Binding loci of RelA-containing nuclear factor-kappaB dimers in promoter regions of PHM1-31 myometrial smooth muscle cells.

Human parturition is associated with many pro-inflammatory mediators which are regulated by the nuclear factor-kappaB (NF-κB) family of transcription factors. In the present study, we employed a ChIP-on-chip approach to define genomic loci within chromatin of PHM1-31 myometrial cells that were occupied by RelA-containing NF-κB dimers in response to a TNF stimulation of 1 h. In TNF-stimulated PHM1-31 cells, anti-RelA serum enriched 13 300 chromatin regions; importantly, 11 110 regions were also enriched by anti-RelA antibodies in the absence of TNF. DNA sequences in these regions, from both unstimulated or TNF-stimulated PHM1-31 cultures, were associated with genic regions including IκBα, COX-2, IL6RN, Jun and KCNMB3. TNF-induced binding events at a consensus κB site numbered 1667; these were represented by 112 different instances of the consensus κB motif. Of the 1667 consensus κB motif occurrences, 770 (46.2%) were identified within intronic regions. In unstimulated PHM1-31 cells, anti-RelA-serum-enriched regions were associated with sequences corresponding to open reading frames of ion channel subunit genes including CACNB3 and KCNB1. Moreover, in unstimulated cells, the consensus κB site was identified 2116 times, being defined by 103 different sequence instances of this motif. Of these 2116 consensus κB motifs, 1089 (51.5%) were identified within intronic regions. Parallel expression array analyses in PHM1-31 cultures demonstrated that TNF stimulated a >2-fold induction in 51 genes and a fold repression of >1.5 in 18 others. We identified 14 anti-RelA-serum-enriched genomic regions that correlated with 17 TNF-inducible genes, such as COX2, Egr-1, Jun, IκBα and IL6, as well as five regions associated with TNF-mediated gene repression, including Col1A2.

Regulation of GTP-binding protein (Gαs) expression in human myometrial cells: a role for tumor necrosis factor in modulating Gαs promoter acetylation by transcriptional complexes.

The onset of parturition is associated with a number of proinflammatory mediators that are themselves regulated by the nuclear factor κB (NF-κB) family of transcription factors. In this context, we previously reported that the RelA NF-κB subunit represses transcription and mRNA expression of the proquiescent Gαs gene in human myometrial cells following stimulation with the proinflammatory cytokine TNF. In the present study, we initially defined the functional consequence of this on myometrial contractility. Here we show that, contrary to our initial expectations, TNF did not induce myometrial contractility but did inhibit the relaxation produced by the histone deacetylase inhibitor trichostatin A, an effect that in turn was abolished by the NF-κB inhibitor N(4)-[2-(4-phenoxyphenyl)ethyl]-4,6-quinazolinediamine. This result suggested a role for TNF in regulating Gαs expression via activating NF-κB and modifying histone acetylation associated with the promoter region of the gene. In this context, we show that the -837 to -618 region of the endogenous Gαs promoter is occupied by cAMP-response element-binding protein (CREB), Egr-1, and Sp1 transcription factors and that CREB-binding protein (CBP) transcriptional complexes form within this region where they induce histone acetylation, resulting in increased Gαs expression. TNF, acting via NF-κB, did not change the levels of CREB, Sp1, or Egr-1 binding to the Gαs promoter, but it induced a significant reduction in the level of CBP. This was associated with increased levels of histone deacetylase-1 and surprisingly an increase in H4K8 acetylation. The latter is discussed herein.

Expression of the GTP-binding protein (Galphas) is repressed by the nuclear factor kappaB RelA subunit in human myometrium.

In humans, the factors that govern the switch from myometrial quiescence to coordinated contractions at the initiation of labor are not well defined. The onset of parturition is itself associated with increases in a number of proinflammatory mediators, many of which are regulated by the nuclear factor kappaB (NF-kappaB) family of transcription factors. Recently, we have provided evidence that the RelA NF-kappaB subunit associates with protein kinase A in pregnant myometrial tissue, suggesting links with the Galphas/cAMP/protein kinase A pathway. TNFalpha is a potent activator of NF-kappaB, and levels of this cytokine are increased within the myometrium at term. In the current study, using primary cultures of myometrial cells, TNFalpha was observed to repress expression of Galphas while, at the same time, stimulating NF-kappaB activity. Furthermore, this effect could be replicated by exposure to bacterial lipopolysaccharide and exogenous expression of RelA. Moreover, TNFalpha was seen to repress endogenous Galphas mRNA expression as judged by RT-PCR analyses. Using the chromatin immunoprecipitation assay, we show that RelA did not bind directly to the Galphas promoter. Significantly, expression of a coactivator protein, cAMP response element binding protein binding protein, relieved RelA-induced down-regulation of Galphas expression. Together, these data suggest that, in human myometrium, repression of the Galphas gene by NF-kappaB occurs through a non-DNA binding mechanism involving competition for limiting amounts of cellular coactivator proteins including cAMP response element binding protein binding protein.

