Lipopolysaccharide and TNF-alpha produce very similar changes in gene expression in human endothelial cells.

Intracellular signaling pathways regulated by Toll-like receptor 4 (TLR4) and tumor necrosis factor-alpha (TNF-alpha) both activate NFkappaB. This suggests that lipopolysaccharide (LPS) and TNF-alpha should alter transcription of a common set of genes. We tested this hypothesis by treating first passage human umbilical endothelial cells (HUVEC) for 6 h with LPS (50 ng/ml+1 microg/ml CD14) or TNF-alpha (10 ng/ml) and analyzing changes in gene expression by microarray analysis (Affymetrix GeneChips). LPS and TNF-alpha increased expression of 191 common genes and decreased expression of 102 genes. Regulated transcripts encoded for a large number of chemokines, adhesion molecules, procoagulant factors, and molecules that affect cell integrity. Based on the microarray analysis and subsequent confirmation of specific genes by Northern analysis, all 203 genes altered by LPS were altered by TNF-alpha. An additional 17 genes were induced only by TNF-alpha and the expression of 46 was reduced. There were, however, some differences in the kinetics of changes. We also showed that endogenous CD14 was present on these early passage cells and exogenous CD14 was not necessary for most of the LPS response. An autocrine effect from LPS induced expression of TNF-alpha also was ruled out by blocking TNF-alpha with monoclonal antibodies. In conclusion, LPS induces a robust alteration in gene expression in HUVEC that is very similar to that induced by TNF-a. This LPS effect on endothelium could play an important role in the innate immune response.

Renal oxytocin receptor messenger ribonucleic acid: characterization and regulation during pregnancy and in response to ovarian steroid treatment.

Although the neurohypophyseal hormone oxytocin (OT) is best know for its role in reproduction, OT also stimulates natriuresis at physiological plasma levels. This effect is mediated via specific renal OT receptors (OTRs). In the present study, we have characterized rat renal OTR gene transcripts and assessed their regulation during gestation and in response to gonadal steroid treatment. Using a specific rat OTR probe, two major OTR messenger RNA (mRNA) bands [6.7 and 4.8 kilobases (kb)] were detected in renal extracts, corresponding to two of the three bands present in rat uterus. In contrast to the dramatic rise of OTR mRNA levels at term in the uterus and pituitary, renal OTR mRNA levels underwent a strong more than 3-fold decrease at term. Binding studies using a iodinated specific OT antagonist revealed a concomitant decrease in renal OT-binding sites. On the other hand, estrogen (E2) treatment led to an increase in renal OTR mRNA levels, as is also the case in the uterus and pituitary. However, the predominant E2-induced mRNA species were shorter (3.6 and 3.2 kb) than those present in control rat kidneys (6.7 and 4.8 kb). Analysis by reverse transcriptase-PCR and 5'- and 3'-directed complementary DNA probes indicated that the E2-induced OTR mRNA transcripts possessed the same coding region, but contained a shortened 3'-untranslated region. Binding studies showed that E2 treatment also led to an increase in renal OT-binding sites, suggesting that the shortened OTR transcripts encoded a functional receptor. The present study indicates that the uterine-type OTR gene is expressed in rat kidneys, but that the mechanisms controlling the expression of this gene in the two tissues are markedly different. The differential tissue-specific regulation of OTR gene expression may represent a mechanism by which circulating OT can assume a multifunctional role in both reproduction and sodium homeostasis.

Oxytocin receptor gene expression in the rat uterus during pregnancy and the estrous cycle and in response to gonadal steroid treatment.

It is well established that uterine oxytocin receptors (OTRs) are strongly up-regulated immediately before parturition as well as in response to estrogen (E2) administration. Progesterone (P4), on the other hand, induces a rapid down-regulation. We recently cloned the rat OTR gene and characterized its expression in the rat uterus. In this study, we examined the regulation of OTR messenger RNA (mRNA) levels in rat uterus during pregnancy, the estrous cycle, and in response to gonadal steroid treatment. OTR mRNA levels increased more than 25-fold during gestation: 4.5-fold during the first 21 days and 6-fold within 24 h between day 21 and the onset of parturition. Uterine OTR mRNA levels fell rapidly by 85% within 24 h following parturition. By in situ hybridization, OTR mRNA was localized specifically to the longitudinal and circular layers of the myometrium but was not detected in the endometrium. During the estrous cycle, OTR mRNA levels increased 2-fold between metestrus and proestrus, whereas oxytocin (OT) binding rose more than 10-fold within this same interval. Treatment of ovariectomized rats with E2 lead to a significant increase in both OTR mRNA levels (4.4-fold) and OT binding (< 6-fold). Cotreatment with P4 strongly reduced OT binding by 75% (P < 0.01) but did not significantly affect the E2-induced rise in OTR mRNA (11% decrease, P > 0.1). Our data suggest that the increased expression of OT binding sites observed at the onset of labor and at proestrus is mediated, at least in part, by an E2-induced up-regulation of OTR gene expression. However, it also appears that OTR mRNA levels are not the sole determinants of uterine OT binding. Specifically, P4-mediated OTR down-regulation cannot be explained by an effect on OTR mRNA accumulation and may involve novel mechanisms acting at translational or posttranslational levels.

Effects of retinoic acid and estrogens on oxytocin gene expression in the rat uterus: in vitro and in vivo studies.

