Retinoic acid regulates Kit translation during spermatogonial differentiation in the mouse.

In the testis, a subset of spermatogonia retains stem cell potential, while others differentiate to eventually become spermatozoa. This delicate balance must be maintained, as defects can result in testicular cancer or infertility. Currently, little is known about the gene products and signaling pathways directing these critical cell fate decisions. Retinoic acid (RA) is a requisite driver of spermatogonial differentiation and entry into meiosis, yet the mechanisms activated downstream are undefined. Here, we determined a requirement for RA in the expression of KIT, a receptor tyrosine kinase essential for spermatogonial differentiation. We found that RA signaling utilized the PI3K/AKT/mTOR signaling pathway to induce the efficient translation of mRNAs for Kit, which are present but not translated in undifferentiated spermatogonia. Our findings provide an important molecular link between a morphogen (RA) and the expression of KIT protein, which together direct the differentiation of spermatogonia throughout the male reproductive lifespan.

Retinoic acid induces multiple hallmarks of the prospermatogonia-to-spermatogonia transition in the neonatal mouse.

In mammals, most neonatal male germ cells (prospermatogonia) are quiescent and located in the center of the testis cords. In response to an unknown signal, prospermatogonia transition into spermatogonia, reenter the cell cycle, divide, and move to the periphery of the testis cords. In mice, these events occur by 3-4 days postpartum (dpp), which temporally coincides with the onset of retinoic acid (RA) signaling in the neonatal testis. RA has a pivotal role in initiating germ cell entry into meiosis in both sexes, yet little is known about the mechanisms and about cellular changes downstream of RA signaling. We examined the role of RA in mediating the prospermatogonia-to-spermatogonia transition in vivo and found 24 h of precocious RA exposure-induced germ cell changes mimicking those that occur during the endogenous transition at 3-4 dpp. These changes included: 1) spermatogonia proliferation; 2) maturation of cellular organelles; and 3), expression of markers characteristic of differentiating spermatogonia. We found that germ cell exposure to RA did not lead to cellular loss from apoptosis but rather resulted in a delay of ∼2 days in their entry into meiosis. Taken together, our results indicate that exogenous RA induces multiple hallmarks of the transition of prospermatogonia to spermatogonia prior to their entry into meiosis.

Nuclear localization of the actin regulatory protein Palladin in sertoli cells.

In the testis, F-actin structures are involved in spermatid nuclear remodeling and cytoplasm reduction, maintenance of the blood-testis barrier, support of the spermatogonial stem cell niche, and release of spermatids into the tubular lumen. To gain a better understanding of actin regulation in Sertoli-germ cell interactions, we investigated the expression of the Palladin (Palld) gene, which encodes a widely expressed phosphoprotein that localizes to actin-rich cytoplasmic structures, including focal adhesions, cell-cell junctions, podosomes, and stress fibers, and serves as a molecular scaffold to bundle actin fibers. In germ cells, PALLD was concentrated along the tubulin- and F-actin-containing cytoplasmic manchette that forms adjacent to the elongating spermatid nucleus during spermiogenesis. To our surprise, PALLD relocated from the cytoplasm to the nucleus of Sertoli cells in the juvenile testis, coincident with the onset of puberty, and this localization was maintained in the adult. We provide evidence that the 140 kDa isoform of PALLD predominates in Sertoli cells, and that it is apparently cleaved, with the C-terminus localizing to the nucleus while the N-terminus remains cytoplasmic. We investigated the nuclear localization of the C-terminus of PALLD and found that it is regulated by a putative nuclear export signal. These results provide the foundation for future work employing Sertoli cell- and spermatid-specific Palld-knockout mice to study diverse roles of PALLD as both a nuclear-actin regulatory protein and as a potential regulator of manchette formation during spermatogenesis.