Human primordial germ cell commitment in vitro associates with a unique PRDM14 expression profile.

Primordial germ cells (PGCs) develop only into sperm and oocytes in vivo. The molecular mechanisms underlying human PGC specification are poorly understood due to inaccessibility of cell materials and lack of in vitro models for tracking the earliest stages of germ cell development. Here, we describe a defined and stepwise differentiation system for inducing pre-migratory PGC-like cells (PGCLCs) from human pluripotent stem cells (PSCs). In response to cytokines, PSCs differentiate first into a heterogeneous mesoderm-like cell population and then into PGCLCs, which exhibit minimal PRDM14 expression. PGC specification in humans is similar to the murine process, with the sequential activation of mesodermal and PGC genes, and the suppression of neural induction and of de novo DNA methylation, suggesting that human PGC formation is induced via epigenesis, the process of germ cell specification via inductive signals from surrounding somatic cells. This study demonstrates that PGC commitment in humans shares key features with that of the mouse, but also highlights key differences, including transcriptional regulation during the early stage of human PGC development (3-6 weeks). A more comprehensive understanding of human germ cell development may lead to methodology for successfully generating PSC-derived gametes for reproductive medicine.

Mamld1 knockdown reduces testosterone production and Cyp17a1 expression in mouse Leydig tumor cells.

BACKGROUND: MAMLD1 is known to be a causative gene for hypospadias. Although previous studies have indicated that MAMLD1 mutations result in hypospadias primarily because of compromised testosterone production around the critical period for fetal sex development, the underlying mechanism(s) remains to be clarified. Furthermore, although functional studies have indicated a transactivation function of MAMLD1 for the non-canonical Notch target Hes3, its relevance to testosterone production remains unknown. To examine these matters, we performed Mamld1 knockdown experiments. METHODOLOGY/PRINCIPAL FINDINGS: Mamld1 knockdown was performed with two siRNAs, using mouse Leydig tumor cells (MLTCs). Mamld1 knockdown did not influence the concentrations of pregnenolone and progesterone but significantly reduced those of 17-OH pregnenolone, 17-OH progesterone, dehydroepiandrosterone, androstenedione, and testosterone in the culture media. Furthermore, Mamld1 knockdown significantly decreased Cyp17a1 expression, but did not affect expressions of other genes involved in testosterone biosynthesis as well as in insulin-like 3 production. Hes3 expression was not significantly altered. In addition, while 47 genes were significantly up-regulated (fold change >2.0×) and 38 genes were significantly down-regulated (fold change <0.5×), none of them was known to be involved in testosterone production. Cell proliferation analysis revealed no evidence for compromised proliferation of siRNA-transfected MLTCs. CONCLUSIONS/SIGNIFICANCE: The results, in conjunction with the previous data, imply that Mamld1 enhances Cyp17a1 expression primarily in Leydig cells and permit to produce a sufficient amount of testosterone for male sex development, independently of the Hes3-related non-canonical Notch signaling.

Ultrastructural characterization of mouse embryonic stem cell-derived oocytes and granulosa cells.

Germ cells are a unique population of cells responsible for transmitting genetic information from one generation to the next. Our understanding of the key mechanisms underlying germ cell development in vivo remains scarce because of insufficient amounts of cell materials available for conducting biological studies. The establishment of in vitro differentiation models that support the generation of germ cells from mouse pluripotent stem cells provides an alternative means for studying reproductive development. The detection and analysis of stem cell-derived germ cells, however, present technical challenges. Methods for determining the developmental stage of germ cells ex vivo, such as gene expression and/or immunochemical analyses are inadequate, frequently necessitating the use of alternative, elaborate methods to prove germ cell identity. We have generated putative oocytes and granulosa cells in vitro from mouse embryonic stem cells and utilized electron microscopy to characterize these cells. Here, we report on the striking ultrastructural similarity of in vitro-generated oocytes and granulosa cells to in vivo oocytes developing within follicles.

Premature ovarian failure and androgen receptor gene CAG repeat lengths weighted by X chromosome inactivation patterns.

The CAG repeat lengths weighted by X-inactivation ratios were significantly shorter in 58 Japanese patients with premature ovarian failure (POF) than in 42 age-matched control females with normal menses. The results suggest that short CAG repeats with a relatively high androgen receptor function may constitute a susceptibility factor for the development of POF.