Expression and interaction of the transcriptional coregulators, CBP/p300, in the human myometrium during pregnancy and labor.

OBJECTIVE: In humans, the factors that govern the switch from myometrial quiescence to coordinated contractions at the initiation of labor are not well defined. Recent studies have highlighted a role for the coactivator, CREB binding protein (CBP), in the human myometrium during pregnancy and labor through its ability to acetylate histones. In the present study, the expression of CBP and its related coactivator, p300, were examined. METHODS: Levels and interactions of CBP and its paralogue p300 were determined by Western blotting, immunohistochemistry, and coimmunoprecipitation experiments using myometrial biopsy samples from nonpregnant (NP), pregnant nonlaboring (P), and spontaneously laboring (SL) women. RESULTS: Levels of CBP were seen to increase in term P myometrial samples but were then greatly reduced in SL myometrium. In contrast, levels of p300 remained uniform between NP, P, and SL tissues. These observations were confirmed by immunhistochemical analyses. Immunoprecipitation experiments highlighted that CBP was able to interact with CREB, CREM, ATF-2, and p300 in P lower segment myometrium. CONCLUSION: Recent evidence suggests that competition for CBP plays an important role in regulating gene expression during cell growth. Consequently our data suggest that the increase in myometrial CBP levels during pregnancy may occur to meet this increase in CBP demand. Moreover, from coimmunoprecipitation experiments, this increase in CBP expression would be expected to facilitate the transactivation potential of the cyclic adenosine monophosphate (cAMP)-dependent transcription factors CREB, CREM, and ATF-2.

Expression and deoxyribonucleic acid-binding activity of the nuclear factor kappaB family in the human myometrium during pregnancy and labor.

In humans, the factors that govern the switch from myometrial quiescence to coordinated contractions at the initiation of labor are not well defined. The onset of parturition is itself associated with increases in a number of proinflammatory factors, many of which are regulated by the nuclear factor kappaB (NF-kappaB) family of transcription factors. The expression and DNA-binding activity of NF-kappaB in the myometrium during gestation and parturition were examined. Levels of c-Rel, p50, and p105 NF-kappaB species were dramatically reduced in pregnant myometrium compared with nonpregnant (NP) controls, whereas expression of the RelA subunit remained uniform. Importantly, during labor, expression of all subunits was observed to be significantly reduced in all myometrial samples studied relative to NP levels. Moreover, for RelA, c-Rel, and p50 subunits, there was a gradient of expression between laboring upper (corpus) and lower uterine segment myometrium. No RelB or p52 subunits could be detected. EMSAs identified changes in NF-kappaB subunit composition in the myometrium during pregnancy and labor, with p50 homodimers predominant in NP tissues being replaced with RelA:p50 heterodimers in pregnant and laboring samples. Significantly, RelA was observed to be phosphorylated at serine-536, implicating the involvement of the phosphatidylinositol-3-kinase/AKT pathway in NF-kappaB function in the myometrium.

The effect of trichostatin-A and tumor necrosis factor on expression of splice variants of the MaxiK and L-type channels in human myometrium.

The onset of human parturition is associated with up-regulation of pro-inflammatory cytokines including tumor necrosis factor (TNF) as well as changes in ion flux, principally Ca(2+) and K(+), across the myometrial myocytes membrane. Elevation of intra-cellular Ca(2+) from the sarcoplasmic reticulum opens L-type Ca(2+) channels (LTCCs); in turn this increased calcium level activates MaxiK channels leading to relaxation. While the nature of how this cross-talk is governed remains unclear, our previous work demonstrated that the pro-inflammatory cytokine, TNF, and the histone deacetylase inhibitor, Trichostatin-A (TSA), exerted opposing effects on the expression of the pro-quiescent Gαs gene in human myometrial cells. Consequently, in this study we demonstrate that the different channel splice variants for both MaxiK and LTCC are expressed in primary myometrial myocytes. MaxiK mRNA expression was sensitive to TSA stimulation, this causing repression of the M1, M3, and M4 splice variants. A small but not statistically significantly increase in MaxiK expression was also seen in response to TNF. In contrast to this, expression of LTCC splice variants was seen to be influenced by both TNF and TSA. TNF induced overall increase in total LTCC expression while TSA stimulated a dual effect: causing induction of LTCC exon 8 expression but repressing expression of other LTCC splice variants including that encoding exons 30, 31, 33, and 34, exons 30-34 and exons 40-43. The significance of these observations is discussed herein.

Human trophoblast cells modulate endometrial cells nuclear factor κB response to flagellin in vitro.

