Expression of the X-inactivation-associated gene XIST during spermatogenesis.

Mammalian X-chromosome inactivation is thought to be controlled by the X inactivation centre (XIC, X-controlling element -Xce-in mice). A human gene, XIST and its mouse counterpart, Xist, which map to the XIC/Xce, are expressed exclusively from inactive X chromosomes, suggesting their involvement in the process of X-inactivation. We now report the presence of Xist/XIST transcripts in newborn and adult mouse testes, and in human testicular tissue with normal spermatogenesis, but not in the testes of patients who lack germ cells. Our results indicate that while the X chromosome in males is active in somatic cells, it undergoes inactivation during spermatogenesis.

Cloning and expression of the mouse pseudoautosomal steroid sulphatase gene (Sts).

Steroid sulphatase (STS) is an important enzyme in steroid metabolism. The human STS gene has been cloned and mapped to Xp22.3, proximal to the pseudoautosomal region (PAR). Using quantitative differences in STS activity among various mouse strains, a segregation pattern consistent with autosomal linkage was first reported, but more recent studies have linked Sts to the mouse PAR. Failed attempts to clone the mouse Sts gene using human reagants (STS cDNA and anti-STS antibodies) suggest a substantial divergence between these genes. However, partial amino-terminal sequence from purified rat liver Sts is very similar to its human counterpart, and several domains are conserved among all the sulphatases. We followed a degenerate-primer reverse transcriptase-PCR (RT-PCR) approach to amplify a conserved fragment of the rat Sts cDNA that was then used to clone the mouse Sts cDNA. This 2.3-kb cDNA revealed 75% similarity with rat Sts cDNA, while it was only 63% similar to human STS cDNA. Transfection of STS(-) A9 cells with the mouse Sts cDNA restored STS enzymatic activity. Sts was also mapped physically to the distal end of the mouse sex chromosomes, and our backcross studies placed Sts distal to the 'obligatory' cross-over in male meiosis.

The murine Xe169 gene escapes X-inactivation like its human homologue.

Among a number of genes that escape X-chromosome inactivation in humans, three have been evaluated in mice and unexpectedly all three are subject to X-inactivation. We report here the cloning and expression studies of a novel mouse gene, Xe169, and show that it escapes X-inactivation like its human homologue. Xe169 was assigned to band F2/F3 on the mouse X chromosome by fluorescent in situ hybridization and Southern analysis indicates that the gene is located outside the pseudoautosomal region. Homologous, but divergent, sequences exist on the Y chromosome. In vitro and in vivo studies show that Xe169 is expressed from both the active and the inactive X chromosomes. Xe169 is the first cloned non-pseudoautosomal gene that escapes X-inactivation in mice.

Localization of ubiquitin specific protease 26 at blood-testis barrier and near Sertoli cell-germ cell interface in mouse testes.

Ubiquitin Specific Protease 26 (USP26) is a little studied ubiquitin-specific protease that is expressed specifically in the testis. In humans, some USP26 polymorphisms have been reported to be associated with impaired male fertility. However, how USP26 affects male reproduction remains unclear. We generated an antibody that stained specifically cultured cells expressing an epitope-tagged USP26 and used it to elucidate the biological function of USP26. Immunostaining of mouse testis sections as well as dispersed germ cells showed the presence of USP26 at the blood-testis barrier, near the Sertoli cell-germ cell interface of post-step 7 spermatids, and coating the dorsal surface of sperm head. Further RT-PCR assays detected the expression of Usp26 in germ cells, but not in primary Sertoli cell lines. In addition, USP26 immunoprecipitated from testis lysates exhibited deubiquitinating activities. The localization of USP26 in the testis suggests a possible role in the movement of germ cells along the seminiferous epithelium.

XXY male mice: an experimental model for Klinefelter syndrome.

