Male sex determination is mediated sequentially by sex-determining region Y (SRY) and related SRY-box 9 (SOX9) transcription factors. To understand the gene regulatory hierarchy for SRY and SOX9, a series of chromatin immunoprecipitation and whole-genome promoter tiling microarray (ChIP-Chip) experiments were conducted with mouse gonadal cells at the time of sex determination. SRY and SOX9 bind to the promoters of many common targets involved in testis differentiation and regulate their expression in Sertoli cells. SRY binds to various ovarian differentiation genes and represses their activation through WNT/β-catenin signaling. Sertoli cell-Sertoli cell junction signaling, important for testis cord formation, is the top canonical pathway among the SRY and SOX9 targets. Hence, SRY determines Sertoli cell fate by repressing ovarian and activating testicular differentiation genes, promotes early Sertoli cells to form testis cord, and then passes on its functions to SOX9, which regulates common targets and activates its own gene regulatory program, beyond SRY actions, in sex determination.
Testis-specific protein Y-encoded (TSPY) is the putative gene for the gonadoblastoma locus on the Y chromosome (GBY). TSPY and an X-homologue, TSPX, harbor a conserved domain, designated as SET/NAP domain, but differ at their C termini. Ectopic expression of TSPY accelerates cell proliferation by abbreviating the G 2 /M stage, whereas overexpression of TSPX retards cells at the same stage of the cell cycle. Previous studies demonstrated that the SET oncoprotein is capable of binding to cyclin B. Using various protein interaction techniques, we demonstrated that TSPY and TSPX indeed bind competitively to cyclin B at their SET/NAP domains in vitro and in vivo. TSPY colocalizes with cyclin B1 during the cell cycle, particularly on the mitotic spindles at metaphase. TSPY enhances while TSPX represses the cyclin B1-CDK1 phosphorylation activity. The inhibitory effect of TSPX on the cyclin B1-CDK1 complex has been mapped to its carboxyl acidic domain that is absent in TSPY, suggesting that TSPX could serve a normal function in modulating cell-cycle progression at the G 2 /M stage, whereas TSPY has acquired a specialized function in germ cell renewal and differentiation. Epigenetic dysregulation of TSPY in incompatible germ or somatic cells could promote cell proliferation and predispose susceptible cells to tumorigenesis.
In both humans and mice, two genes encode phosphoglycerate kinase, a key enzyme in the glycolytic pathway. The pgk-1 gene is expressed in all somatic cells, is located on the X chromosome, and contains 10 introns. The pgk-2 gene is expressed only in sperm cells, is located on an autosome, and has no introns. The nucleotide sequence of the pgk-2 gene suggests that it arose from pgk-1 more than 100 million years ago by RNA-mediated gene duplication. The pgk-2 gene may, then, be a transcribed retroposon. Thus, gene duplication by retroposition may have been used as a mechanism for evolutionary diversification.
The testis-specific protein Y-encoded (TSPY) gene is a candidate for the gonadoblastoma locus on the Y chromosome and is expressed in normal testicular germ cells and gonadoblastoma cells of XY sex-reversed females. Although TSPY expression has been demonstrated in gonadoblastoma tissues, it is uncertain if such expression is involved in a causative or consequential event of the oncogenic process. We postulate that if TSPY is involved in gonadoblastoma development, its promoter should be functional in the female gonad before and/or at early stages of tumorigenesis. To test this hypothesis, we generated several lines of transgenic mice harboring a Cre-recombinase transgene directed by a 2.4-kb hTSPY promoter. These mice were crossed with the Z/EG reporter line that expresses EGFP only after a Cre-mediated recombination. Our results showed that hTSPY-Cre;Z/EG double transgenic mice expressed EGFP specifically in the germ cells of both male and female gonads. Further, neurons of the central and peripheral nervous systems also expressed EGFP as early as E12.5 embryonic stage. EGFP was particularly observed in the trigeminal nerve, trigeminal ganglion, dorsal root of the ganglia, and in postnatal and adult brains. These observations support the hypothesis that TSPY plays an active role in gonadoblastoma. The tissue-specific expression of the hTSPY-Cre transgene should also be useful in studies utilizing Cre-mediated gene activation/inactivation strategies in gamatogenesis and/or neurogenesis.
