Activin A balances Sertoli and germ cell proliferation in the fetal mouse testis.

Activin affects many aspects of cellular development, including those essential for reproductive fitness. This study examined the contribution of activin A to murine fetal testicular development, revealing contrasting outcomes of activin actions on Sertoli cells and gonocytes. Shortly after sex determination, from Embryonic Day 12.5 (E12.5) through to birth (0 dpp), the activin A subunit transcript (Inhba) level rises in testis but not ovary, followed closely by the Inha transcript (encoding the inhibitory inhibin alpha subunit). Activin receptor transcript levels also change, with Acvr1 (encoding ALK2) and Acvr2b (ActRIIB) significantly higher and lower, respectively, at 0 dpp compared with E13.5 and E15.5. Transcripts encoding the signaling mediators Smad1, Smad3, and Smad4 were higher at 0 dpp compared with E13.5 and E15.5, whereas Smad2, Smad5, and Smad7 were lower. Detection of phosphorylated (P-)SMAD2/3 in nearly all testis cell nuclei indicated widespread transforming growth factor beta (TGFB) and/or activin ligand signaling activity. In contrast to wild-type littermates, activin betaA subunit knockout (Inhba(-/-)) mice have significantly smaller testes at birth, attributable to a 50% lower Sertoli cell number and decreased Sertoli cell proliferation from E13.5. Inhba(-/-) testes contained twice the normal gonocyte number at birth, with some appearing to bypass quiescence. Persistence of widespread P-SMAD2/3 in Inhba(-/-) cells indicates other TGFB superfamily ligands are active in fetal testes. Significant differences in Smad and cell cycle regulator transcript levels correlating to Inhba gene dosage correspond to differences in Sertoli and germ cell numbers. In Inhba(-/-) testes, Cdkn1a (encoding p21(cip1)), identified previously in fetal gonocytes, was lower at E13.5, whereas Cdkn1b (encoding p(27kip1) in somatic cells) was lower at birth, and cyclin D2 mRNA and protein were lower at E15.5 and 0 dpp. Thus, activin A dosage contributes to establishing the balance between Sertoli and germ cell number that is ultimately required for adult male fertility.

Activin bioactivity affects germ cell differentiation in the postnatal mouse testis in vivo.

The transforming growth factor beta superfamily ligand activin A controls juvenile testis growth by stimulating Sertoli cell proliferation. Testicular levels are highest in the first postnatal week, when Sertoli cells are proliferating and spermatogonial stem cells first form. Levels decrease sharply as Sertoli cell proliferation ceases and spermatogenic differentiation begins. We hypothesized that changing activin levels also affect germ cell maturation. We detected an acute and developmentally regulated impact of activin on Kit mRNA in cocultures of Sertoli cells and germ cells from Day 8, but not Day 4, mice. Both stereological and flow cytometry analyses identified an elevated spermatogonium:Sertoli cell ratio in Day 7 testes from Inhba(BK/BK) mice, which have decreased bioactive activin, and the germ cell markers Sycp3, Dazl, and Ccnd3 were significantly elevated in Inhba(BK/BK) mice. The flow cytometry measurements demonstrated that surface KIT protein is significantly higher in Day 7 Inhba(BK/BK) germ cells than in wild-type littermates. By Day 14, the germ cell:Sertoli cell ratio did not differ between genotypes, but the transition of type A spermatogonia into spermatocytes was altered in Inhba(BK/BK) testes. We conclude that regulated activin signaling not only controls Sertoli cell proliferation, as previously described, but also influences the in vivo progression of germ cell maturation in the juvenile testis at the onset of spermatogenesis.

All in the family: TGF-beta family action in testis development.

To achieve and maintain fertility, the adult mammalian testis produces many generations of sperm. While testicular integrity is established in the fetus and develops further in juvenile life, sperm production does not ensue until much later in life, following the onset of puberty. Signals from the transforming growth factor-beta superfamily of proteins are vital for governance of testis development and spermatogenesis, and this review discusses our current understanding of the mechanisms and processes in which they have been implicated with a focus on the fetal and juvenile testis.

Expression of c-Kit receptor mRNA and protein in the developing, adult and irradiated rodent testis.

Germ cell proliferation, migration and survival during all stages of spermatogenesis are affected by stem cell factor signalling through the c-Kit receptor, the expression and function of which are vital for normal male reproductive function. The present study comprehensively describes the c-Kit mRNA and protein cellular expression profiles in germ cells of the postnatal and adult rodent testis, revealing their significant elevation in synthesis at the onset of spermatogenesis. Real-time PCR analysis for both mice and rats matched the cellular mRNA expression profile where examined. Localization studies in normal mouse testes indicated that both c-Kit mRNA and protein are first detectable in differentiating spermatogonia. In addition, all spermatogonia isolated from 8-day-old mice displayed detectable c-Kit mRNA, but 30-50% of these lacked protein expression. The c-Kit mRNA and protein profile in normal rat testes indicated expression in gonocytes, in addition to differentiating spermatogonia. However, in the irradiated adult rat testes, in which undifferentiated spermatogonia are the only germ cell type, mRNA was also detected in the absence of protein. This persisted at 3 days and 1 and 2 weeks following treatment with gonadotrophin-releasing hormone (GnRH) antagonist to stimulate spermatogenesis recovery. By 4 weeks of GnRH antagonist treatment, accompanying the emergence of differentiating spermatogonia, both mRNA and protein were detected. Based on these observations, we propose that c-Kit mRNA and protein synthesis are regulated separately, possibly by influences linked to testis maturation and circulating hormone levels.