Expression of the relaxin-like factor (RLF) was studied at the messenger RNA (mRNA) and protein levels in the testes and ovaries of the mouse, as well as through testicular development and differentiation in the mouse testis. In situ hybridization or RT-PCR, and immunohistochemistry using a polyclonal antibody raised against a recombinant protein, provided mutually confirmatory results for a high expression of RLF in the Leydig cells of the adult testis and at a much lower level of expression in the luteal cells of the ovary through the cycle, pregnancy, and in lactation. Analysis of protein and mRNA expression, through postnatal testicular development, indicated moderate RLF expression also in the fetal population of Leydig cells, even in the hpg mutant mouse, lacking an active pituitary-gonadal axis. Prepubertal Leydig cells, however, exhibit only very low-level RLF gene expression, this phenotype persisting in the adult hpg mouse. In summary, fetal Leydig cells express RLF in an LH/human CG-independent fashion, whereas LH/human CG is essential to induce RLF expression in the adult-type Leydig cell. In cultured adult Leydig cells or in the mouse tumor MA-10 cell line, RLF mRNA is expressed in a constitutive fashion. RLF thus seems to be a useful marker of Leydig cell differentiation status.
The new peptide hormone insulin-like peptide 3 (INSL3) is a member of the insulin-relaxin family, yet, unlike insulin, it signals through a new G-protein coupled receptor, LGR8, distantly related to the receptors for LH and FSH. INSL3 is produced in large amounts by the Leydig cells of the testis in both fetal and adult mammals. Using a combination of mRNA analysis by RT-PCR, immunohistochemistry, ligand-binding, and/or bioactivity assays, the distribution of LGR8 expression was assessed in testicular tissues and cells and in the epididymis. There was consistent agreement that LGR8 was expressed in meiotic and particularly postmeiotic germ cells and in Leydig cells, though not in Sertoli or peritubular cells. Leydig cells appear to express only a low level of the LGR8 gene product; other transcripts may be present, representing nonfunctional products. Messenger RNA analysis suggested that LGR8 transcripts in germ cells represented mostly full-length forms. LGR8 mRNA was also expressed in the epididymis, though no function can yet be ascribed to this expression. Therefore, the INSL3/LGR8 system represents a further paracrine hormone-receptor system in the testis, which conveys information about Leydig cell status to germ cells, and possibly as part of an autocrine feedback loop.
Relaxin-like factor (RLF) is a new member of the insulin/insulin-like growth factor family of hormones and growth factors, which appears to be predominantly expressed in the Leydig cells of the testis. An analysis of male and female bovine tissues indicated that in the cow the RLF gene is also highly expressed in the female, mainly in the follicular theca interna and in the corpus luteum, with a pattern of gene expression very similar to that for the related peptide relaxin in other species. Sequence analysis of bovine testicular and luteal RLF and cDNA shows that the same gene is expressed in both male and female gonads. Because the bovine RLF sequence, like those from pigs, humans, and mice, retains, the putative receptor binding motif described for relaxin, it seems plausible that RLF might functionally substitute for relaxin in the cow, in which the latter peptide appears not to be significantly expressed.
The complete protein-coding region of the human relaxin-like factor (RLF; formerly Ley-I-L) was cloned by reverse transcription-polymerase chain reaction from human testis and subcloned into a bacterial expression plasmid for the production of recombinant human RLF in Escherichia coli. Polyclonal antibodies were raised against the recombinant RLF, as well as against a peptide epitope from the B-domain of the RLF polypeptide. Antibodies were used for immunohistochemistry of Bouin-fixed, paraffin-embedded samples of human testis tissues. Specific immunoreactivity was located exclusively in the Leydig cells with a consistent high intensity of staining, showing similar spatial distribution to other Leydig cell markers, such as the luteinizing hormone (LH) receptor and 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD), and to the pattern of RLF mRNA shown by in-situ transcript hybridization. In biopsy samples from patients with severe disturbances of spermatogenesis, RLF staining intensity was consistently high in all cases, unlike staining for 3 beta-HSD which varied considerably between patients. Immunostaining for RLF would thus appear to offer an interesting new marker for Leydig cells in human testis samples.
A novel profilin, named profilin IV, was cloned and characterized as a testicular isoform, distinct from the previously described testis-specific profilin III. Profilin IV showed only 30% amino acid identity with the other mammalian profilins; nevertheless, database searches produced significant alignments with the conserved profilin domain. Northern blot analysis and in situ transcript hybridization suggested that profilin IV, like profilin III, is transcribed in the germ cells. However, the timing of their expression during post-natal development of rat testis and in the rat spermatogenetic cycle was distinct. In the human testis, profilin IV mRNA expression correlates with the presence of germ cells suggesting that it may be a suitable molecular diagnostic parameter to supplement conventional histopathological diagnostics in the assessment of testicular biopsies. The predicted profilin IV protein was verified employing an anti-oligopeptide antibody. Western blot analysis detected an immunorelated testicular protein of approximately 14 kDa. Immunohistochemistry revealed an intracellular protein of the rat, the mouse and the human testis accumulating asymmetrically in the cytoplasm of round and elongating spermatids with its perinuclear location coinciding with the position of the developing acrosome-acroplaxome and the manchette. Profilin IV thus may regulate testicular actin cytoskeleton dynamics and play a role in acrosome generation and spermatid nuclear shaping.
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