Characterization and evolution of a single-copy sequence from the human Y chromosome

Molecular features of the TSPY gene of gibbons and Old World monkeys

Restriction pattern, chromosome localization and the sequence of the testis-specific gene, TSPY, were investigated in the white-handed gibbon, agile gibbon, siamang, hamadryas baboon and Japanese monkey. Southern blot analysis showed the TSPY gene to be male specific in the primates used and disclosed variability of restriction pattern in gibbons. Fluorescence in situ hybridization demonstrated that the probe ppTSPY2372, biotinylated using polymerase chain reaction, is located as a slight signal in the proximal long arm of the Y chromosome of the white-handed gibbon, hamadryas baboon and Japanese monkey and in the middle long arm of the Y chromosome of the siamang, while a faint signal and an intense signal were detected in the proximal long arm of the Y chromosome of the aglle gibbon. These findings allow us to speculate that the gibbons might have evolved some structural differentiation in the TSPY gene. The first introns of the TSPY genes were sequenced and compared. One hundred thirty-seven of 606 sites were found to be variable, and 10 deletions/insertions were noted among these gibbons, two species of Old World monkeys and human. Sequence similarity ranged from 81.7% between humans and hamadryas baboons to 98.7% between Japanese monkeys and hamadryas baboons. These sequences may be of great use in future studies for resolving the phylogeny of gibbons and Old World monkeys.

Comparison of human ZFY and ZFX transcripts

ZFY is a candidate for the primary sex-determining gene (TDF, testis-determining factor) on the human Y chromosome. We have isolated cDNA clones of ZFY and its homologue on the X chromosome, ZFX. The transcripts of these genes are very similar to each other and encode predicted proteins of equal size. The conceptual amino acid sequence of both proteins contains an acidic domain, similar to the activation domain of transcription factors, and a potential nucleic acid-binding domain of 13 "zinc fingers." We have used the polymerase chain reaction to demonstrate the expression of ZFY and ZFX in a wide range of adult and fetal human tissues and to show that ZFX is expressed from the inactive X chromosome present in human-mouse hybrids.

A long range restriction map of the pseudoautosomal region by partial digest PFGE analysis from the telomere

The analysis of partial digestion products extending from the telomere of the human X and Y chromosomes, visualised by hybridisation to a probe located close to the telomere, was used to establish a restriction map of the pseudoautosomal region. In this highly polymorphic region with a 10-fold elevated recombination frequency in males we identified site or methylation differences between 7 different in male and female cell lines and tissues, and derived an estimate of the size of the pseudoautosomal region of approximately 3 Megabases by comparing X and Y chromosomes. This size correlates well with previous estimates based on genetic arguments and argues against a strongly enhanced rate of exchange near telomeres in general. We identified a CpG rich and hypomethylated region within 500 kbp from the telomere, which might reflect structural features of mammalian telomeres, and a small number of (additional) CpG islands, which might represent candidate genes for the Turner phenotype in XO females.

Evolution of homologous sequences on the human X and Y chromosomes, outside of the meiotic pairing segment

A sequence isolated from the long arm of the human Y chromosome detects a highly homologous locus on the X. This homology extends over at least 50 kb of DNA and is postulated to be the result of a transposition event between the X and Y chromosomes during recent human evolution, since homologous sequences are shown to be present on the X chromosome alone in the chimpanzee and gorilla.

Isolation of a sequence which maps close to the human sex determining gene

A sequence mapping close to the human sex determining gene (TDF) has been isolated from a lambda library constructed with DNA derived from a chromosome transfectant hybrid cell line. This sequence is shown to be present in the DNA of X-Y interchange males at a very high frequency and, based on these studies, it is categorised with the sequence defined by the probe, GMGY3, as the closest known Y chromosome derived marker to TDF. In contrast to GMGY3, however, this locus shares no homology with any other human chromosome. Southern blot analysis also reveals specific hybridization to the Y chromosome of other primates. It therefore defines, for the first time, a conserved and Y chromosome unique locus that is near to TDF.

