Gonadotropin-regulated testicular RNA helicase (GRTH/DDX25), a negative regulator of luteinizing/chorionic gonadotropin hormone-induced steroidogenesis in Leydig cells: central role of steroidogenic acute regulatory protein (StAR)

Gonadotropin-regulated testicular RNA helicase (GRTH/DDX25) is a testis-specific gonadotropin-regulated RNA helicase that is present in Leydig cells (LCs) and germ cells and is essential for spermatid development and completion of spermatogenesis. Normal basal levels of testosterone in serum and LCs were observed in GRTH null (GRTH(-/-)) mice. However, testosterone production was enhanced in LCs of GRTH(-/-) mice compared with WT mice by both in vivo and in vitro human chorionic gonadotropin stimulation. LCs of GRTH(-/-) mice had swollen mitochondria with a significantly increased cholesterol content in the inner mitochondrial membrane. Basal protein levels of SREBP2, HMG-CoA reductase, and steroidogenic acute regulatory protein (StAR; a protein that transports cholesterol to the inner mitochondrial membrane) were markedly increased in LCs of GRTH(-/-) mice compared with WT mice. Gonadotropin stimulation caused an increase in StAR mRNA levels and protein expression in GRTH(-/-) mice versus WT mice, with no further increase in SREBP2 and down-regulation of HMG-CoA reductase protein. The half-life of StAR mRNA was significantly increased in GRTH(-/-) mice. Moreover, association of StAR mRNA with GRTH protein was observed in WT mice. Human chorionic gonadotropin increased GRTH gene expression and its associated StAR protein at cytoplasmic sites. Taken together, these findings indicate that, through its negative role in StAR message stability, GRTH regulates cholesterol availability at the mitochondrial level. The finding of an inhibitory action of GRTH associated with gonadotropin-mediated steroidogenesis has provided insights into a novel negative autocrine molecular control mechanism of this helicase in the regulation of steroid production in the male.     

Structure and expression of the rat relaxin-like factor (RLF) gene.

The relaxin-like factor (RLF) is a novel member of the insulin-IGF-relaxin family of growth factors and hormones, and its mRNA is expressed very specifically in the Leydig cells of the testis and in the theca and luteal cells of the ovary. Here we report the cloning of the RLF gene and cDNA from the rat. The 0.8kb mRNA is produced from a small gene comprising two exons situated less than 1 kb downstream of the gene for the signalling factor JAK3. Northern hybridization confirms high RLF mRNA expression in the adult rat testis, and low expression in the ovary, but in no other tissues examined. Northern analysis of fetal and neonatal gonadal tissues showed that RLF mRNA is highly upregulated in the testes of day 19 embryos, but not in later neonatal stages, nor in any ovarian tissue from this period. This would indicate that RLF is a marker for the mature fetal as well as the adult-type Leydig cell, but is not expressed in premature, precursor, or dedifferentiated Leydig cells of either cell type. Finally, RNA was analysed from the testes of rats which had been treated with ethylene dimethane sulfonate (EDS), an alkylating agent that specifically destroys rat Leydig cells. RLF mRNA was absent from the acutely treated testes, but became detectable between 15 and 20 days post-treatment, concomitant with the repopulation of the testes by new Leydig cells. Continuous testosterone substitution of EDS-treated rats suppressed the production of gonadotropins, and LH-dependent Leydig cell differentiation, with the result that RLF mRNA remained undetectable throughout the study period. In conclusion, RLF is a very specific marker for the mature Leydig cell phenotype in both the adult-type and fetal Leydig cell populations of the rat testis.     

Anti-apoptotic factor humanin is expressed in the testis and prevents cell-death in leydig cells during the first wave of spermatogenesis

