Gonadotropin-regulated Testicular Helicase Research Articles

GRTH: A Key to Understanding Androgen-Mediated Germ Cell Signaling

GRTH: A Key to Understanding Androgen-Mediated Germ Cell Signaling

Endocrine Regulation of Male Fertility by the Skeleton

Interactions between bone and the reproductive system have until now been thought to be limited to the regulation of bone remodeling by the gonads. We now show that, in males, bone acts as a regulator of fertility. Using coculture assays, we demonstrate that osteoblasts are able to induce testosterone production by the testes, though they fail to influence estrogen production by the ovaries. Analyses of cell-specific loss- and gain-of-function models reveal that the osteoblast-derived hormone osteocalcin performs this endocrine function. By binding to a G protein-coupled receptor expressed in the Leydig cells of the testes, osteocalcin regulates in a CREB-dependent manner the expression of enzymes that is required for testosterone synthesis, promoting germ cell survival. This study expands the physiological repertoire of osteocalcin and provides the first evidence that the skeleton is an endocrine regulator of reproduction.

Differences in gonadotropin-regulated testicular helicase (GRTH/DDX25) single nucleotide polymorphism between Japanese and Chinese populations

Differences in gonadotropin-regulated testicular helicase (GRTH/DDX25) single nucleotide polymorphism between Japanese and Chinese populations

Gonadotropin-regulated Testicular Helicase (DDX25), an Essential Regulator of Spermatogenesis, Prevents Testicular Germ Cell Apoptosis

Gonadotropin-regulated testicular helicase (GRTH)/DDX25 is an essential post-transcriptional regulator of spermatogenesis. In GRTH null mice severe apoptosis was observed in spermatocytes entering the metaphase of meiosis. Pro- and anti-apoptotic factors were found to be under GRTH regulation in comparative studies of spermatocytes from wild type and GRTH(-/-) knock-out (KO) mice. KO mice displayed decreased levels of Bcl-2 and Bcl-xL (anti-apoptotic factors), an increase in Bid, Bak, and Bad (pro-apoptotic), reduced phospho-Bad, and release of cytochrome c. Also, an increase on Smac, a competitor of inhibitor apoptotic proteins that release caspases, was observed. These changes caused an increase in cleavage of caspases 9 and 3, activation of caspase 3 and increases in cleavage products of PARP. The half-life of caspase 3 transcripts was markedly increased in KO, indicating that GRTH had a negative role on its mRNA stability. IkappaBalpha, which sequesters NF-kappaB from its transcriptional activation of pro-apoptotic genes, was highly elevated in KO, and its phospho-form, which promotes its dissociation, was reduced. The increase of HDAC1 and abolition of p300 expression in KO indicated a nuclear action of GRTH on the NF-kappaB-mediated transcription of anti-apoptotic genes. It also regulates the associated death domain pathway and caspase 8-mediated events. GRTH-mediated apoptotic regulation was further indicated by its selective binding to pro- and anti-apoptotic mRNAs. These studies have demonstrated that GRTH, as a component of mRNP particles, acts as a negative regulator of the tumor necrosis factor receptor 1 and caspase pathways and promotes NF-kappaB function to control apoptosis in spermatocytes of adult mice.

Regulation of steroidogenic enzymes and a novel testicular RNA helicase

Luteinizing hormone (LH) supports steroidogenesis and maintains testicular and ovarian function. Mediators of LH action exert homologous regulation of membrane receptors, steroidogenic enzymes and other regulatable genes of the Leydig cell (LC). Androgen and estrogen induced by LH could act through its cognate receptors in the LC to regulate gene expression. Although androgens are unquestionable essential for spermatogenesis and presumably exert their heterologous action through androgen receptors present in the Sertoli its regulatory mechanism in germinal cell maturation is far from clear. In contrast to physiological concentrations of gonadotropins which maintain the steroidogenic functions and LH and prolactin receptors in the gonads, high concentrations of gonadotropin (hCG) cause receptor down-regulation and desensitization of steroidogenic enzymes of the LCs in vivo (3β-hydroxysteroid dehydrogenase types I and II, 17α-hydroxylase/17,20 lyase, and 17β-hydroxysteroid dehydrogenase type III [17β-HSD]). In addition, 17β-HSD is regulated by compartmentalized endogenous glucose/ATP. The attenuation of steroidogenesis which results from receptor mediated activation by cognate hormone, but is independent of the subsequent phase of receptor down-regulation, is due to changes at the transcriptional level. Among the candidates affecting this regulation are active steroid metabolites (direct or indirect of steroids and other mediator(s) i.e. cAMP, putative transcription factors induced by LH action). Differential display assay revealed another gene which is transcriptionally regulated by gonadotropin termed GRTH (Gonadotropin Regulated Testicular Helicase). GRTH is a novel member of the DEAD-box family of RNA helicases, and is specifically expressed in LCs and meiotic LC of the testis. It is markedly up-regulated by hCG via cAMP-induced androgen formation in LCs at doses that cause down-regulation of receptors and steroidogenic enzymes. GRTH functions as a translational activator. Androgen produced by gonadotropin stimulation exerts intracrine/autocrine actions on GRTH, and also could influence transcription within the seminiferous tubule. GRTH may contribute to the control of steroidogenesis, including the restoration of down regulated cellular functions, and in the paracrine regulation of androgen dependent gene(s) involved in the meiotic process, and could thus have a crucial role in spermatogenesis.