Differential rates of evolution for the ZFY-related zinc finger genes,Zfy, Zfx,and Zfa in the mouse genus Mus

A comparative study of the last exon of the zinc finger genes Zfx, Zfy, and Zfa from species of mice in the genus Mus was conducted to assess the extent of gene-specific and chromosome-specific effects on the evolutionary patterns among related X-, Y-, and autosomal-linked genes. Phylogenetic analyses of 29 sequences from Zfx, Zfa, and Zfy from 10 taxa were performed to infer relatedness among the zinc finger loci, and codon-based maximum likelihood analyses were conducted to assess evolutionary pattern among genes. Five models of nucleotide sequence evolution were applied and compared using a likelihood ratio test. Estimates of nonsynonymous to synonymous changes (dN/dS) for these genes suggest that amino acid substitutions are occurring at a more rapid rate across the autosomal- and Y-specific lineages compared to the X-specific lineage, with the Y-specific lineage showing the highest rate under certain models. The data suggest the action of gene-specific effects on evolutionary pattern. In particular, Zfa and Zfy genes, both with presumed restricted expression, appear less functionally constrained relative to ubiquitously expressed Zfx. Slightly elevated dN/dS for Zfy genes in comparison to Zfa also suggest Y-specific effects.     

Zfa is an expressed retroposon derived from an alternative transcript of the Zfx gene.

ZFY, a gene on the Y chromosome encoding a zinc finger protein, has been proposed as a candidate for the human testis determining gene. Sequences related to ZFY, called ZFX, are present on the X chromosome of a wide range of placental mammals. Unlike most mammals the mouse has four genes homologous to ZFY; two on the Y chromosome, Zfy-1 and Zfy-2, an X-linked gene, Zfx, and an autosomal gene, Zfa. We show here that Zfa has arisen recently by retroposition of one of at least three alternatively spliced mRNAs transcribed from the Zfx gene. Zfa is an unusual retroposon in that it has retained an open reading frame and is expressed, although its function may be limited or altered by the presence of a potentially inactivating mutation in the third of its zinc fingers. This mutation must have occurred at the same time or soon after the retroposition event as it is also present in the Zfa gene of Mus spretus. Interestingly the third finger of the M. musculus musculus Zfy-2 gene has also sustained a mutation suggesting that this gene family may be rapidly evolving in mice.     

Regional assignments of the zinc finger Y-linked gene (ZFY) and related sequences on human and mouse chromosomes

Recent chromosome walking experiments have identified a candidate gene (ZFY) for the testis-determining factor on the human Y chromosome (Page et al., 1987). We report here the regional assignments of the ZFY gene and related sequences in the human and the mouse. By in situ hybridization, we assigned ZFX and ZFY to human chromosome bands Xp21 and Yp11.3, respectively. Although the mouse harbors two Zfy genes, only one site at band A1 of its Y chromosome was significantly labeled. The mouse Zfx gene and the Zfa gene on chromosome 10 were assigned to bands XD and 10B5, respectively. These assignments of the ZFX gene in human and mouse add another marker to the conserved syntenic group for evaluating the evolutionary relationship of the human and mouse X chromosomes.     

Localization of Murine X and Autosomal Sequences Homologous to the Human Y Located Testis-Determining Region

Recently a candidate gene for the primary testis-determining factor (TDF) encoding a zinc finger protein (ZFY) has been cloned from the human Y chromosome. A highly homologous X-linked copy has also been identified. Using this human sequence it is possible to identify two Y loci, an X and an autosomal locus in the mouse (Zfy-1, Zfy-2, Zfx and Zfa, respectively). Suprisingly ZFY is more homologous to the mouse X and autosomal sequences than it is to either of the Y-linked loci. Both Zfy-1 and Zfy-2 are present in the Sxr region of the Y but Zfy-2 is absent in the Sxr deletion variant Sxrb (or Sxr") suggesting it is not necessary for male determination. Extensive backcross analyses map Zfa to mouse chromosome 10 and Zfx to a 5-cM interval between anonymous X probe MDXS120 and the tabby locus (Ta). We also show that the mouse androgen receptor locus (m-AR) believed to underlie the testicular feminization mutation (Tfm) shows complete linkage to Zfx. Comparative mapping indicates that in man these genes lie in separate conserved DNA segments.     

