Ullrich-Turner syndrome is not caused by haploinsufficiency of RPS4X

Ullrich-Turner syndrome (UTS) is frequently associated with monosomy X but may also occur with structural aberrations of the X and the Y chromosomes. It has been hypothesized that the ribosomal protein genes RPS4X and RPS4Y play a critical role in the prevention of UTS. Individual patients with a 46,X,i(Xq) karyotype cannot be differentiated phenotypically from 45,X UTS patients and carry three gene copies of RPS4X. Since haploinsufficiency of one or several gene(s) is thought to cause the UTS phenotype, direct assessment of RPS4X expression levels in these patients should establish whether RPS4X is involved in UTS. We have investigated fibroblasts of four 46,X,i(Xq) UTS patients with typical symptoms and a non-mosaic chromosome complement, and have found significantly increased RPS4X mRNA levels in all patients. Based on our results, we conclude that haploinsufficiency of RPS4X is not the cause of UTS.     

Trimethylation of Histone H3 Lysine 4 is an Epigenetic Mark at Regions Escaping Mammalian X Inactivation

It is now estimated that 150-200 genes clustered in several discrete regions escape X inactivation in somatic cells of human females by unknown mechanisms. Here, we show that although the human female inactive X chromosome is largely devoid of histone 3 lysine 4 trimethylation (H3K4me3), regions that are known to escape X inactivation, including the pseudoautosomal regions, are enriched with this modification. Also, H3K4me3, unlike H3K4me2 and H4 and H3 acetylation, is restricted to discrete regions on metaphase chromosomes. In contrast to humans, there are only a few genes that are known to escape X inactivation in the mouse. Therefore, we examined mouse female somatic cells with H3K4me3 to identify candidate regions with genes that escape X inactivation. We found the mouse female inactive X in somatic cells and the male inactive X in meiosis to have seven discrete regions that are enriched with H3K4me3. Furthermore, RNA polymerase II is largely excluded from the XY body at male pachytene except for several discrete regions on the X and Y suggesting the presence of regions that also escape sex chromosome inactivation during male meiosis.     

The minimal mammalian Y chromosome - the marsupial Y as a model system

The mammalian X and Y chromosomes are very different in size and gene content. The Y chromosome is much smaller than the X and consists largely of highly repeated non-coding DNA, containing few active genes. The 65-Mb human Y is homologous to the X over two small pseudoautosomal regions which together contain 13 active genes. The heterochromatic distal half of the human Yq is entirely composed of highly repeated non-coding DNA, and even the euchromatic portion of the differential region is largely composed of non-coding repeated sequences, amongst which about 30 active genes are located. The basic marsupial Y chromosome (about 10 Mb) is much smaller than that of humans or other eutherian mammals. It appears to include no PAR, since it does not undergo homologous pairing, synaptonemal complex formation or recombination with the X. We show here that the tiny dunnart Y chromosome does not share cytogenetically detectable sequences with any other chromosome, suggesting that it contains many fewer repetitive DNA sequences than the human or mouse Y chromosomes. However, it shares several genes with the human and/or mouse Y chromosome, including the sex determining gene SRY and the candidate spermatogenesis gene RBMY, implying that the marsupial and eutherian Y are monophyletic. This minimal mammalian Y chromosome might provide a good model Y in which to hunt for new mammalian Y specific genes.     

X chromosome inactivaton and SV40 transformation of mammalian cells.

Five embryonic mouse cultures and one human fibroblast culture were transformed with SV40. The cultures were studied cytologically to see if the normal pattern of sex chromosome replication was maintained in SV40 transformed cells. Characteristic late replication patterns were observed for both the X and Y chromosomes, and there was no evidence for loss of the inactive X chromosome, even in cells with 4 or more X chromosomes. The human line was heterozygous at two X-linked loci and a clonal analysis showed that the expression of X-linked genes was not affected by SV40 transformation.     

Analysis of methylation of a human X located gene which escapes X inactivation.