Klinefelter syndrome (47,XXY) is the most common sex chromosome aneuploidy in men. Thus, it is important to establish an experimental animal model to explore its underlying molecular mechanisms. Mice with a 41,XXY karyotype were produced by mating wild-type male mice with chimeric female mice carrying male embryonic stem cells. The objectives of the present study were to characterize the testicular phenotype of adult XXY mice and to examine the ontogeny of loss of germ cells in juvenile XXY mice. In the first experiment the testicular phenotypes of four adult XXY mice and four littermate controls (40,XY) were studied. XXY mice were identified by either Southern hybridization or karyotyping and were further confirmed by fluorescence in situ hybridization. The results showed that the testis weights of adult XXY mice (0.02 +/- 0.01 g) were dramatically decreased compared with those of the controls (0.11 +/- 0.01 g). Although no significant differences were apparent in plasma testosterone levels, the mean plasma LH and FSH levels were elevated in adult XXY mice compared with controls. The testicular histology of adult XXY mice showed small seminiferous tubules with varying degrees of intraepithelial vacuolization and a complete absence of germ cells. Hypertrophy and hyperplasia of Leydig cells were observed in the interstitium. Electron microscopic examination showed Sertoli cells containing scanty amounts of cytoplasm and irregular nuclei with prominent nucleoli. The junctional region between Sertoli cells appeared normal. In some tubules, nests of apparently degenerating Sertoli cells were found. In the second experiment the ontogeny of germ cell loss in juvenile XXY mice and their littermate controls was studied. Spermatogonia were found and appeared to be morphologically normal in juvenile XXY mice. Progressive loss of germ cells occurred within 10 days after birth. This resulted in the absence of germ cells in the adult XXY mice. We conclude that a progressive loss of germ cells occurring in early postnatal life results in the complete absence of germ cells in adult XXY mice. The XXY mouse provides an experimental model for its human XXY counterpart, Klinefelter syndrome.

Steroid sulfatase expression in human placenta: immunocytochemistry and in situ hybridization study.

Steroid sulfatase (STS), an important enzyme in the pathway of estrogen synthesis from sulfated steroid precursors, was localized to the syncytial trophoblast of human placentas during different periods of pregnancy by using a mouse monoclonal antibody and immunocytochemical techniques. Preembedding immunoelectron microscopy revealed STS immunoreactivity associated with the rough endoplasmic reticulum of the syncytial trophoblast. STS mRNA was also localized to this outermost layer of the human trophoblast. At a cellular level, both STS message and immunoreactivity seemed to be more abundant during the late first and early second trimesters than in term placentas. Although the syncytial trophoblast is known to originate from the cytotrophoblast, neither STS immunoreactivity nor STS mRNA was detected in the cytotrophoblast at any stage of placental development studied.

Male infertility caused by a de novo partial deletion of the DAZ cluster on the Y chromosome.

Deletions in distal Yq interval 6 represent the cause of 10-15% of idiopathic severe male infertility and map to a region defined AZFc (azoospermia factor c). The testis-specific gene DAZ is considered a major AZFc candidate, and its deletion has been associated with a severe disruption in spermatogenesis. However, DAZ is actually a multicopy gene family consisting of seven clustered copies spanning about 1 megabase. Only deletions removing the entire DAZ gene cluster together with other genes have been reported in infertile males. Because no case of spermatogenic failure has been traced to intragenic deletions, point mutations, or even deletions not involving all the DAZ copies, the definitive proof for a requirement of DAZ for spermatogenesis is still debatable. Here we report the first case of a partial deletion of the DAZ cluster removing all but one of the copies. This deletion is present in a patient affected with severe oligozoospermia who had a testicular phenotype characterized by a great quantitative reduction of germ cells (severe hypospermatogenesis). The absence of this deletion in the fertile brother of the patient suggests that this de novo mutation indeed caused the spermatogenic failure.

Characterization of the mouse Dazap1 gene encoding an RNA-binding protein that interacts with infertility factors DAZ and DAZL.