The molecular evolution of ZFY-related genes in birds and mammals

Summary We report the isolation and nucleotide sequence determination of clones derived from five ZFY-related zinc-finger genes from birds and mammals. These sequences are analyzed with reference to the previously published human genes, ZFX and ZFY, and mouse genes, Zfx, Zfa, Zfy-1, and Zfy-2. The analysis indicates that ZFY-related genes are highly conserved in birds and mammals, and that the rate of nucleotide substitution in the Y-linked genes is not as high as predicted. However, the mouse Zfy-1 and Zfy-2 genes are markedly divergent members of the ZFY gene family; we suggest this relates to X-inactivation of the mouse gene Zfx.     

Patterns of Y and X chromosome DNA sequence divergence during the Felidae radiation.

The 37 species of modern cats have evolved from approximately eight phylogenetic lineages within the past 10 to 15 million years. The Felidae family has been described with multiple measures of morphologic and molecular evolutionary methods that serve as a framework for tracking gene divergence during brief evolutionary periods. In this report, we compare the mode and tempo of evolution of noncoding sequences of a large intron within Zfy (783 bp) and Zfx (854 bp), homologous genes located on the felid Y and X chromosomes, respectively. Zfy sequence variation evolves at about twice the rate of Zfx, and both gene intron sequences track feline hierarchical topologies accurately. As homoplasies are infrequent in patterns of nucleotide substitution, the Y chromosome sequence displays a remarkable degree of phylogenetic consistency among cat species and provides a highly informative glimpse of divergence of sex chromosome sequences in Felidae.     

Zfy1 encodes a nuclear sequence-specific DNA binding protein

Zfy1 is a mouse Y chromosomal gene encoding a zincfinger protein which is thought to have some function during spermatogenesis. Here we show that, when introduced into tissue culture cells, Zfy1 is targeted to the nucleus. Two independent signals are present within the protein for nuclear localization. This nuclear Zfy1 protein is able to bind strongly to DNA-cellulose and, using site-selection assays, we have identified specific Zfy1 DNA binding sites. Taken together these results suggest that Zfy1 is a nuclear-located sequence-specific DNA binding protein which functions during spermatogenesis.     

Evolution of zinc finger-Y and zinc finger-X genes in oryzomyne-akodontine rodents (Cricetidae)

Summary Zinc finger-Y (Zfy) and zinc finger-X (Zfx) genes were analyzed by Southern blotting in male and female specimens of 10 species belonging to the oryzomyne-akodontine stock of Cricetidae rodents. DNA fragments were used as characters to construct a parsimony tree of the genes. Zfx and Zfy trees in general coincide with the evolutionary history of the taxa. Both trees show Oryzomys longicaudatus genes as the outgroup whereas Akodon xanthorrhinus genes are also distant from those of the other species. Oxymycterus rufus and Bolomys obscurus share related sequences, while genes from the other six Akodon species form a group of their own. It was found that 9 out of the 10 species analyzed show Zfy amplification in a range varying from 2 to 24 copies and with a pattern that is clade specific. The estimation of the average changes per character strongly suggests that Zfy has evolved more rapidly than Zfx; our estimates of the rate of nucleotide substitution are 4.6 times higher for Zfy than for Zfx. Offprint requests to: N.O. Bianchi     

Demonstration of a stage-specific expression of the ZFY protein in fetal mouse testis using anti-peptide antibodies.

