The present investigation studied the influ-
Though gender-based differences in the development of protective or pathological adaptive host responses have been widely noted, it is becoming apparent that sex may also influence the early perception of microbial challenges and the generation of inflammatory immune responses. These differences may be due to the actions of reproductive hormones, and such a hypothesis is supported by the presence of receptors for these hormones in a variety of immune cell types. Androgens such as testosterone have been shown to decrease immune functions, including cytokine production. However, the mechanisms by which testosterone limits such responses remain undefined. In this study, we have investigated the acute effects of testosterone on the level of expression of a key trigger for inflammation and innate immunity, Toll-like receptor 4 (TLR4), on isolated mouse macrophages. We show that in vitro testosterone treatment of macrophages, generated in the absence of androgen, elicits a modest but significant decrease in TLR4 expression and sensitivity to a TLR4-specific ligand. In addition, we have studied the effect of in vivo removal of endogenous testosterone on TLR4 expression and endotoxin susceptibility. We report that orchidectomized mice were significantly more susceptible to endotoxic shock and show that macrophages isolated from these animals have significantly higher TLR4 cell surface expression than those derived from sham gonadectomized mice. Importantly, these effects were not apparent in orchidectomized animals that received exogenous testosterone treatment. As such, these data may represent an important mechanism underlying the immunosuppressive effects of testosterone.
Gender has long been known to be a contributory factor in the incidence and progression of disorders associated with immune system dysregulation. More recently, evidence has accumulated that gender may also play an important role in infectious disease susceptibility. In general, females generate more robust and potentially protective humoral and cell-mediated immune responses following antigenic challenge than their male counterparts. In contrast, males have frequently been observed to mount more aggressive and damaging inflammatory immune responses to microbial stimuli. In this article we review the evidence for sexual dimorphism in innate immune responses to infectious organisms and describe our recent studies that may provide a mechanism underlying gender-based differences in conditions such as bacterial sepsis.
Estrogen has been shown to induce a rapid transient increase in c-myc mRNA in the rat uterus. However, no studies of the cell specificity of c-myc expression in the uterus have been reported, and nothing is known about the expression of c-myc in response to other steroids or during normal uterine preparation for implantation. To this end, the cell type-specific localization of c-myc protein was determined in the ovariectomized mouse uterus after progesterone (P4) and/or 17 beta-estradiol (E2) injection as well as during the periimplantation period. After E2 injection, a rapid accumulation of c-myc protein was detected exclusively in the uterine luminal and glandular epithelial nuclei in the ovariectomized mouse. Essentially all of these cells contained immunoreactive c-myc by 12 h postinjection. In contrast, after P4 injection, rapid accumulation of c-myc was noted exclusively in some of the stromal cell nuclei. Pretreatment of the ovariectomized mouse for 4 days with P4 (P4 priming) followed by E2 injection resulted in an increase in the number of c-myc-positive stromal cells, but few, if any, c-myc-positive cells were detected in the luminal and glandular epithelia. These uterine cell type-specific localizations of c-myc protein, induced by E2 or P4 injection, were followed within 18-24 h by DNA synthesis ([ 3H]thymidine incorporation) restricted to the epithelia or stroma, respectively. c-Myc was detected in the nuclei of luminal and glandular epithelia during proestrus and on days 1 and 2 of pregnancy, a period when the uterus is under the influence of estrogen. c-Myc-positive cells were detected in the stroma on day 3, and by day 4 a large number of stromal cell nuclei were c-myc positive. These changes are coincident with increasing P4 levels during early pregnancy. At the implantation chamber on day 5, many cells in the primary decidual zone as well as some of the deeper stromal cells were c-myc protein positive, whereas on day 6, c-myc protein was detected only in the secondary decidual zone. During this period of uterine preparation for embryo implantation and subsequent decidualization, there was a positive correlation between c-myc protein localized in specific populations of uterine cells and subsequent DNA synthesis in those cell types. Thus, both E2 and P4 induce cell type-specific accumulation of c-myc protein in the uterus of the ovariectomized mouse, with E2 induction of c-myc being restricted to epithelia, and P4 induction restricted to stroma.(ABSTRACT TRUNCATED AT 400 WORDS)
Estrogen stimulates water imbibition in the uterine endometrium. This water then crosses the epithelial cells into the lumen, leading to a decrease in viscosity of uterine luminal fluid. To gain insight into the mechanisms underlying this estrogen-stimulated water transport, we have explored the expression profile and functionality of water channels termed aquaporins (AQPs) in the ovariectomized mouse uterus treated with ovarian steroid hormones. Using immunocytochemical analysis and immunoprecipitation techniques, we have found that AQP-1, -3, and -8 were constitutively expressed. AQP-1 expression was restricted to the myometrium and may be slightly regulated by ovarian steroid hormones. AQP-3 was expressed at low levels in the epithelial cells and myometrium, whereas AQP-8 was found in both the stromal cells and myometrium. AQP-2 was absent in vehicle controls but strongly up-regulated by estrogen in the epithelial cells and myometrium of the uterus. This localization implicates all four isotypes in movement of water during uterine imbibition and, based on their localization to the luminal epithelial cells, AQP-2 and -3 in facilitating water movement into the lumen of the uterus. The analysis of the plasma membrane permeability of luminal epithelial cells by two separate cell swelling assays confirmed a highly increased water permeability of these cells in response to estrogen treatment. This finding suggests that estrogen decreases the luminal fluid viscosity, in part, by enhancing the water permeability of the epithelial layer, most likely by increasing the expression of AQP-2 and/or the availability of AQP-3. Together these results provide novel information concerning the mechanism by which estrogen controls water imbibition and luminal fluid viscosity in the mouse uterus.