BACKGROUND: DAZAP1 (DAZ Associated Protein 1) was originally identified by a yeast two-hybrid system through its interaction with a putative male infertility factor, DAZ (Deleted in Azoospermia). In vitro, DAZAP1 interacts with both the Y chromosome-encoded DAZ and an autosome-encoded DAZ-like protein, DAZL. DAZAP1 contains two RNA-binding domains (RBDs) and a proline-rich C-terminal portion, and is expressed most abundantly in the testis. To understand the biological function of DAZAP1 and the significance of its interaction with DAZ and DAZL, we isolated and characterized the mouse Dazap1 gene, and studied its expression and the subcellular localization of its protein product. RESULTS: The human and mouse genes have similar genomic structures and map to syntenic chromosomal regions. The mouse and human DAZAP1 proteins share 98% identity and their sequences are highly similar to the Xenopus orthologue Prrp, especially in the RBDs. Dazap1 is expressed throughout testis development. Western blot detects a single 45 kD DAZAP1 protein that is most abundant in the testis. Although a majority of DAZAP1 is present in the cytoplasmic fraction, they are not associated with polyribosomes. CONCLUSIONS: DAZAP1 is evolutionarily highly conserved. Its predominant expression in testes suggests a role in spermatogenesis. Its subcellular localization indicates that it is not directly involved in mRNA translation.

Prenatal in situ hybridization test for deleted steroid sulfatase gene.

X-linked ichthyosis results from steroid sulfatase (STS) deficiency; 90% of affected patients have a complete deletion of the entire 146 kb STS gene on the distal X chromosome short arm (Xp22.3). In these families prenatal diagnosis and carrier testing can be completed in 2 days by hybridizing simultaneously 2 different cosmid probes labeled with fluorescein or Texas red and counterstaining interphase nuclear DNA with DAPI. An STS gene probe labeled with Texas red hybridizes specifically to the steroid sulfatase gene on the X chromosome. A second flanking probe labeled with fluorescein hybridizes to both the normal Y chromosome and normal and STS deleted X chromosomes. In this fashion the interphase nuclei of normal males, affected males, normal females, and carrier females can be distinguished unambiguously. Because normal males and carrier females each show two yellow-green fluorescein spots and one Texas red STS spot, use of this test prenatally requires determining fetal sex independently with repetitive X and Y chromosome-specific probes. This procedure can be used with lymphocytes, direct and cultured chorionic villus cells, direct and cultured amniocytes, and fibroblasts. Similar methods are anticipated to be useful for rapid diagnostic assessment of other aneuploid gene disorders.

Genetics of spermatogenic failure.

Spermatogenesis is an ongoing developmental process in adult testes that requires the coordinated expression of many genes. The genetic causes of spermatogenic failure in men remain largely unknown, though abnormalities in the sex chromosomes constitute a significant portion of them. In this review, we focus on 3 disorders that involve the sex chromosomes and are often screened in infertility clinics. These are Klinefelter syndrome, Y chromosome microdeletion, and XX male syndrome. We describe their prevalence, the associated phenotypes, and the molecular mechanisms underlying the disorders and discuss the difficulties in identifying the causal genes contributing to the spermatogenic defects. Currently, there are no effective therapies for the spermatogenic failure in the patients, and conception through assisted reproductive technology bears the risk of passing genetic abnormalities to the next generation.

A long-range restriction map of deletion interval 6 of the human Y chromosome: a region frequently deleted in azoospermic males.

Deletion interval 6 (DI6) of the human Y chromosome, located at the distal end of the long arm euchromatic region, is required for normal spermatogenesis. About 10% of males with idiopathic azoospermia or oligospermia have microdeletions in this region. Six gene families, including RBMY (RNA binding motif, Y chromosome), DAZ (deleted in azoospermia), and four recently isolated genes, have been mapped to this interval. Genes from all of these families show testis-specific expression and are thus candidates for azoospermic factor (AZF). DI6 is also rich in Y-specific repetitive sequences, which may be responsible for its frequent deletion. To understand the sequence organization of this region, a 5-Mb restriction map was constructed based on YAC clones and was partially verified on genomic DNA. The locations of five gene family members, as well as numerous STSs, were determined. The map shows several inverted and direct repeats several hundred kilobases in size. The restriction map of DI6 will facilitate future mapping of deletion breakpoints in infertile males and elucidation of mechanisms behind frequent deletions.

Advances in Y chromosome mapping.

The human Y chromosome has long been recognized as being responsible for sex determination. In fact, it also encodes more than 30 genes and gene families that participate in a variety of cellular functions, including bone development, tooth growth, and spermatogenesis. De-novo deletion of Y chromosome segments that contain spermatogenesis genes occurs frequently, resulting in low sperm production and male infertility. This article reviews our current knowledge of the structure and function of the Y chromosome is reviewed.