The gene MIC2 is located in the pseudoautosomal region at the ends of the short arms of the X and Y chromosomes. In females MIC2 escapes X inactivation. We have analyzed the methylation pattern of MIC2 on the active X, the inactive X chromosomes, and the Y chromosome. The 5' end of the gene contains a GC rich region which is unmethylated on the active X, the inactive X and on the Y. The body of the gene is characterized by variable methylation.     

The cell surface antigen locus, MIC2X, escapes X-inactivation

Recently, it was shown that the cell surface antigen defined by the monoclonal antibody 12E7 is expressed by both the human X and Y chromosomes; the gene loci on the X and Y chromosomes are referred to as MIC2X and MIC2Y, respectively. It was also shown that MIC2X is located in the region Xp22.3----Xpter and MIC2Y is in the region Ypter-Yq1.1. Here, we show that MIC2X escapes X-inactivation on structurally normal and abnormal inactive human X chromosomes.     

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.     

The human X-linked steroid sulfatase gene and a Y-encoded pseudogene: evidence for an inversion of the Y chromosome during primate evolution

The mammalian X and Y chromosomes are thought to have evolved from a common, nearly homologous chromosome pair. Although there is little sequence similarity between the mouse or the human X and Y, there are several regions in which moderate to extensive sequence homologies have been found, including, but not limited to, the so-called pseudoautosomal segment, in which X-Y pairing and recombination take place. The steroid sulfatase gene is in the pseudoautosomal region of the mouse, but not in man. We have cloned and characterized the human STS X-encoded locus and a pseudogene that is present on the long arm of the Y chromosome. Our data in humans and other primates suggest that there has been a pericentric inversion of the Y chromosome during primate evolution that has disrupted the former pseudoautosomal arrangement of these genes. These results provide additional insight into the evolution of the sex chromosomes and into the nature of this interesting portion of the human genome.     

Function of the sex chromosomes in mammalian fertility

The sex chromosomes play a highly specialized role in germ cell development in mammals, being enriched in genes expressed in the testis and ovary. Sex chromosome abnormalities (e.g., Klinefelter [XXY] and Turner [XO] syndrome) constitute the largest class of chromosome abnormalities and the commonest genetic cause of infertility in humans. Understanding how sex-gene expression is regulated is therefore critical to our understanding of human reproduction. Here, we describe how the expression of sex-linked genes varies during germ cell development; in females, the inactive X chromosome is reactivated before meiosis, whereas in males the X and Y chromosomes are inactivated at this stage. We discuss the epigenetics of sex chromosome inactivation and how this process has influenced the gene content of the mammalian X and Y chromosomes. We also present working models for how perturbations in sex chromosome inactivation or reactivation result in subfertility in the major classes of sex chromosome abnormalities.     

Novel gene acquisition on carnivore Y chromosomes

Despite its importance in harboring genes critical for spermatogenesis and male-specific functions, the Y chromosome has been largely excluded as a priority in recent mammalian genome sequencing projects. Only the human and chimpanzee Y chromosomes have been well characterized at the sequence level. This is primarily due to the presumed low overall gene content and highly repetitive nature of the Y chromosome and the ensuing difficulties using a shotgun sequence approach for assembly. Here we used direct cDNA selection to isolate and evaluate the extent of novel Y chromosome gene acquisition in the genome of the domestic cat, a species from a different mammalian superorder than human, chimpanzee, and mouse (currently being sequenced). We discovered four novel Y chromosome genes that do not have functional copies in the finished human male-specific region of the Y or on other mammalian Y chromosomes explored thus far. Two genes are derived from putative autosomal progenitors, and the other two have X chromosome homologs from different evolutionary strata. All four genes were shown to be multicopy and expressed predominantly or exclusively in testes, suggesting that their duplication and specialization for testis function were selected for because they enhance spermatogenesis. Two of these genes have testis-expressed, Y-borne copies in the dog genome as well. The absence of the four newly described genes on other characterized mammalian Y chromosomes demonstrates the gene novelty on this chromosome between mammalian orders, suggesting it harbors many lineage-specific genes that may go undetected by traditional comparative genomic approaches. Specific plans to identify the male-specific genes encoded in the Y chromosome of mammals should be a priority.