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.

Identification of two novel proteins that interact with germ-cell-specific RNA-binding proteins DAZ and DAZL1.

The human DAZ (deleted in azoospermia) gene family on the Y chromosome and an autosomal DAZ-like gene, DAZL1, encode RNA-binding proteins that are expressed exclusively in germ cells. Their role in spermatogenesis is supported by their homology with a Drosophila male infertility gene boule and sterility of Daz11 knock-out mice. While all mammals contain a DAZL1 homologue on their autosomes, DAZ homologues are present only on the Y chromosomes of great apes and Old World monkeys. The DAZ and DAZL1 proteins differ in the copy numbers of a DAZ repeat and the C-terminal sequences. We studied the interaction of DAZ and DAZL1 with other proteins as an approach to investigate functional similarity between these two proteins. Using DAZ as bait in a yeast two-hybrid system, we isolated two DAZAP (DAZ-associated protein) genes. DAZAP1 encodes a novel RNA-binding protein that is expressed most abundantly in the testis, and DAZAP2 encodes a ubiquitously expressed protein with no recognizable functional motif. DAZAP1 and DAZAP2 bind similarly to both DAZ and DAZL1 through the DAZ repeats. The DAZAP genes were mapped to chromosomal regions 19p13.3 and 2q33-q34, respectively, where no genetic diseases affecting spermatogenesis are known to map.

Association of the mouse infertility factor DAZL1 with actively translating polyribosomes.

The DAZ (Deleted in AZoospermia) gene family was isolated from a region of the human Y chromosome long arm that is deleted in about 10% of infertile men with idiopathic azoospermia. DAZ and an autosomal DAZ-like gene, DAZL1, are expressed in germ cells only. They encode proteins with an RNA recognition motif and with either a single copy (in DAZL1) or multiple copies (in DAZ) of a DAZ repeat. A role for DAZL1 and DAZ in spermatogenesis is supported by their homology to a Drosophila male infertility protein Boule and by sterility of Dazl1 knock-out mice. The biological function of these proteins remains unknown. We found that DAZL1 and DAZ bound similarly to various RNA homopolymers in vitro. We also used an antibody against the human DAZL1 to determine the subcellular localization of DAZL1 in mouse testis. The sedimentation profiles of DAZL1 in sucrose gradients indicate that DAZL1 is associated with polyribosomes, and further capture of DAZL1 on oligo(dT) beads demonstrates that the association is mediated through the binding of DAZL1 to poly(A) RNA. Our results suggest that DAZL1 is involved in germ-cell specific regulation of mRNA translation.

Human papillomavirus-associated penile squamous cell carcinoma in HIV-positive patients.

Two cases of penile squamous cell carcinoma with distinctive clinicopathologic characteristics are presented. The tumors appeared in patients infected with HIV and were located in the glans of the penis. Histologically, the neoplasms were well-differentiated, infiltrating, squamous cell carcinomas. The entire spectrum from benign condyloma to infiltrative squamous cell carcinoma was present in the two patients. In both cases, human papillomavirus (HPV) could be demonstrated using polymerase chain reaction analysis. The reported cases suggest a synergic interaction of HPV and HIV in the carcinogenic process of some penile carcinomas.

The mouse alanine:glyoxylate aminotransferase gene (Agxt1): cloning, expression, and mapping to chromosome 1.

The human alanine:glyoxylate aminotransferase gene (AGXT) has been cloned and characterized in detail, and various mutant alleles have been shown to be responsible for primary hyperoxaluria type 1 (PH1). However, advances in understanding the basic mechanisms of this rare human disease have been hampered by the lack of a suitable animal model. Although several AGXT homologous genes have been cloned in a number of mammalian species, none of them allows the level of genetic experimentation that current methods provide for mouse embryo manipulation. Thus, we have carried out the molecular cloning and analysis of the mouse Agxt1 gene, as a necessary first step towards the generation of a mouse model for PH1. The full-length mouse Agxt1 cDNA is 1545 bp long, and encodes a 414 amino acid protein. Mouse Agxt1 is highly similar to its rat counterpart both at the nucleotide (91% identity) and the amino acid (92% identity) levels. Like its rat homologue, the larger mRNA species transcribed encodes a conserved amino terminal end characteristic of AGXT forms known to be targeted to the mitochondria. Mouse Agxt1 expression is restricted to the liver, and in vitro transfection of AGXT(-) cells with the cloned Agxt1 cDNA confers AGXT enzymatic activity. At the genomic level, mouse Agxt1 contains 11 exons, spanning 11 Kb, and it maps to the central portion of chromosome 1, a region of known synteny with human distal 2q, where AGXT has been previously mapped (2q36-37).