The gross anatomy of a tRNA gene cluster at region 42A of the D. melanogaster chromosome.

The sequence organization and positions of the tRNA genes in a tRNA gene cluster at chromosomal region 42A of the D. melanogaster (Dm) genome have been studied by recombinant DNA methods. A set of overlapping inserts of Dm DNA cloned in a lambdoid vector and extending in both directions from the Drosophila tRNA gene-bearing fragment of plasmid pCIT12 has been isolated by the procedure of "chromosomal walking." The isolated region has a total length of 94 kb of which a central 46 kb region contains eight tRNAAsn genes, four tRNA2Arg genes, five tRNA2Lys genes and one tRNAIle gene. The genes are irregularly spaced and transcribed from both strands; they occur to some extent in subclusters. Thus this sequence organization is totally different from the tandem repeat organizaiton seen in many 5S rRNA gene clusters of higher eucaryotes and in one Xenopus rRNA gene clusters of higher eucaryotes and in one Xenopus tRNA gene cluster.

Isolation of a new gene GS2 (DXS1283E) from a CpG island between STS and KAL1 on Xp22.3.

A gene, GS2 (DXS1283E), was isolated from a CpG island located approximately midway between the steroid sulfatase (STS) and the Kallmann syndrome (KAL1) loci on the distal short arm of the human X chromosome. DNA sequencing of a GS2 cDNA clone revealed an open reading frame for a basic protein of 253 amino acid residues. A polymorphic CT dinucleotide repeat was found in the 3' untranslated region. The GS2 gene is expressed in all human tissues examined, including heart, brain, placenta, lung, liver, muscle, kidney, pancreas, and spleen. Several GS2 transcripts, ranging in size from 1.1 to 5.8 kb, were found among different tissues, suggesting tissue-specific processing of the GS2 transcript. Characterization of GS2 genomic clones revealed that the gene consists of 7 exons spanning over 26 kb, with a CpG island located in the first intron. The GS2 gene is transcribed toward Xpter, in the same direction as KAL1 but opposite to that of STS.

Stability of DNA methylation of the human hypoxanthine phosphoribosyltransferase gene.

Methylation sensitive restriction enzymes were used to evaluate the methylation level of several restriction sites near human hypoxanthine phosphoribosyltransferase (HPRT) genes on active and inactive X chromosomes. DNA samples from leukocytes, from clonally derived fibroblasts, and from independent mouse-human hybrid lines isolated from the fusion of A-9 cells and these clonally derived human cells were studied. Comparison of the methylation patterns shows that restriction sites may show variable or constant methylation among tissues and clones, and heritability of methylation is also different among restriction sites. Methylation is more stable at sites whose methylation status correlate well with HPRT activity. Our results suggest that the methylation of certain cytosine residues may critically affect gene activity and that the methylation pattern of these sites is stably inherited.

Fibre-fluorescence in situ hybridization unravels apparently seven DAZ genes or pseudogenes clustered within a Y-chromosome region frequently deleted in azoospermic males.

Using the technique of 'fibre-FISH' (fluorescence in situ hybridization), we describe the direct visualization of seven longer DAZ signal stretches and in addition a maximum of four isolated single DAZ signals on Y-chromatin fibres of four different individuals. These seven longer DAZ signal stretches may represent seven DAZ genes or pseudogenes, whereas the single DAZ signals may represent truncated DAZ genes.

The human autosomal gene DAZLA: testis specificity and a candidate for male infertility.

The DAZ (Deleted in AZoospermia) and DAZLA (DAZ-like autosomal) genes may be determinants of male infertility. The DAZ gene on the long arm of the human Y chromosome is a strong candidate for the 'azoospermia factor' (AZF). Its role in spermatogenesis is supported by its exclusive expression in testis, its deletion in a high percentage of males with azoospermia or severe oligospermia, and its homology with a Drosophila male infertility gene boule. No DAZ homologous sequences have been found on the mouse Y chromosome. Instead, a Dazla gene was isolated from mouse chromosome 17 and has been considered to be a murine homologue of DAZ. However, the homology between human DAZ and mouse Dazla is not strong, and Dazla contains only one of the seven DAZ repeats found in DAZ. We report the isolation of the human DAZLA gene by screening a human testis cDNA library with a DAZ cDNA clone. DAZLA encodes only one DAZ repeat and shares high homology with the mouse Dazla, indicating that these two genes are homologues. Using a panel of rodent-human somatic cell lines and fluorescence in situ hybridization, the DAZLA gene was mapped to 3p24, a region not known to share homology with mouse chromosome 17. The DAZLA gene may be involved in some familial cases of autosomal recessive male infertility.