Evolution of four human Y chromosomal unique sequences

Four cloned unique sequences from the human Y chromosome, two of which are found only on the Y chromosome and two of which are on both the X and Y chromosomes, were hybridized to restriction enzyme-treated DNA samples of a male and a female chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla), and pig-tailed macaque (Macaca nemestrina); and a male orangutan (Pongo pygmaeus) and gibbon (Hylobates lar). One of the human Y-specific probes hybridized only to male DNA among the humans and great apes, and thus its Y linkage and sequence similarities are conserved. The other human Y-specific clone hybridized to male and female DNA from the humans, great apes, and gibbon, indicating its presence on the X chromosome or autosomes. Two human sequences present on both the X and Y chromosomes also demonstrated conservation as indicated by hybridization to genomic DNAs of distantly related species and by partial conservation of restriction enzyme sites. Although conservation of Y linkage can only be demonstrated for one of these four sequences, these results suggest that Y-chromosomal unique sequence genes do not diverge markedly more rapidly than unique sequences located on other chromosomes. However, this sequence conservation may in part be due to evolution while part of other chromosomes.

Human retroviral sequences on the Y chromosome

Novel endogenous human retroviral sequences were cloned by low-stringency hybridization, using the pol gene of endogenous human retrovirus 51-1. One clone, lambda NP-2, contained gag, pol, env, and long terminal repeat sequences related to the corresponding portions of clone 51-1 and the closely related full-length endogenous human retrovirus 4-1. The sequence of the env gene of NP-2 was 73% homologous to that of 4-1. Genomic Southern blots of male and female DNAs showed that NP-2 is located on the Y chromosome and that the Y chromosome also contains one other sequence closely related to the env and 3' flanking regions of NP-2. Conservation of flanking DNA suggests that the second Y chromosome copy of the NP-2 env sequence arose by gene duplication rather than provirus insertion.

Localisation of Y chromosome sequences in normal and 'XX' males

Three unique sequences derived from the Y chromosome have been mapped within the human genome. A Y specific sequence DYS20 is localised to Yq11.2. DXYS25 and DXYS27 are both X-Y homologous sequences which map to the Y short arm and to Xq21. DXYS25 maps more distally than DXYS27, on the Y short arm and on the X long arm. Y specific restriction fragments for these two sequences are shown to be present in the genome of two XX males, and an aberrant signal for DXYS25 is demonstrated at the tip of an X chromosome short arm in one XX male by in situ hybridisation. The implications of these findings for the location of the testis determining factor are discussed.

Human retroviral sequences on the Y chromosome

Novel endogenous human retroviral sequences were cloned by low-stringency hybridization, using the pol gene of endogenous human retrovirus 51-1. One clone, lambda NP-2, contained gag, pol, env, and long terminal repeat sequences related to the corresponding portions of clone 51-1 and the closely related full-length endogenous human retrovirus 4-1. The sequence of the env gene of NP-2 was 73% homologous to that of 4-1. Genomic Southern blots of male and female DNAs showed that NP-2 is located on the Y chromosome and that the Y chromosome also contains one other sequence closely related to the env and 3' flanking regions of NP-2. Conservation of flanking DNA suggests that the second Y chromosome copy of the NP-2 env sequence arose by gene duplication rather than provirus insertion.

Moderately repeated mouse Y chromosomal sequence families present distinct types of organization and evolutionary change

Male specific repeated sequences compose approximately 10% of the mouse Y chromosome. This was deduced from studies of genomic phage clones that contain male specific DNA, and three subcloned EcoRI fragments pBC10-0.6, pBC15-1.1, and pBA33-1.8. Southern analyses and in situ hybridization of metaphase chromosomes show these three sequences to be present in 100-200 copies on the Y chromosome and in female DNA as single copies. One of these, pBC10-0.6, was directly demonstrated to be on the X chromosome. All three exhibited male specific transcription. These sequences are found in two distinct organizations. Subclone pBC10-0.6 is uniformly found in a long HpaI repeat unit of 9.7 Kbp. Subclones pBC15-1.1 and pBA33-1.8 are distributed throughout several EcoR1 repeat families in which the male specific fragments are interspersed. These male specific fragments also differ among themselves with regard to the types and frequency of evolutionary changes.