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.

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.

Genetic mapping of the adenine nucleotide translocase-2 gene (Ant2) to the mouse proximal X chromosome.

Adenine nucleotide translocases are mitochondrial membrane proteins encoded by a small dispersed multigene family. We have previously cloned cDNAs derived from the mouse adenine nucleotide translocase-1 and -2 genes (Ant1 and Ant2) and assigned the loci to mouse chromosomes 8 and X, respectively. Here we describe the genomic organization of the Ant2 gene and its regional map position on the X chromosome, which was determined through linkage analysis using an interspecific backcross between Mus musculus and Mus spretus inbred strains. Ant2 cosegregates with DXMit49 and DXMit50 and lies distal to Agtr2 in the proximal region of the mouse X chromosome. This map assignment further defines a region of conserved synteny between human Xq22-q25 and the mouse proximal X chromosome.

Cloning of the rat steroid sulfatase gene (Sts), a non-pseudoautosomal X-linked gene that undergoes X inactivation.

Although the human steroid sulfatase (STS) gene has been cloned and characterized in detail, several attempts to clone its mouse homologue, with either anti-human STS antibodies or human STS cDNA probes, have failed, suggesting a substantial divergence between these genes. However, partial amino-terminal sequence from purified rat liver STS is very similar to its human counterpart, and sequence comparisons have revealed several domains that are conserved among all the sulfatases characterized to date. Thus, we used a degenerate-primer RT-PCR approach to amplify a 321-bp fragment from rat liver cDNA, which was used as a probe to clone and characterize the complete cDNA. Comparison of the protein coding region between the rat and human genes showed 66% homology both at the DNA and the protein levels. STS activity was conferred to STS(-) A9 cells upon transfection with a rat Sts expression construct, indicating the authenticity of the cloned cDNA. While Sts has been shown to be located in the mouse pseudoautosomal region, both physical and genetic mapping demonstrate that Sts is not pseudoautosomal in the rat. The overall genomic organization of rat Sts and human STS is very similar, except that the insertion site for intron 1 in the rat is 26 bp upstream from that in the human. Rat Sts is only 8.2 kb long, while the human STS spans over 146 kb.

Generation of sequence-tagged sites from Xp22.3 by isolating common Alu-PCR products of radiation hybrids retaining overlapping human X chromosome fragments.

Several human diseases have been mapped to Xp22.3 on the distal short arm of the human X chromosome, and many genes in this area have been found to be expressed from the inactive X chromosome. To facilitate physical mapping and characterization of this interesting region, we have constructed a battery of radiation hybrids containing human X chromosomal fragments, and isolated two hybrid clones A with overlapping fragments of Xp22.3. Alu-PCR on these hybrids and identification of sequences common to both hybrids allowed the isolation of six sequences-tagged sites (STSs) from Xp22.3. Five of the STSs were mapped+ to individual YACs comprising a recently constructed contig of this region. These novel STSs are useful markers for further physical characterization of this part of the genome.

High frequency de novo alterations in the long-range genomic structure of the mouse pseudoautosomal region.

The pseudoautosomal region (PAR) is a segment of shared homology between the X and Y chromosomes. Here we report physical linkage of three mouse PAR probes: DXYHgu1, DXYMov15 and (TTAGGG)n. Steroid sulphatase (Sts) maps distal to these probes, indicating that there is an internal array of the telomere sequence (TTAGGG)n in the PAR. Pseudoautosomal PacI restriction fragments, up to 2 Mb in size, are unstable in C57BL/6 x C57BL/6 crosses. New alleles, often several hundred kilobases different in size, occur at a sex-averaged rate of approximately 30% per allele. Such frequent large-scale germline genome arrangements are without precedent in mammals.

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.

An evaluation of the inactive mouse X chromosome in somatic cell hybrids.

The expression of mouse Zfx, Rps4, Ube1x, and Xist was evaluated in hamster-mouse somatic cell hybrids containing either an active or an inactive mouse X chromosome using polymerase chain reaction of reverse transcribed RNA (RT-PCR). The results showed that Zfx, Rps4, and Ube1x are expressed exclusively from the active mouse X, while Xist is expressed exclusively from the inactive X. These findings confirm the pattern of X inactivation for these mouse genes reported previously based on expression in somatic tissues of F1 females from interspecific crosses. These results demonstrate the existence of differences between human and mouse X inactivation, as the corresponding human genes, ZFX, RPS4X, and UBE1 escape X inactivation.