The zinc finger Y (Zfy) gene is located on the Y chromosome of all placental mammals. Although it is phylogenetically conserved and is expressed in mouse fetal testis, it is not the sex determining Y (Tdy) gene. To address the possible function of the Zfy gene in mice, the distribution of Zfy protein in fetal mice was investigated by immunocytochemical staining using several specific antisera against synthetic peptides of the mouse Zfy protein. Analysis of various fetal tissues at different embryonic stages demonstrated a specific staining only in fetal testis. In particular, reactive protein was initially observed in male fetal gonads at day 11.5 postcoitum (p.c.). The immuno-staining intensified in fetal testes at day 12 and 12.5 p.c., decreased drastically in those at day 13 and 14 p.c. and became undetectable in those at day 15 p.c. and beyond. The reactive molecules were distributed mostly within the seminiferous tubules of the embryonic testis. The present observations confirm the previous findings with RT-PCR analysis and indicate that Zfy or Zfy-like protein is expressed in stage-specific manner during early testis differentiation. Its location in the seminiferous tubules suggests a possible role in early germ cell development.     

Evolution of the Zfx and Zfy genes: rates and interdependence between the genes

A phylogenetic analysis of sex-chromosomal zinc-finger genes (Zfx and Zfy) indicates that the genes have not evolved completely independently since their initial separation. The sequence similarities suggest gene conversion in the last exon between the duplicated Y-chromosomal genes Zfy-1 and Zfy-2 in the mouse. There are also indications of conversion (or recombination) between the X- and Y-chromosomal genes in the crab- eating fox and in the mouse. The method for estimating synonymous and nonsynonymous substitutions is modified by incorporating the substitutions in the twofold-degenerate sites in a novel way. The estimates of synonymous substitutions support the generation-time hypothesis in that the obtained rates are higher in mice (by a factor of 4.7) than in humans and higher in the Y-chromosomal genes (by a factor of 1.9) than in the X-chromosomal genes.      

Correlation of appearance of metastasis-associated protein1 (Mta1) with spermatogenesis in developing mouse testis

Mta1, a representative of the MTA gene family, is believed to be involved in the metastasis of malignant tumors. However, a systematic study of its physiological function has not been performed. It has been found in normal mouse organs at relatively low levels, except for in testis, suggesting a potential function in the male reproductive system. In order to explore the role of Mta1 protein during spermatogenesis, its expression in adult mouse testis was compared with that in developing mouse testis and in testis from adult mice treated with methoxyacetic acid, which selectively depletes primary spermatocytes. Quantitative analysis revealed that Mta1 protein gradually increased in the testis from 14 days postnatally. Immunolocalization analysis demonstrated strong signals in the seminiferous tubules, and Mta1 was predominantly present in the nucleus of primary spermatocytes and spermatogonia from 14 days postnatally. The most intensive staining was located in the nucleus of pachytene spermatocytes in mature testes. The expression pattern of Mta1 during spermatogenesis was also shown to be stage-specific by immunohistochemistry analysis. Finally, dramatic loss of Mta1 expression from pachytene spermatocytes was observed in the spermatogenic-arrested adult mouse testis. These results collectively demonstrate that Mta1 appears during postnatal testis development and suggest that this expression may be crucial for spermatogenesis. This study was supported by the Natural Science Foundation of China (2006: 30570982; 2003: 30370750; 2003: 30371584).     

Cloning,Characterization and Primary Function Study of a Novel Gene,Cymg1,Related to Family 2 Cystatins