Regional assignment of Y-linked DNA probes by deletion mapping and their homology with X-chromosome and autosomal sequences

A series of Y recombinants have been isolated from Y-specific DNA libraries and regionally located on the Y chromosome using a Y deletion panel constructed from individuals carrying structural abnormalities of the Y chromosome. Of twenty recombinants examined twelve have been assigned to Yp and eight to Yq. Five of the Yp recombinants map between Yp11.2 and Ypter and one can only be assigned to Yp. Of the former, four detect homologies on the X chromosome between Xq13 and Xq24 and the latter one between Xp22.3 and Xpter. The sixth recombinant detects autosomal homologous sequences. The six remaining Yp probes are located between Ycen and Yp11.2. One of these detects a homology on the X chromosome at Xq13-Xq24 and a series of autosomal sequences, two detect uniquely Y-specific sequences and three a complex pattern of autosomal homologies. The remaining eight recombinants have been assigned to three intervals on Yq. Of three recombinants located between Ycen and Yq11.21 two detect only Y sequences and one additional autosomal homologies. Two recombinants lie in the interval Yq11.21-Yq11-22, one of which detects only Y sequences and the other an Xp homology between Xp22.3 and Xpter. Finally, the three remaining Yq recombinants all detect autosomal homologies and are located between Yq11.22 and Yq12. The divergence between homologies on different chromosomes has been examined for three recombinants by washing Southern Blots at different levels of stringency. Additionally, Southern analysis of DNA from flow sorted chromosomes has been used to identify autosomes carrying homologies to two of the Y recombinants.

The human Y chromosome

Despite its central role in sex determination, genetic analysis of the Y chromosome has been slow. This poor progress has been due to the paucity of available genetic markers. Whereas the X chromosome is known to include at least 100 functional genetic loci, only three or four loci have been ascribed to the Y chromosome and even the existence of several of these loci is controversial. Other factors limiting genetic analysis are the small size of the Y chromosome, which makes cytogenetic definition difficult, and the absence of extensive recombination. Based on cytogenetic observation and speculation, a working model of the Y chromosome has been proposed. In this classical model the Y chromosome is defined into subregions; an X-Y homologous meiotic pairing region encompassing most of the Y chromosome short arm and, perhaps, including a pseudoautosomal region of sex chromosome exchange; a pericentric region containing the sex determining gene or genes; and a long arm heterochromatic genetically inert region. The classical model has been supported by studies on the MIC2 loci, which encode a cell surface antigen defined by the monoclonal antibody 12E7. The X linked locus MIC2X, which escapes X inactivation, maps to the tip of the X chromosome short arm and the homologous locus MIC2Y maps to the Y chromosome short arm; in both cases, these loci are within the proposed meiotic pairing region. MIC2Y is the first biochemically defined, expressed locus to be found on the human Y chromosome. The proposed simplicity of the classical model has been challenged by recent molecular analysis of the Y chromosome. Using cloned probes, several groups have shown that a major part of the Y chromosome short arm is unlikely to be homologous to the X chromosome short arm. A substantial block of sequences of the short arm are homologous to sequences of the X chromosome long arm but well outside the pairing region. In addition, the short arm contains sequences shared with the Y chromosome long arm and sequences shared with autosomes. About two-thirds of XX males contain detectable Y derived sequences. As the amount of Y sequences present varies in different XX males, DNA from these subjects can be used to construct a map of the region around the sex determining gene. Assuming that XX males are usually caused by simple translocation, the sex determining genes cannot be located in the pericentric region. Although conventional genetic analysis of the Y chromosome is difficult, this chromosome is particularly suited to molecular analysis. Paradoxically, the Y chromosome may soon become the best defined human chromosome at the molecular level and may become the model for other chromosomes.