BACKGROUND: Implantation is a complex process that requires a delicate cooperation between the immune and reproductive system. Any interference in the fine balance could result in embryo loss and infertility. We have recently shown that Toll-like receptor 5 activation results in a decrease of trophoblast cells binding to endometrial cells in an in vitro model of human implantation. However, little is known about the downstream signalling leading to the observed failure in implantation and the factors that modulate this immune response. METHODS AND PRINCIPAL FINDINGS: An in vitro model of embryo implantation was used to evaluate the effect of trophoblasts and flagellin on the activation of NF-κB in endometrial cells and whether TLR5-related in vitro implantation failure is signalled through NF-κB. We generated two different NF-κB reporting cell lines by transfecting either an immortalized endometrial epithelial cell line (hTERT-EECs) or a human endometrial carcinoma cell line (Ishikawa 3-H-12) with a plasmid containing the secreted alkaline phosphatase (SEAP) under the control of five NF-κB sites. The presence of trophoblast cells as well as flagellin increased NF-κB activity when compared to controls. The NF-κB activation induced by flagellin was further increased by the addition of trophoblast cells. Moreover, blocking NF-κB signalling with a specific inhibitor (BAY11-7082) was able to restore the binding ability of our trophoblast cell line to the endometrial monolayer. CONCLUSIONS: These are the first results showing a local effect of the trophoblasts on the innate immune response of the endometrial epithelium. Moreover, we show that implantation failure caused by intrauterine infections could be associated with abnormal levels of NF-κB activation. Further studies are needed to evaluate the target genes through which NF-κB activation after TLR5 stimulation lead to failure in implantation and the effect of the embryo on those genes. Understanding these pathways could help in the diagnosis and treatment of implantation failure cases.

NF-kappaB function in the human myometrium during pregnancy and parturition.

Interactions between the nuclear factor kappaB (NF-kappaB) family of proteins (RelA, RelB, c-Rel, p50 and p52) and DNA are vital for cells to function normally; for example, in the human myometrium, NF-kappaB-regulated pro-inflammatory mediators, including TNFalpha, IL-1beta, IL-8 and COX-2 are associated with the onset of labour. NF-kappaB, however, regulates the expression of over 400 genes, although it is unlikely these would all be activated in concert by a single inducer. At present, defining the role of the NF-kappaB RelA:p50 dimer, which governs a number of inflammatory promoters, is at the forefront of the parturition research field. However, to over-look the function of other family members and how they may regulate alternative signalling networks within reproductive tissues, only serves to ensure we will never fully understand the molecular circuitry influenced by this family of transcription factors. Consequently this review highlights other mechanisms by which the NF-kappaB family of regulators have been shown to function in other systems and how they may readily translate to understanding the regulation underpinning human parturition.

Examining the spatio-temporal expression of mRNA encoding the membrane-bound progesterone receptor-alpha isoform in human cervix and myometrium during pregnancy and labour.

Human parturition is associated with a modification in the sensitivity of the myometrium to progesterone. The molecular basis for this change, however, remains unclear. It is well documented that progesterone can exert its effects through non-genomic mechanisms, including acting through membrane-bound progesterone receptors (mPRs). Recently, a novel membrane-bound PR, termed mPRalpha, was cloned. mPRalpha was unlike any other PR in the databases, but it was seen to have significant homology to G-protein-coupled receptors (GPCR). In this study, we examined the spatio-temporal expression of mPRalpha mRNA in human cervix and both lower and upper myometrial segments from non-pregnant (NP), pregnant (P) and spontaneously labouring (SL) women. We observed an incremental increase in mPRalpha mRNA expression in NP and P samples with the peak level being observed in SL tissues. No major differences were observed between upper or lower pregnant myometrial regions. Interestingly, levels of mPRalpha transcripts were substantially greater in labouring lower segment myometrium compared with labouring upper segment. Significantly, we failed to detect mPRalpha message in either unripe or ripe human cervices. These data suggest that mPRalpha protein function may play a role in regulating lower segment myometrial activity during labour. Whether it functions in the cervix, however, remains unclear.

A novel form of the RelA nuclear factor kappaB subunit is induced by and forms a complex with the proto-oncogene c-Myc.

Members of both Myc and nuclear factor kappaB (NF-kappaB) families of transcription factors are found overexpressed or inappropriately activated in many forms of human cancer. Furthermore, NF-kappaB can induce c-Myc gene expression, suggesting that the activities of these factors are functionally linked. We have discovered that both c-Myc and v-Myc can induce a previously undescribed, truncated form of the RelA(p65) NF-kappaB subunit, RelA(p37). RelA(p37) encodes the N-terminal DNA binding and dimerization domain of RelA(p65) and would be expected to function as a trans-dominant negative inhibitor of NF-kappaB. Surprisingly, we found that RelA(p37) no longer binds to kappaB elements. This result is explained, however, by the observation that RelA(p37), but not RelA(p65), forms a high-molecular-mass complex with c-Myc. These results demonstrate a previously unknown functional and physical interaction between RelA and c-Myc with many significant implications for our understanding of the role that both proteins play in the molecular events underlying tumourigenesis.