Is ZFY the sex-determining gene on the human Y chromosome?

The sex-determining region of the human Y chromosome contains a gene, ZFY, that encodes a zinc-finger protein. ZFY may prove to be the testis-determining factor. There is a closely related gene, ZFX, on the human X chromosome. In most species of placental mammals, we detect two ZFY-related loci: one on the Y chromosome and one on the X chromosome. However, there are four ZFY-homologous loci in mouse: Zfy-1 and Zfy-2 map to the sex-determining region of the mouse Y chromosome, Zfx is on the mouse X chromosome, and a fourth locus is autosomal.     

Interchromosomal gene conversion as a possible mechanism for explaining divergence patterns of ZFY-related genes

Summary The divergence pattern of mammalian ZFY-related genes from human (ZFY and ZFX) and mouse (Zfy-1 and Zfx) was reexamined on the basis of nucleotide substitutions at the synonymous codon-alternating positions. It is possible to explain the unusual divergence pattern of the mammalian Y-linked ZF genes by interchromosomal gene conversion by X-linked ZF genes. Furthermore, the rates of evolution of mammalian X- and Y-linked ZF genes were shown to agree well with those expected from our model. Offprint requests to: T. Miyata     

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.     

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.     

Molecular evolution of the ZFY and ZNF6 gene families

Members of the ZFY and ZNF6 gene families have been cloned from species representing different taxa and different modes of sex determination. Comparisons of these genes show the ZFY-like and ZNF6 sequences to be strongly conserved across marsupials, birds, and lepidosaurians. Sequence analyzed by neighbor-joining indicated that both gene families are monophyletic with a high bootstrap value. Pairing of sequences from males and females of nonmammalian species showed there to be no significant difference between male and female sequences from a single species, consistent with autosomal locations. The molecular distances between murine Zfy-1, Zfy-2, and other ZFY-like sequences suggested that Zfy genes have undergone a period of rapid evolutionary change not seen in human ZFY.      

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.      

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.     

An interstitial deletion in mouse Y chromosomal DNA created a transcribed Zfy fusion gene.

The small portion of the mouse Y chromosome retained in the Sxra transposition is thought to carry at least five genes including, as demonstrated here, the entirety of the zinc-finger genes Zfy-1 and Zfy-2. Sxrb, a derivative of Sxra, was previously thought to retain Zfy-1 but to be deleted for Zfy-2. Here we show that Sxrb differs from Sxra as the result of unequal crossing-over between Zfy-1 and Zfy-2. This unequal crossing-over created a transcribed Zfy-2/1 fusion gene and an interstitial deletion. Our data and previous results together suggest that this deletion encompassed the 3' portion of Zfy-2, the histocompatibility gene Hya, the spermatogenesis factor Spy, and the 5' portion of Zfy-1. We suggest that not only Zfy but also other neighboring genes such as Spy and Hya may exist in two copies on the Y as the result of a large tandem duplication during rodent evolution.     

Sex diagnosis of equine preimplantation embryos using the polymerase chain reaction

A rapid and reliable method for sex determination of preimplantation-stage equine embryos has not been available. The aim of the present study was to find an enzyme which would distinguish sexes in the horse by finding a polymorphic restriction site between the ZFY and ZFX homologues amplified by the polymerase chain reaction (PCR). Altogether, 38 different restriction enzymes were tested using female and male DNA extracted from blood. The primers used for amplification were selected from conserved sequences between human ZFY and ZFX genes and mouse Zfy-1 and Zfy-2 genes. Nine enzymes cut the PCR product of approximately 450 basepairs, but only Bsm I yielded different banding patterns in female and male DNA. All blood samples were correctly diagnosed. To test the method on embryonic cells, 17 horse demi-embryos were obtained from expanding blastocysts 220 to 950 mum in diameter. Demi-embryos were further cut into 3 to 7 parallel samples which were analyzed individually to test the repeatability of the method. Eight of the original embryos were diagnosed as females and 9 as males. No misidentifications were observed within the embryonic samples, suggesting that this sexing method is highly reliable. This study provides a rapid and accurate method to sex horse embryos.     