We and others have previously identified functional estrogen (E) and retinoic acid (RA) response elements in the human and rat oxytocin (OT) gene promoters. Whereas there is no direct evidence for a significant role of E or RA in the regulation of rat hypothalamic OT gene expression, we have recently demonstrated that in vivo administration of E strongly stimulates uterine OT gene expression. Here, we show that in vivo administration of RA similarly induces a significant increase in uterine OT gene expression. Moreover, we report that the E and RA effects are reproducible in vitro. Using short-term uterine organ explant cultures derived from 18-day pregnant rats, we found that E (50 nM) and RA (0.4 nM) increased OT mRNA levels 5.2- and 3-fold, respectively, suggesting a direct action of these agents on uterine OT gene expression. Finally, we analyzed uterine E and RA receptor gene expression during pregnancy. Using semi-quantitative Northern blot analysis, we found that mRNAs encoding the E receptor, the RA receptor alpha and RA receptor beta are present in rat uterus and that their levels rise by 3.7-, 3.6- and 5.8-fold, respectively, between day 14 of gestation and term. Taken together, the data suggest that, at term, the rat uterus has an increased capacity to respond to E and RA, and that both agents may be involved in mediating the dramatic increase of OT mRNA accumulation observed in the uterus at term.

Gonadal steroid regulation of oxytocin and oxytocin receptor gene expression.

By Northern blot analysis and in situ hybridization, we have determined that, at term, the rat uterine epithelium represents a major site of oxytocin (OT) gene expression. OT mRNA levels increase > 150-fold during pregnancy and, at term, exceed hypothalamic OT mRNA by a factor of 70. By cryoultramicroscopy, OT immunoreactivity was localized to transport vesicles in the apical compartment of uterine epithelial cells. Estrogens (E) act as a strong inducer of uterine OT gene expression in vivo, and this effect is potentiated 7-fold by concomitant progesterone (P) administration. We have also cloned the rat OT receptor (OTR) gene and developed a polymerase chain reaction (PCR)-based assay to measure OTR mRNA. Whereas OTR mRNA is strongly induced by E, P does not potentiate but slightly attenuates the E-induced rise. However, E-induced OT binding is completely reversed by concomitant P administration, suggesting an additional post-transcriptional effect of P. The mechanisms of E-induction of the uterine OT gene remain unclear, inasmuch as the OTR gene promoter does not contain a classical estrogen response element (ERE). Moreover, transfection analysis of a 3.1 kb OTR gene promoter fragment linked to a luciferase reporter gene indicates that promoter activity is induced 5-fold by calcium ionophore A23187 but not by E.

Uterine oxytocin gene expression. I. Induction during pseudopregnancy and the estrous cycle.

We have recently demonstrated that the gene encoding the hypothalamic peptide oxytocin (OT) is highly expressed in the rat endometrial epithelium during the last 4 days of pregnancy. Here, we show that uterine OT gene expression is also induced during the proestrous phase of the estrous cycle and after induction of pseudopregnancy. In mature female rats, OT mRNA levels increased more than 10-fold between diestrus and proestrus and remained elevated at estrus. The levels attained at estrus corresponded to about 1/20th of the levels present at term. In immature rats rendered pseudopregnant by treatment with pregnant mare serum and hCG, uterine OT mRNA levels rose steadily and reached a maximum on day 14 of pseudopregnancy, corresponding to about 1/8th of the levels observed on day 21 of normal pregnancy. Oil-induced decidualization of the left uterine horn prolonged pseudopregnancy and maintained OT mRNA levels in both uterine horns until day 19 of pseudopregnancy. These changes were tissue specific, as hypothalamic OT mRNA levels remained essentially unaffected. The present findings demonstrate that either spontaneous or induced changes in endogenous steroid levels are capable of eliciting important changes in uterine, but not hypothalamic, OT gene expression.

Uterine oxytocin gene expression. II. Induction by exogenous steroid administration.

As we have recently shown, the gene encoding the hypothalamic nonapeptide oxytocin (OT) is expressed in the rat endometrial epithelium during late pregnancy and the estrous phase of the estrous cycle. To investigate the role of ovarian steroids in the regulation of uterine OT gene expression, Silastic capsules containing estradiol or progesterone were implanted into immature ovariectomized rats. Exposure to estradiol alone for 2 days caused a significant rise in OT mRNA. Administration of progesterone alone was without effect. However, a strong synergism was observed when the two hormones were applied together; progesterone potentiated the effect of estradiol by a factor of 7. In animals treated with steroids for 4 days, the removal of either the estradiol or progesterone capsule after day 2 led to a decrease in the total amount of OT mRNA accumulation, implying that the continued action of both steroids was required to achieve maximal OT mRNA levels. Immunocytochemical analysis demonstrated that the main site of steroid-induced uterine OT gene expression is the endometrial epithelium, the same site where endogenously induced OT gene expression occurs at the end of pregnancy. The OT mRNA levels achieved after 4 days of treatment with both steroids were comparable to those achieved at estrus or during pseudopregnancy, but corresponded to less than 20% of the levels present in the uterus on day 21 of pregnancy. These data suggest that in the uterus, the synergistic action of ovarian steroids represents an important, but probably not exclusive, regulator of OT gene expression.

Ubiquitin gene expression: response to environmental changes.

It has previously been shown that the yeast ubiquitin genes UBI1, 2 and 3 are strongly expressed during the log-phase of batch culture growth, whereas the UBI4 gene is weakly expressed. We found that heat shock, treatment with DNA-damaging agents, starvation, and the feeding of starved cells all transiently induced UBI4. These results suggest that UBI4 is induced whenever a change in culture conditions dictates a dramatic shift in cellular metabolism, and that UBI4 expression returns to lower levels once cellular metabolism has adapted to the new conditions. In contrast, all of the treatments tested, except starvation, transiently repressed the UBI1, 2 and 3 genes. Although starvation also repressed UBI1, 2 and 3 its effect was not transient, and expression only recovered upon the addition of fresh media. These results, together with others presented here, suggest that high levels of UBI1, 2 and 3 expression are dependant upon ongoing cell growth, and that treatments which slow or stop growth repress their expression.