Microarray profiling of progesterone-regulated endometrial genes during the rhesus monkey secretory phase

BACKGROUND: In the endometrium the steroid hormone progesterone (P), acting through its nuclear receptors, regulates the expression of specific target genes and gene networks required for endometrial maturation. Proper endometrial maturation is considered a requirement for embryo implantation. Endometrial receptivity is a complex process that is spatially and temporally restricted and the identity of genes that regulate receptivity has been pursued by a number of investigators. METHODS: In this study we have used high density oligonucleotide microarrays to screen for changes in mRNA transcript levels between normal proliferative and adequate secretory phases in Rhesus monkey artificial menstrual cycles. Biotinylated cRNA was prepared from day 13 and days 21–23 of the reproductive cycle and transcript levels were compared by hybridization to Affymetrix HG-U95A arrays. RESULTS: Of ~12,000 genes profiled, we identified 108 genes that were significantly regulated during the shift from a proliferative to an adequate secretory endometrium. Of these genes, 39 were up-regulated at days 21–23 versus day 13, and 69 were down-regulated. Genes up-regulated in P-dominant tissue included: secretoglobin (uteroglobin), histone 2A, polo-like kinase (PLK), spermidine/spermine acetyltransferase 2 (SAT2), secretory leukocyte protease inhibitor (SLPI) and metallothionein 1G (MT1G), all of which have been previously documented as elevated in the Rhesus monkey or human endometrium during the secretory phase. Genes down-regulated included: transforming growth factor beta-induced (TGFBI or BIGH3), matrix metalloproteinase 11 (stromelysin 3), proenkephalin (PENK), cysteine/glycine-rich protein 2 (CSRP2), collagen type VII alpha 1 (COL7A1), secreted frizzled-related protein 4 (SFRP4), progesterone receptor membrane component 1 (PGRMC1), chemokine (C-X-C) ligand 12 (CXCL12) and biglycan (BGN). In addition, many novel/unknown genes were also identified. Validation of array data was performed by semi-quantitative RT-PCR of two selected up-regulated genes using temporal (cycle day specific) endometrial cDNA populations. This approach confirmed up-regulation of WAP four-disulfide core domain 2 (WFDC2) and SLPI during the expected window of receptivity. CONCLUSION: The identification of P-regulated genes and gene pathways in the primate endometrium is expected to be an important first step in elucidating the cellular processes necessary for the development of a receptive environment for implantation

Temporal regulation of gene expression during the expected window of receptivity in the rhesus monkey endometrium

Progesterone has been shown to regulate a number of genes and gene networks in the primate endometrium. This action of progesterone is essential to provide an appropriate milieu for embryo-endometrial communication that can lead to implantation and the successful initiation of pregnancy. A temporal regulation of endometrial genes is most likely required to achieve an appropriate state of receptivity in the primate endometrium. Using simulated menstrual cycles in the rhesus monkey, endometrial tissue was harvested at days that encompass the expected window of receptivity (4-10 days after the estradiol surge) and subsequently converted to cycle day-specific cDNA populations. Using differential display reverse transcriptase-polymerase chain reaction, 12 cDNA fragments were isolated and sequenced whose mRNA levels were elevated during this time frame. The temporal expression patterns of these mRNAs were confirmed by semiquantitative polymerase chain reaction. Two of these fragments exhibited high homology to previously characterized human genes: 1) secretory leukocyte protease inhibitor, also known as antileukoprotease, an endometrial neutrophil elastase inhibitor with antibacterial and anti-inflammatory properties; and 2) syncytin, also known as endogenous retrovirus W envelope protein, a highly fusogenic membrane glycoprotein that induces formation of giant syncytia and is believed to be important in decidual and placental development. The temporal regulation of these genes by progesterone supports their likely role in the orchestration of molecular and cellular events that are required to achieve a state of receptivity in the primate endometrium

Identification of progesterone-dependent messenger ribonucleic acid regulatory patterns in the rhesus monkey endometrium by differential-display reverse transcription-polymerase chain reaction

We used differential-display reverse transcription-polymerase chain reaction (DDRT-PCR) to identify different patterns of progesterone (P4)-dependent gene regulation in rhesus monkey endometria. Complementary DNA populations representing the proliferative phase (estrogen dominant, EcDNA) and an inadequate secretory phase (low level of P4, IcDNA) were compared with a cDNA population representing an adequate secretory phase (normal level of P4, PcDNA). We were able to distinguish four different levels of mRNA regulation: 1) up-regulation by P4 during an adequate secretory phase, 2) autologous down-regulation (IcDNA versus PcDNA), 3) lower abundance in IcDNA compared to PcDNA, and 4) P4-dependent inhibition of EcDNA gene expression. We isolated and sequenced 16 fragments representing these different levels of P4 regulation. The sequence of three fragments that were autologously down-regulated (I1, I2, I4) matched previously entered GenBank mRNAs: I1 encodes serine/threonine protein phosphatase A; I2 encodes oxobutanoate dehydrogenase E1b-beta; and I4 encodes line-1 reverse transcriptase homologue. Six other fragments exhibited homology to uncharacterized expressed sequence tags, sequence site tags, and cosmid clones. The remaining seven fragments exhibited no significant homology to GenBank entries at this time. The various patterns of P4-dependent gene regulation identified in the present study are likely to play roles in the temporal orchestration of events that lead to proper maturation of the endometrium