Using a positional cloning approach, we have isolated an expressed gene from a flow-sorted Y chromosome cosmid library. The isolation of this gene was based on the identification of the Y-231 cosmid that contains CpG rich sequences (HTF islands) in its human insert. The Y-231 cosmid was capable of detecting a 1.3 kb transcript in poly (A)+ RNA samples from human testis. Several cDNA clones were isolated from a human testis cDNA library constructed in lambda gt10. In addition, DNA-mediated gene transfer and restriction enzyme mapping experiments demonstrated that two functional transcriptional units are present within the Y-231 cosmid. DNA sequencing analysis showed that the largest cDNA clone contains 1075 bp of unique sequence and a poly (A) track at the 3' end of the corresponding mRNA. An open reading frame of 762 bp that encodes a predicted protein of 253 amino acids with a calculated molecular weight of 28.9 kD was identified. The Y-231 structural gene encompasses approximately 2.7 kb of genomic sequence and contains six exons that are interrupted by five introns. The Y-231 gene shares very high (97%) identity at the DNA level to a previously described Y-specific gene, testis specific protein Y-encoded (TSPY) gene, suggesting the possibility that these two genes are related, if not identical. However, the TSPY gene has been postulated to be intronless. Further PCR and RT-PCR analyses of these two genes and their transcripts have provided evidence supporting the hypothesis that they are the same gene and are members of a Y-specific repeated gene family containing intronic sequences. The Y-231 (TSPY) gene is conserved in the male genome and expressed in the testis of the chimpanzee, suggesting that it may play an important role in the physiology of this organ in man and the great ape.
The contribution of specific genes on the Y chromosome in the etiology of prostate cancer has been undefined. Genetic mapping studies have identified a gonadoblastoma locus on the human Y chromosome (GBY) that predisposes the dysgenetic gonads of XY sex-reversed patients to tumorigenesis. Recently a candidate gene, the testis-specific protein Y-encoded (TSPY) that resides on the GBY critical region, has been demonstrated to express preferentially in tumor cells in gonadoblastoma and testicular germ cell tumors. TSPY shares high homology to a family of cyclin B binding proteins and has been considered to possibly play a role in cell cycle regulation or cell division. To address the possible involvement of the TSPY gene in prostate cancer, both in situ mRNA hybridization and immunohistochemistry techniques were used to study the expression of this putative GBY gene in prostate specimens. Our results demonstrated that TSPY was expressed at low levels in normal epithelial cells and benign prostatic hyperplasia (BPH), but at elevated levels in tumor cells of prostate cancers at various degrees of malignancy. Sequence analysis of RT-PCR products obtained from both prostatic and testicular tissues using specific primers flanking the open reading frame of the TSPY mRNA revealed a complex pattern of RNA processing of the TSPY transcripts involving cryptic intron splicing and/or intron skipping. The variant transcripts encode a variety of polymorphic isoforms or shortened versions of the TSPY protein, some of which might possess different biochemical and/or functional properties. The abbreviated transcripts were more abundant in prostatic cancer tissues than the testicular ones. Although the exact nature of such variant TSPY transcripts and proteins is still unclear, their differential expression suggests that the TSPY gene may also be involved in the multi-step prostatic oncogenesis besides its putative role in gonadoblastoma and testicular seminoma.
Isolation and mapping of a mouse complementary DNA sequence (mouse Y-finger) encoding a multiple, potential zinc-binding, finger protein homologous to the candidate human testis-determining factor gene is reported. Four similar sequences were identified in Hind III-digested mouse genomic DNA. Two (7.2 and 2.0 kb) were mapped to the Y chromosome. Only the 2.0-kb fragment, however, was correlated with testis determination. Polymerase chain reaction analysis suggests both Y loci are transcribed in adult testes. A 3.6-kb fragment was mapped to the X chromosome between the T16H and T6R1 translocation breakpoints, and a fourth (6.0 kb) was mapped to chromosome 10. Hence, mYfin sequences have been duplicated several times in the mouse, although they are not duplicated in humans.
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