Cystatins are cysteine proteinase inhibitors,We found two expression sequence tags (ESTs),CA463109 and AV042522,from a mouse testis library using Digital differential display (DDD).By electricalhybridization,a novel gene,Cymgl(GenBank accession No.AY600990),which has a full length of 0.78 kb,and contains four exons and three introns,was cloned from a mouse testis eDNA library.The gene is locatedin the 2G3 area of chromosome 2.The full eDNA encompasses the entire open reading frame,encoding 141amino acid residues.The protein has a cysteine protease inhibitor domain that is related to the family 2cystatins but lacks critical consensus sites important for cysteine protease inhibition.These characteristicsare seen in the CRES subfamily,which are related to the family 2 cystatins and are expressed specifically inthe male reproductive tract.CYMG1 has a 44%(48/108)identity with mouse CRES and 30%(42/140)identity with mouse cystatin C.Northern blot analysis showed that the Cymgl is specifically expressed inadult mouse testes.Cell location studies showed that the GFP-tagged CYMG 1 protein was localized in thecytoplasm of HeLa cells,lmmunohistochemistry revealed that the CYMG1 protein was expressed in mousetestes spermatogonium,spermatocytes,round spermatids,elongating spermatids and spermatozoa.RT-PCRresults also showed that Cymgl was expressed in mouse testes and spermatogonium.The Cymgl expressionlevel varied in different developmental stages:it was low 1 week postpartum,steadily increased 2 to 5 weekspostpartum,and was highest 7 weeks postpartum.The expression level at 5 weeks postpartum was main-tained during 13 to 57 weeks postpartum.The Cymgl expression level in the testes over different develop-mental stages correlates with the mouse spermatogenesis and sexual maturation process.All these indicatethat Cymgl might play an important role in mouse spermatogenesis and sexual maturation. Cystatins are cysteine proteinase inhibitors,We found two expression sequence tags(ESTs),CA463109 and AV042522,from a mouse testis library using Digital differential display (DDD).By electricalhybridization,a novel gene,Cymgl(GenBank accession No.AY600990),which has a full length of 0.78 kb,and contains four exons and three introns,was cloned from a mouse testis eDNA library.The gene is locatedin the 2G3 area of chromosome 2.The full eDNA encompasses the entire open reading frame,encoding 141amino acid residues.The protein has a cysteine protease inhibitor domain that is related to the family 2cystatins but lacks critical consensus sites important for cysteine protease inhibition.These characteristicsare seen in the CRES subfamily,which are related to the family 2 cystatins and are expressed specifically inthe male reproductive tract.CYMG1 has a 44%(48/108)identity with mouse CRES and 30%(42/140)identity with mouse cystatin C.Northern blot analysis showed that the Cymgl is specifically expressed inadult mouse testes.Cell location studies showed that the GFP-tagged CYMG 1 protein was localized in thecytoplasm of HeLa cells,lmmunohistochemistry revealed that the CYMG1 protein was expressed in mousetestes spermatogonium,spermatocytes,round spermatids,elongating spermatids and spermatozoa.RT-PCRresults also showed that Cymgl was expressed in mouse testes and spermatogonium.The Cymgl expressionlevel varied in different developmental stages:it was low 1 week postpartum,steadily increased 2 to 5 weekspostpartum,and was highest 7 weeks postpartum.The expression level at 5 weeks postpartum was main-tained during 13 to 57 weeks postpartum.The Cymgl expression level in the testes over different develop-mental stages correlates with the mouse spermatogenesis and sexual maturation process.All these indicatethat Cymgl might play an important role in mouse spermatogenesis and sexual maturation.     

CD9 is expressed on human male germ cells that have a long-term repopulation potential after transplantation into mouse testes

Human spermatogonial stem cells (SSCs) play critical roles in lifelong maintenance of male fertility and regeneration of spermatogenesis. These cells are expected to provide an important resource for male fertility preservation and restoration. A basic strategy has been proposed that would involve harvesting testis biopsy specimens from a cancer patient prior to cancer therapies, and transplanting them back to the patient at a later time; then, SSCs included in the specimens would regenerate spermatogenesis. To clinically apply this strategy, isolating live human SSCs is important. In this study, we investigated whether CD9, a known rodent SSC marker, is expressed on human male germ cells that can repopulate recipient mouse testes upon transplantation. Testicular tissues were obtained from men with obstructive azoospermia. Using immunohistochemistry, we found that CD9 was expressed in human male germ cells in the basal compartment of the seminiferous epithelium. Following immunomagnetic cell sorting, CD9-positive cells were enriched for germ cells expressing MAGEA4, which is expressed by spermatogonia and some early spermatocytes, compared with unsorted cells. We then transplanted CD9-positive cells into nude mouse testes and detected an approximately 3- to 4-fold enrichment of human germ cells that repopulated mouse testes for at least 4 mo after transplantation, compared with unsorted cells. We also observed that some cell turnover occurred in human germ cell colonies in recipient testes. These results demonstrate that CD9 identifies human male germ cells with capability of long-term survival and cell turnover in the xenogeneic testis environment.