Multiple functional copies of the RBM gene family, a spermatogenesis candidate on the human Y chromosome.

The RBM (RNA-binding motif) gene family on the human Y chromosome encodes proteins with an RNA-binding domain. Its exclusive expression in germ cells and its partial deletion in some azoospermic or severely oligospermic males provide evidence of a role for RBM genes in spermatogenesis. There are approximately 30 RBM genes, found on both arms of the Y chromosome. Two RBM cDNA clones with slightly different sequences have been reported. To investigate the number of functional genes, we studied RBM expression by use of RT-PCR of RBM transcripts and by characterizing numerous RBM cDNA clones. A total of 27 RT-PCR and 19 cDNA clones were sequenced. Whereas the RT-PCR clones pointed to the existence of at least six RBM subfamilies (RBMI to RBMVI), the cDNA clones indicated that only RBMI is actively transcribed and encodes functional proteins. A total of six RBMI genes were identified, which produce four polypeptides due to some silent base substitutions. The transcripts of each gene are alternatively spliced to generate protein isoforms with three or four SRGY boxes, thus greatly increasing the complexity of the products of the RBM gene family. We also provide evidence suggesting that a 5-bp deletion in a previously reported RBM cDNA clone represents a processing irregularity.

The human DAZ genes, a putative male infertility factor on the Y chromosome, are highly polymorphic in the DAZ repeat regions.

The DAZ genes on the human Y Chromosome (Chr) are strong candidates for the azoospermia factor AZF. They are frequently deleted in azoospermic or severely oligospermic males and are expressed exclusively in germ cells. In addition, the DAZ genes share a high degree of similarity with a Drosophila male infertility gene, boule. The predicted DAZ proteins contain an RNA recognition motif (RRM), and multiple copies of a repeat (the DAZ repeat) in tandem array. To understand the DAZ gene family and its expression, the DAZ genomic structure and RNA transcripts in numerous males, as well as several DAZ cDNA clones were analyzed. The results of genomic Southern blot showed that each male contains multiple DAZ genes with varying numbers of DAZ repeats, and that the copy number of the DAZ repeats are polymorphic in the population. The presence of multiple species of DAZ transcripts with different copy number and arrangement of the DAZ repeats in an individual suggests that more than one DAZ gene are transcribed. The existence of multiple functional DAZ genes complicates the analysis of genotype/phenotype correlations among males with varying sperm counts.

Characterization of a low copy repetitive element S232 involved in the generation of frequent deletions of the distal short arm of the human X chromosome.

There are several copies of related sequences on the distal short arm of the human X chromosome and the proximal long arm of the Y chromosome which were originally detected by cross hybridization with a genomic DNA clone, CRI-S232. Recombination between two S232-like sequences flanking the steroid sulfatase locus has been shown to cause frequent deletions in the X chromosome short arm, resulting in steroid sulfatase deficiency. We now report the characterization of several S232-like sequences. Restriction mapping and sequence analysis show that each S232 unit contains 5 kb of unique sequence in addition to two elements, RU1 and RU2, composed of a variable number of tandem repeats. RU1 consists of 30 bp repeating units and its length shows minimal variation between individuals. The RU2 elements in the hypervariable S232 loci on the X chromosome consist of repeating sequences which are highly asymmetric, with about 90% purines and no C's on one strand. The X-derived RU2 elements range from 0.6 kb to over 23 kb among different individuals, accounting entirely for the observed polymorphism at the S232 loci. Although the repeating units of the RU2 elements in the nonpolymorphic S232 loci on the Y chromosome share high sequence homology with those on the X chromosome, they exhibit much higher intrarepeat sequence variation. S232 homologous sequences are found in great apes, old world and new world monkeys. In chimpanzees and gorillas the S232-like sequences are polymorphic in length.