/or 113 kDa (STAT2). Recent studies have suggested that these proteins are substrates of Janus kinases and that proteins related in STAT1 are involved in a number of signalling pathways, including those activated in myeloid cells by erythropoietin and interleukin-3 (IL-3). To clone STAT-related proteins from myeloid cells, degenerate oligonucleotides were used in PCRs to identify novel family members expressed in myeloid cells. This approach allowed the identification and cloning of the Stat4 gene, which is 52% identical to STAT1. Unlike STAT1, Stat4 expression is restricted but includes myeloid cells and spermatogonia. In the erythroid lineage, Stat4 expression is differentially regulated during differentiation. Functionally, Stat4 has the properties of other STAT family genes. In particular, cotransfection of expression constructs for Stat4 and Jak1 and Jak2 results in the tyrosine phosphorylation of Stat4 and the acquisition of the ability to bind to the gamma interferon (IFN-gamma)-activated sequence of the interferon regulatory factor 1 (IRF-1) gene. Stat4 is located on mouse chromosome 1 and is tightly linked to the Stat1 gene, suggesting that the genes arose by gene duplication. Unlike Stat1, neither IFN-alpha nor IFN-gamma activates Stat4. Nor is Stat4 activated in myeloid cells by a number of cytokines, including erythropoietin, IL-3, granulocyte colony-stimulating factor, stem cell factor, colon-stimulating factor 1, hepatocyte growth factor, IL-2, IL-4, and IL-6.