Humanin (HN) is a 24 amino acids peptide with potent neuro-survival properties that protects against damage associated with Alzheimer's disease. In the present report, we have demonstrated by immunohistochemical analysis and Western blotting the pattern of expression of rat humanin (HNr) in the testis of 10- to 60-day-old rats. The Leydig cells of 10- and 40- day-old rats expressed this peptide at high levels; and in the testis of 60-day-old rats the expression of HNr expanded to include Leydig, endothelial, peritubular and germ cells. As monitored by Western blotting, HNr was released into the medium of cultures of Leydig cells isolated from 10-, 40-, and 60-days-old rats. HNr stimulated the incorporation of [(3)H]TdR into DNA of Leydig cells from 10-days-old rats, in a manner that indicated promotion of cell survival rather than an increase in the rate of cell multiplication. This peptide also enhanced steroidogenesis by cultured Leydig cells from 10- to 40-day-old rats both alone and synergistically with IGF-I. The expression of HNr in cultured Leydig cells increased in response to GH and IGF-I. In summary, we demonstrated here that HNr was expressed at all stages of maturation in the rat testis. This peptide promoted the survival of Leydig cells in culture and interacted with IGF-I to stimulate DNA synthesis and steroidogenesis. We propose that HNr is a novel testicular anti-apoptotic factor.     

Detection of platelet-derived growth factor-alpha (PDGF-A) protein in cells of Leydig lineage in the postnatal rat testis

Platelet-derived growth factor-A (PDGF-A) is a locally produced growth factor in the rat testis secreted by both Sertoli cells and Leydig cells. It has been suggested that PDGF-A may be involved in modulation of testosterone production and may be essential to Leydig cell differentiation, however it is not known at what stage of differentiation PDGF-A begins to be expressed in the cells of Leydig lineage in the postnatal rat testis. Therefore, the objectives of this research were to determine at what postnatal age and in which cell type is PDGF-A first expressed in cells of the adult Leydig cell lineage, and does PDGF-A expression coincide with expression of 3beta-hydroxysteroid dehydrogenase (3beta-HSD), an indicator of steroid hormone synthesis. Male Sprague Dawley rats of postnatal day 1, 7, 9-14, 21, 28, 40, 60, and 90 were used (n=6). Animals were euthanized and their testicles removed, fixed in Bouin's solution, embedded in paraffin, and 5 micrometers sections were prepared. Immunolocalization of PDGF-A and 3beta-HSD was carried out using a peroxidase-streptavidin-biotin method. PDGF-A was first detected in cells of the Leydig cell lineage at postnatal day 10 in progenitor cells, which were surrounding the seminiferous tubules (peritubular). These cells were confirmed to be the progenitor cells and not the mesenchymal or any other spindle-shaped cells in the testis interstitium by immunolocalization of 3beta-HSD and PDGF-A in the cells in adjacent sections of testis tissue from rats of postnatal days 10-14. After postnatal day 10, PDGF-A was continued to be expressed in subsequent cells of the Leydig lineage through day 90 (adult), however, was not present in peritubular mesenchymal precursor cells of the Leydig cell lineage or any other spindle-shaped cells in the testis interstitium at any tested age. These results revealed that PDGF-A first appears in Leydig progenitor cells in the postnatal rat testis at the onset of mesenchymal cell differentiation into progenitor cells at postnatal day 10 and suggest that a functional role(s) of PDGF-A in postnatally differentiated Leydig cells in the rat testis is established at the time of the onset of postnatal Leydig stem cell differentiation. It is suggested that the significance of the first expression of PDGF-A in the Leydig progenitor cells may be associated with inducing cell proliferation and migration of this cell away from the peritubular region during Leydig cell differentiation.     

Cellular location and hormonal regulation of ghrelin expression in rat testis

Ghrelin, the endogenous ligand for the growth hormone-secretagogue receptor, is a recently cloned 28-amino acid peptide, expressed primarily in the stomach and hypothalamus, with the ability to stimulate growth hormone (GH) release and food intake. However, the possibility of additional, as yet unknown biological actions of ghrelin has been suggested. As a continuation of our recent findings on the expression and functional role of ghrelin in rat testis, we report here the pattern of cellular expression of ghrelin peptide in rat testis during postnatal development and after selective Leydig cell elimination, and we assess hormonal regulation of testicular ghrelin expression, at the mRNA and/or protein levels, in different experimental models. Immunohistochemical analyses along postnatal development demonstrated selective location of ghrelin peptide within rat testis in mature fetal- and adult-type Leydig cells. In good agreement, ghrelin protein appeared undetectable in testicular interstitium after selective Leydig cell withdrawal. In terms of hormonal regulation, testicular ghrelin mRNA and protein expression decreased to negligible levels after long-term hypophysectomy, whereas replacement with human chorionic gonadotropin (CG) (as superagonist of LH) partially restored ghrelin mRNA and peptide expression. Furthermore, acute administration of human CG (25 IU) to intact rats resulted in a transient increase in testicular ghrelin mRNA levels, with peak values 4 h after injection, an effect that was not mimicked by FSH (12.5 IU/rat). In contrast, testicular expression of ghrelin mRNA remained unaltered in GH-deficient rats, under hyper- and hypothyroidism conditions, as well as in adrenalectomized animals. In conclusion, our results demonstrate that mature Leydig cells are the source of ghrelin expression in rat testis, the protein being expressed in both fetal- and adult-type Leydig cells. In addition, our data indicate that testicular expression of ghrelin is hormonally regulated and is at least partially dependent on pituitary LH.     

