The highly conserved NANOS2 protein: testis-specific expression and significance for the human male reproduction.

The highly conserved Nanos gene was found to encode a translational repressor necessary for germ-cell development in lower organisms. The mammalian homologue, Nanos2, was recently found to be expressed in the mouse germ cells. Since its disruption caused infertility exclusively in males, we sought to study the significance of this gene in human male reproduction. Here, we describe for the first time the expression pattern of the NANOS2 gene in human tissues and show that it is testis specific. We found that NANOS2 protein is present in prenatal germ cells and at later stages in spermatogenesis. To elucidate the role of NANOS2 in human germ-line development, we screened this gene for mutations in 214 males with isolated sterility and spermatogenic abnormalities. We identified two heterozygous variants, each in a different oligospermic patient, the second allele being the wild-type. The influence of the first variant, a missense mutation H68Q on the sterility phenotype, was not obvious since it was accompanied by a microdeletion within the AZF region of the Y chromosome. The second variant contained a silent mutation, H109H. Although both mutations were situated within the most conserved RNA-binding domain and were absent in 400 fertile males, it is not obvious that they cause male infertility.

Polymorphisms of the human PUMILIO2 gene and male sterility.

The highly conserved Pumilio protein plays crucial roles in fertility of many organisms acting as a repressor of translation, and causing infertility when mutated. Although one of two human Pumilio homologs, PUMILIO2 is expressed mainly in the germ line, its role in mammalian germ cell development has not been reported yet. To shed light on the role of PUMILIO2 in development of the human male germ line, we screened this gene for mutations in 137 patients presenting a variety of phenotypes with spermatogenic failure. The first variant, we identified was a single base substitution within intron 15 (IVS15 + 6G > A). This variant was found in three azoospermic males, the second allele being the wild type. However, this variant was also present among fertile males, as frequently as in the patients. Although location of IVS15 + 6G > A substitution in close proximity to the canonical donor splice site GT, indicates that its influence on splicing cannot be excluded, our preliminary cDNA analysis has not revealed evidence of a splicing abnormality of PUMILIO2 pre-mRNA carrying this variant. Nevertheless, this study provides new interesting variant containing a donor splice site variant, which can be relevant for understanding of splicing mechanism of mammalian genes. The second variant, c.774 C > T transversion (Y258Y) in exon 6 was found only in one patient, but an influence on PUMILIO2 function is not obvious. Altogether, this study shows that variation in the PUMILIO2 gene is very low and it seems improbable that mutations of this gene significantly contribute to male infertility in humans.

A familial X/Y translocation: cytogenetic and molecular study.

In this study we describe a 3-generation family carrying a (X;Y)(p22.3;q11.2) translocation in seven individuals of both sexes. Molecular analysis of the aberrant (X;Y)(p22.3;q11.2) chromosome was performed by FISH using X and Y-specific painting probes and also PCR amplification of the Y-specific sequences. Using these approaches it was demonstrated that the translocation resulted in a deletion of both X and Y pseudoautosomal regions. Moreover, using RBG banding it was shown that in all females the X-derivative chromosome was inactive in over 90% of mitoses. From the preliminary results obtained in this study we assumed that in this particular family the observed phenotype of the patients was caused by a deletion of the cluster of pseudoaotosomal genes responsible for the stature. More proximal loci, like STS or MRX49, were probably not deleted, since neither ichtyosis nor mental retardation was observed in this family.

[Androblastoma in a female patient with the signs of virility: a clinical-morphological and genetic study]. / Androblastoma u pacjentki z objawami wirylizacji--badanie kliniczo-morfologiczne i genetyczne.

We report a case of 24 year old patient with secondary amenorrhea, virilization and elevated serum testosterone concentration, in which cystic-solid tumor in right ovary was found. Surgical treatment was applied--adnexectomy. Histopathologic examination supported suspicion of androblastoma. After treatment regulation of menses and serum testosterone level was obtained.

A region of human chromosome 9p required for testis development contains two genes related to known sexual regulators.

Deletion of the distal short arm of chromosome 9 (9p) has been reported in a number of cases to be associated with gonadal dysgenesis and XY sex reversal, suggesting that this region contains one or more genes required in two copies for normal testis development. Recent studies have greatly narrowed the interval containing this putative autosomal testis-determining gene(s) to the distal portion of 9p24.3. We previously identified DMRT1, a human gene with sequence similarity to genes that regulate the sexual development of nematodes and insects. These genes contain a novel DNA-binding domain, which we named the DM domain. DMRT1 maps to 9p24. 3 and in adults is expressed specifically in the testis. We have investigated the possible role of DM domain genes in 9p sex reversal. We identified a second DM domain gene, DMRT2, which also maps to 9p24.3. We found that point mutations in the coding region of DMRT1 and the DM domain of DMRT2 are not frequent in XY females. We showed by fluorescence in situ hybridization analysis that both genes are deleted in the smallest reported sex-reversing 9p deletion, suggesting that gonadal dysgenesis in 9p-deleted individuals might be due to combined hemizygosity of DMRT1 and DMRT2.

Incomplete masculinisation of XX subjects carrying the SRY gene on an inactive X chromosome.

46,XX subjects carrying the testis determining SRY gene usually have a completely male phenotype. In this study, five very rare cases of SRY carrying subjects (two XX males and three XX true hermaphrodites) with various degrees of incomplete masculinisation were analysed in order to elucidate the cause of sexual ambiguity despite the presence of the SRY gene. PCR amplification of 20 Y chromosome specific sequences showed the Yp fragment to be much longer in XX males than in true hermaphrodites. FISH analysis combined with RBG banding of metaphase chromosomes of four patients showed that in all three true hermaphrodites and in one XX male the Yp fragment was translocated onto a late replicating inactive X chromosome in over 90% of their blood lymphocytes. However, in a control classical XX male with no ambiguous features, the Yp fragment (significantly shorter than in the XX male with sexual ambiguity and only slightly longer than in XX hermaphrodites) was translocated onto the active X chromosome in over 90% of cells. These studies strongly indicate that inactivation on the X chromosome spreading into a translocated Yp fragment could be the major mechanism causing a sexually ambiguous phenotype in XX (SRY+) subjects.