A progesterone-induced endometrial homolog of a new candidate tumor suppressor, DMBT1

We have previously prepared and characterized a subtracted library enriched for endometrial progesterone (P)-dependent genes in the rhesus monkey. One of the fragment clones (H3) that we selected for sequencing from this library was found to be homologous to human DMBT1, a recently isolated member of the scavenger receptor cysteine-rich superfamily and a new putative tumor suppressor. In this report, we provide evidence that H3 is the rhesus monkey homolog of DMBT1. Additional sequence data of H3 (1071 bp) showed a striking homology with DMBT1 (92% identical). Semiquantitative kinetic PCR of estrogen-dominant vs. P-dominant endometrial complementary DNA populations showed that the H3 gene was up-regulated 5-fold by normal secretory P levels. In situ hybridization with unique probes to H3 confirmed the up-regulation by P in the endometrium and a restricted expression in the stromal compartment. Another recent report suggested the presence of an endometrial tumor suppressor in the same chromosomal region as DMBT1 (10q23-26); deletions in this region were associated with endometrial cancers. Together, these studies potentially provide a molecular link to the protective effect of the action of P on unopposed estrogen exposure in reproductive tract cancers in women

Analysis of differential gene regulation in adequate versus inadequate secretory-phase endometrial complementary deoxyribonucleic acid populations from the rhesus monkey

The ability to create artificial menstrual cycles in the rhesus monkey provides a model for studies on the regulation of genes and gene networks by estradiol or progesterone (P) in the primate endometrium. This model allowed us to create both a normal level of secretory phase P or an inadequate level of secretory phase P, i.e. endometria that cannot support implantation. The objective of our present study focused on PCR analyses of genes for several factors that are believed to be important in the proper maturation of the endometrium. Complementary DNA (cDNA) populations were prepared from endometria harvested on day 13 (peak E level), days 21-23 of an adequate secretory phase (PcDNA) and days 21-23 of an inadequate secretory phase (IcDNA). Although placental protein 14, leukemia inhibitory factor and 17-beta hydroxysteroid dehydrogenase displayed highly upregulated levels in PcDNA (P-activated genes), there was little or no up-regulation in IcDNA. Transforming growth factor-beta 2 and its receptor and insulin growth factor-I and its receptor were up-regulated in PcDNA, whereas little or no expression was observed in IcDNA. Regulators of the cell cycle and transcription, such as retinoblastoma, c-fos, and c-jun genes, were also greatly underexpressed in IcDNA compared with PcDNA. Interestingly, one gene that we studied, keratinocyte growth factor, that was up-regulated by P (peak E levels vs. PcDNA) was more highly expressed in IcDNA. This latter result suggests that low levels of circulating P are sufficient for expression of this gene, whereas high sustained P levels result in an autologous down-regulation. These data show that the regulation of genes that may play pivotal roles in endometrial maturation are differentially expressed in IcDNA vs. PcDNA and may, in part, characterize improper endometrial maturation

Assessment and application of laser microdissection for analysis of gene expression in the rhesus monkey endometrium

We investigated the use of laser capture microdissection (LCM) to identify differences in gene expression between cell types or regions within the rhesus monkey endometrium. Different cell types were harvested from the two major regions of the endometrium during midsecretory phases (Days 21-23) of adequate artificial menstrual cycles: glandular epithelia (G) or stroma (S) from the functionalis (F) or the basalis (B). Amplification of the cDNA populations (primer-specific adaptors) was used to increase the amount of nucleic acid for further analysis. This single amplification step allowed us to detect the housekeeping genes (glyceraldehyde-3-phosphate dehydrogenase and 18S rRNA) and the cDNA smears in the samples. Using differential display reverse transcription polymerase chain reaction (DDRT-PCR), six fragments were selected, cloned, and sequenced based on their regional and cell type localization. Primer-specific PCR analysis subsequently confirmed the localization of three fragments: F1, highly expressed in the functionalis but not the basalis, was homologous (93% identical) to the human leukotriene B4 receptor BLT2; FS-1, highly expressed only in the stroma of the functionalis, had a 94% homology with an as yet uncharacterized gene (FLJ124360); and BG-1, primarily expressed only in the glandular epithelia of the basalis, showed a 98% homology with an uncharacterized bacterial artificial chromosome clone sequence. These LCM-generated cDNA populations coupled with DDRT-PCR can provide an important avenue for the identification of new or novel gene fragments that display cell type- or region-specific gene expression in the rhesus monkey endometrium