Tissue-cell- and species-specific expression of gonadotropin-regulated long chain acyl-CoA synthetase (GR-LACS) in gonads, adrenal and brain. Identification of novel forms in the brain

Gonadotropin-regulated long chain acyl-CoA synthetase (GR-LACS) is a novel hormonally regulated fatty acyl-CoA synthetase (FACS) with activity for long-chain fatty acids. The presence of this enzyme in the Leydig cells of the mature rat testis and its mode of regulation suggest that it participates in testicular steroidogenesis. This study demonstrates that GR-LACS expression is tissue, cell and species-specific. The 79 kDa GR-LACS protein is expressed in rodent gonads and brain, and only in the mouse in the adrenal cortex. In the ovary of both species it is associated with follicles undergoing atresia. It is present in the newborn and immature testis tubules and after puberty only in the Leydig cells. A distinct GR-LACS protein species of 64 kDa that was more abundant than the 79 kDa long form was found in the rat brain. Also, a minor 73 kDa form was observed in the rat brain and mouse ovary. Two novel species resulting from alternatively splicing of the GR-LACS gene were identified in a rat brain cDNA library: a short form 1 (S1) lacking exon 8 and short form 2 (S2) lacking exons 6–8. Expression studies revealed that the sizes of the S1/S2 proteins are comparable to those of the endogenous variant species. Neither S form contains FACSs activity, suggesting that exon 8 is essential for the enzymatic function. GR-LACS variants exhibit small but significant dominant negative effects on the FACS activity of the long form. GR-LACS variants may regulate the long form's activity in the brain.     

A Transcriptome-Wide Screen for mRNAs Enriched in Fetal Leydig Cells: CRHR1 Agonism Stimulates Rat and Mouse Fetal Testis Steroidogenesis

Fetal testis steroidogenesis plays an important role in the reproductive development of the male fetus. While regulators of certain aspects of steroidogenesis are known, the initial driver of steroidogenesis in the human and rodent fetal testis is unclear. Through comparative analysis of rodent fetal testis microarray datasets, 54 candidate fetal Leydig cell-specific genes were identified. Fetal mouse testis interstitial expression of a subset of these genes with unknown expression (Crhr1, Gramd1b, Itih5, Vgll3, and Vsnl1) was verified by whole-mount in situ hybridization. Among the candidate fetal Leydig cell-specific factors, three receptors (CRHR1, PRLR, and PROKR2) were tested for a steroidogenic function using ex vivo fetal testes treated with receptor agonists (CRH, PRL, and PROK2). While PRL and PROK2 had no effect, CRH, at low (approximately 1 to 10) nM concentration, increased expression of the steroidogenic genes Cyp11a1, Cyp17a1, Scarb1, and Star in GD15 mouse and GD17 rat testes, and in conjunction, testosterone production was increased. Exposure of GD15 fetal mouse testis to a specific CRHR1 antagonist blunted the CRH-induced steroidogenic gene expression and testosterone responses. Similar to ex vivo rodent fetal testes, ≥10 nM CRH exposure of MA-10 Leydig cells increased steroidogenic pathway mRNA and progesterone levels, showing CRH can enhance steroidogenesis by directly targeting Leydig cells. Crh mRNA expression was observed in rodent fetal hypothalamus, and CRH peptide was detected in rodent amniotic fluid. Together, these data provide a resource for discovering factors controlling fetal Leydig cell biology and suggest that CRHR1 activation by CRH stimulates rat and mouse fetal Leydig cell steroidogenesis in vivo.