Immunocytochemical analyses, using several mouse epidermal growth factor (EGF) polyclonal antibodies, detected immunoreactivity only in uterine luminal and glandular epithelia on late proestrus, estrus, and early on day 1 of pregnancy, but not late on day 1. This immunoreactivity was not detected in the ovariectomized uterus, but after estrogen stimulation it was detected first in the luminal epithelium between 12-24 h and then also in the glandular epithelium by 48 h. After 72 h of estrogen withdrawal, EGF immunoreactivity was no longer detected. This response was specific for estrogen and did not occur after progesterone injection (2 mg/day for 4 days). Using antipeptide antibodies specific for prepro-EGF, no immunoreactivity was detected in the ovariectomized uterus, weak reactivity was detected in the estrogenized uterus and submandibular gland, and strong reactivity was detected in the kidney. Northern blot analysis of uterine RNA failed to detect the expected 4.8-kilobase prepro-EGF mRNA, but, instead, a rare transcript of 2.4 kilobases was detected, which suggests that EGF mRNA is alternately processed in the uterus. The presence of an EGF-coding uterine transcript was further documented by hybridization of an EGF-coding region-specific oligodeoxyribonucleotide (oligo) to polymerase chain reaction-amplified uterine cDNA. In situ hybridization, using a prepro-EGF cRNA probe as well as an EGF-coding region-specific oligo, showed hybridization that colocalized with the EGF immunostaining (epithelia) and was absent from non-EGF-immunoreactive cells. Pulse labeling experiments coupled with immunoaffinity chromatography showed that estrogen induced an increase in the relative rate of synthesis of an acid-soluble immunoreactive protein which was the same size as authentic EGF. Furthermore, analysis of acid-soluble uterine proteins fractionated by DEAE-cellulose chromatography demonstrated a single coincident peak of antigenic activity and receptor-binding activity which coeluted from the column with authentic EGF. Electron microscopy localized EGF immunoreactivity to the Golgi of luminal epithelial cells. Taken together these results suggest that estrogen regulates expression of the EGF gene specifically in uterine epithelial cells. Increased expression of this gene results in an increase in the relative rate of synthesis of this protein and the accumulation of mature EGF.
The role of nitric oxide (NO) in activation of cGMP is well established. It has been proposed that the ratio of cAMP to cGMP may be important in the regulation of preimplantation embryonic growth and differentiation. Therefore, we determined the ability of murine preimplantation embryos to produce NO. In addition, NO as an endogenous smooth muscle relaxant and vasodilator is a candidate for involvement in embryo implantation because this process requires increased vascular permeability and uterine quiescence at the sites of blastocyst apposition. Nitrite assays, an indirect measure of NO production, indicate that preimplantation murine embryos produce NO. This production was reversibly inhibited by culture of embryos in medium containing a nonspecific NO synthase (NOS) inhibitor (NG-nitro-L-arginine). Additionally, inhibition of normal development was observed in embryos cultured with NOS inhibitor. NO levels increased in culture medium when ovariectomized progesterone-treated animals were exposed to estrogen for 1 h in utero. Such hormonal treatment induces implantation. These data indicate that NO levels are regulated by estrogen and may be important in regulation of implantation. In addition, these data demonstrate for the first time that NO production appears to be required for normal embryonic development.
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