Expression of epidermal growth factor receptor (proto-oncogene c-erbB-1) and estrogen receptor in human breast carcinoma. An immunocytochemical study of 70 cases.

In vitro studies have shown that growth factors may mediate the growth stimulatory effect of estrogen in hormone-dependent human breast carcinomas while the constitutive expression of same growth factors might by-pass the need for estrogenic stimulus in hormone-independent neoplasms. We have performed immunocytochemical analysis of the expression of epidermal growth factor receptor (EGF-R or proto-oncogen c-erbB-1) and estrogen receptor (ER) in 70 cases of human breast carcinoma. We found an inverse relationship between the expression of EGF-R and ER (Kendall's tau b = -0.1997, P < 0.03), which prompts us to conclude that ER(-) breast carcinomas may grow in a hormone-independent manner through the over-expression of the proto-oncogene c-erbB-1, which is the receptor for epidermal (EGF) and alpha transforming (TGFalfa) growth factors.

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.

Epidermal growth factor prohormone is secreted in human urine.

Examination of adult human urine by immunoblot analysis with antiserum specific to human recombinant 6-kDa epidermal growth factor (EGF) reveals the presence of an immunoreactive protein with a molecular mass of 165 kDa. This protein is consistently found in the morning (first) but not in day urine of adult males and females. Day urine contains variable proportions of four other high-molecular-weight EGFs with approximate molecular masses of 97, 66, 50, and 42 kDa. The 165-kDa EGF immunoreactive protein reacts with mouse amino-terminal EGF prohormone (proEGF) antiserum and comigrates with mouse urinary proEGF, suggesting that the protein is the human EGF prohormone. The 165-kDa human proEGF exhibits strong binding affinity to concanavalin A, indicating that it is glycosylated. Immunoblotting of urine in infants and children of various age groups demonstrates the presence of proEGF in all age groups, but its concentration is highest in children 2-4 yr of age. These findings, taken together with secretion of proEGF of similar molecular mass in mouse and rat urine, suggest that renal proEGF secretion is an evolutionarily conserved phenomenon and may have an important function or functions distal to the site of its synthesis.

Isolation of a new gene from the distal short arm of the human X chromosome that escapes X-inactivation.

A gene, designated GS1, was identified by its association with a CpG island approximately 100 kb telomeric to the steroid sulfatase (STS) locus on the distal short arm of the human X chromosome. Both cDNA and genomic clones of the GS1 gene have been isolated and characterized. The cDNA clone detects a 2.3 kb transcript in human placenta and fibroblasts, and may encode a protein of 214 amino acid residues. Although sequences homologous to GS1 cDNA are present on chromosomes 1, 20, X, and Y, the functional GS1 gene is on the X chromosome. The GS1 gene appears to be non-essential, as there are no obvious clinical differences between STS deficient patients with point mutations in the STS gene, and patients with a deletion of the STS and GS1 genes. The GS1 gene is expressed from mouse-human cell hybrids containing active or inactive human X chromosomes, indicating that it escapes X inactivation. Characterization of GS1 genomic clones revealed that the gene consists of 4 exons spanning over 105 kb, with its transcriptional direction opposite to that of the STS gene. The isolation and characterization of a new gene which escapes X inactivation from distal Xp is of interest as it adds to our understanding of the structural organization of the human X chromosome and may help in providing clues regarding the mechanism of X-inactivation.

The human enamel protein gene amelogenin is expressed from both the X and the Y chromosomes.

Amelogenins, a family of extracellular matrix proteins of the dental enamel, are transiently but abundantly expressed by ameloblasts during tooth development. Amelogenins seem to regulate the formation of crystallites during the secretory stage of enamel development, while they are specifically degraded during tooth-bud maturation. In this paper we report the characterization of the AMGX and AMGY genes on the short arms of the human X and Y chromosomes which encode the amelogenins. Our studies on the expression of the amelogenin genes in male developing tooth buds showed that both the AMGX and AMGY genes are transcriptionally active and encode potentially functional proteins. We have isolated genomic and cDNA clones from both the AMGX and AMGY loci and have studied the sequence organization of these two genes. Reverse transcriptase (RT)PCR amplification of the 5' portion of the amelogenin transcripts revealed several alternatively spliced products. The splicing pattern observed in the Y-derived mRNA varies from that of the X-derived mRNA. The promoter regions from both genes and the predicted amelogenin protein sequences are presented. This information will be useful for studying the molecular basis of X-linked amelogenesis imperfecta, for understanding the evolution and regulation of gene expression on the mammalian sex chromosomes, and for investigating the role of amelogenin genes during tooth development.