Uterine leiomyoma is the most common tumor in women and can cause severe morbidity. Leiomyoma growth requires maintenance and proliferation of a stem cell population. Dysregulated DNA methylation has been reported in leiomyoma, but its role in leiomyoma stem cell regulation remains unclear. Here, we FACS sorted cells from human leiomyoma tissues into three populations: stem-cell like cells (LSC, 5%), intermediate cells (LIC, 7%), and differentiated cells (LDC, 88%) and analyzed the transcriptome and epigenetic landscape of leiomyoma cells at different differentiation stages. LSC harbored a unique methylome, with 8862 differentially methylated regions compared to LIC and 9444 compared to LDC, most of which were hypermethylated. Consistent with global hypermethylation, transcript levels of TET1 and TET3 methylcytosine dioxygenases were lower in LSC. Integrative analyses revealed an inverse relationship between methylation and gene expression changes during LSC differentiation. In LSC, hypermethylation suppressed genes important for myometrium- and leiomyoma-associated functions, including muscle contraction and hormone action, to maintain stemness. The hypomethylating drug, 5'-Aza stimulated LSC differentiation, depleting the stem cell population and inhibiting tumor initiation. Our data suggest that DNA methylation maintains the pool of LSC, which is critical for the regeneration of leiomyoma tumors.
Summary
Uterine leiomyoma (LM) is the most common tumor in women. Via its receptor (PGR) expressed in differentiated LM cells, progesterone stimulates paracrine signaling that induces proliferation of PGR-deficient LM stem cells (LSCs). Antiprogestins shrink LM but tumors regrow after treatment cessation possibly due to persisting LSCs. Using sorted primary LM cell populations, we found that the
PGR
gene locus and its target cistrome are hypermethylated in LSCs, inhibiting the expression of genes critical for progesterone-induced LSC differentiation. PGR knockdown shifted the transcriptome of total LM cells toward LSCs and increased global DNA methylation by regulating TET methylcytosine dioxygenases. DNA methylation inhibitor 5′-Aza activated PGR signaling, stimulated LSC differentiation, and synergized with antiprogestin to reduce tumor size
in vivo
. Taken together, targeting the feedback loop between DNA methylation and progesterone signaling may accelerate the depletion of LSCs through rapid differentiation and sensitize LM to antiprogestin therapy, thus preventing tumor regrowth.
The alterations in myometrial biology during labor are not well understood. The myometrium is the contractile portion of the uterus and contributes to labor, a process that may be regulated by the steroid hormone progesterone. Thus, human myometrial tissues from term pregnant in-active-labor (TIL) and term pregnant not-in-labor (TNIL) subjects were used for genome-wide analyses to elucidate potential future preventive or therapeutic targets involved in the regulation of labor. Using myometrial tissues directly subjected to RNA sequencing (RNA-seq), progesterone receptor (PGR) chromatin immunoprecipitation sequencing (ChIP-seq), and histone modification ChIP-seq, we profiled genome-wide changes associated with gene expression in myometrial smooth muscle tissue in vivo. In TIL myometrium, PGR predominantly occupied promoter regions, including the classical progesterone response element, whereas it bound mainly to intergenic regions in TNIL myometrial tissue. Differential binding analysis uncovered over 1700 differential PGR-bound sites between TIL and TNIL, with 1361 sites gained and 428 lost in labor. Functional analysis identified multiple pathways involved in cAMP-mediated signaling enriched in labor. A three-way integration of the data for ChIP-seq, RNA-seq, and active histone marks uncovered the following genes associated with PGR binding, transcriptional activation, and altered mRNA levels: ATP11A, CBX7, and TNS1. In vitro studies showed that ATP11A, CBX7, and TNS1 are progesterone responsive. We speculate that these genes may contribute to the contractile phenotype of the myometrium during various stages of labor. In conclusion, we provide novel labor-associated genome-wide events and PGR-target genes that can serve as targets for future mechanistic studies.
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