A bird zinc-finger protein closely related to ZFY

The ZFY gene is thought to reside in the "sex-determining" region of the mammalian Y chromosome and encodes a zinc-finger protein that may function in determining the sex of embryos. Although birds have a ZZ(male)/ZW(female) sex-determination system, they possess a gene, Zfb, that is highly homologous to ZFY. We used ZFY as a hybridization probe to clone the zinc-finger domain of the chicken Zfb gene. Chicken Zfb is widely transcribed in male and female tissues and encodes a protein with a zinc-finger domain that is 93% identical in amino acid sequence to the zinc-finger domain of ZFY. Thus, the putative DNA-binding domains of the Zfb and ZFY proteins diverged little from a common ancestral protein that existed prior to birds and mammals, suggesting that the DNA binding site has been similarly conserved. The absence of sex differences in the hybridization patterns of Zfb raises the question of whether this gene is present on the Z/W sex chromosomes in birds.     

Evolution of the X-linked Zinc Finger Gene and the Y-linked Zinc Finger Gene in Primates

We have sequenced the partial exon of the zinc finger genes (ZFX and ZFY) in 5 hominoids, 2 Old World monkeys, 1 New World monkey, and 1 prosimian. Among these primate species, the percentage similarities of the nucleotide sequence of the ZFX gene were 96-100% and 91.2-99.7% for the ZFY gene. Of 397 sites in the ZFX and ZFY gene sequences, 20 for ZFX gene and 42 for ZFY gene were found to be variable. Substitution causes 1 amino acid change in ZFX, and 5 in ZFY, among 132 amino acids. The numbers of synonymous substitutions per site (Ks) between human and the chimpanzee, gorilla and orangutan for ZFY gene were 0.026, 0.033, and 0.085, respectively. In contrast, the Ks value between human and hominoid primates for the ZFX gene was 0.008 for each comparison. Comparison of the ZFX and ZFY genes revealed that the synonymous substitution levels were higher in hominoids than in other primates. The rates of synonymous substitution per site per year were higher in the ZFY exon than in the SRY exon, and higher in the ZFY exon than in the ZFY intron, in hominoid primates.     

Normal structure and expression of Zfy genes in XY female mice mutant in Tdy.

Zfy-1 and Zfy-2 are candidate genes for Tdy, the testis-determining gene in mice. We have analysed these genes in a line of XY female mice that have been shown to be mutated in Tdy. We have used Southern blot analysis to show that the Zfy genes have not undergone any major structural alterations, and have also demonstrated that both genes are transcribed normally from the mutant Y chromosome (Y) in both adult XYY testis and XY female embryonic gonads. The fact that these genes show a normal structure and expression pattern in mice with a Y chromosome known to carry a mutation in Tdy and that mutant embryos develop into females despite Zfy-1 expression, strongly supports other recent evidence that Zfy genes are not directly involved in primary testis determination.     

牦牛与其他物种ZFX/ZFY基因片段间的进化关系

利用PCR扩增、克隆和序列分析法对牦牛ZFX/ZFY基因第11外显子部分片段进行了研究,并同来自于NCBI GenBank中人、猩猩、普通牛等9个物种的ZFX/ZFY基因核苷酸及其氨基酸序列进行了进化分析.结果表明,牦牛ZFX、ZFY基因间核苷酸序列同源性为94.1%,显示同一物种同源基因ZFX/ZFY间存在变异;比较的10个物种间ZFX基因核苷酸序列同源性为87.7%、ZFY基因为81.7%,相应ZFX、ZFY氨基酸同源性分别为96.6%、91.0%,ZFY基因的变异性大于ZFX基因,显示X染色体与Y染色体可能是独立进化.