Evolutionary dynamics of the human pseudoautosomal regions

Recombination between the X and Y human sex chromosomes is limited to the two pseudoautosomal regions (PARs) that present quite distinct evolutionary origins. Despite the crucial importance for male meiosis, genetic diversity patterns and evolutionary dynamics of these regions are poorly understood. In the present study, we analyzed and compared the genetic diversity of the PAR regions using publicly available genomic sequences encompassing both PAR1 and PAR2. Comparisons were performed through allele diversities, linkage disequilibrium status and recombination frequencies within and between X and Y chromosomes. In agreement with previous studies, we confirmed the role of PAR1 as a male-specific recombination hotspot, but also observed similar characteristic patterns of diversity in both regions although male recombination occurs at PAR2 to a much lower extent (at least one recombination event at PAR1 and in ≈1% in normal male meioses at PAR2). Furthermore, we demonstrate that both PARs harbor significantly different allele frequencies between X and Y chromosomes, which could support that recombination is not sufficient to homogenize the pseudoautosomal gene pool or is counterbalanced by other evolutionary forces. Nevertheless, the observed patterns of diversity are not entirely explainable by sexually antagonistic selection. A better understanding of such processes requires new data from intergenerational transmission studies of PARs, which would be decisive on the elucidation of PARs evolution and their role in male-driven heterosomal aneuploidies.     

Arrangement and localization of the human GM-CSF receptor alpha chain gene CSF2RA within the X-Y pseudoautosomal region.

The gene encoding one subunit of the receptor for the hemopoietic growth factor, GM-CSF, has been previously localized to the short arm of the human sex chromosomes. By pulsed-field gel electrophoresis, the precise localization of this gene, CSF2RA, within the pseudoautosomal region has been determined. The gene is located 1180 to 1300 kb from the telomere, in close proximity to the CpG island B5. The CSF2RA gene spans at least 45 kb, and a representation of most of the gene on three overlapping cosmid clones has been obtained. The exon(s) encoding the first 35 bp of cDNA sequence lies outside these cosmids. The CSF2RA gene is characterized by abundant hypervariable sequences, and a number of informative restriction fragment length polymorphisms have been defined.     

人类性染色体拟常染色体区的研究进展

拟常染色体区是性染色体上的重要区域,对于维持性染色体结构与功能、保证性染色体在减数分裂过程中正常配对与分离具有重要意义。拟常染色体区与常染色体结构与功能的异同点也为了解性染色体的起源与进化提供了很好的材料。人类的拟常染色体区由PAR1和PAR2两个区域组成,这两个区域在结构上有明显不同。位于其上的基因虽然不多,但与许多遗传疾病相关,详细研究该区的基因与疾病的关系还有助于尽早诊断并防治与之相关的遗传疾病。本文全面综述了人类性染色体拟常染色体区的最新研究进展。     

The pseudoautosomal regions of the human sex chromosomes

In human females, both X chromosomes are equivalent in size and genetic content, and pairing and recombination can theoretically occur anywhere along their entire length. In human males, however, only small regions of sequence identity exist between the sex chromosomes. Recombination and genetic exchange is restricted to these regions of identity, which cover 2.6 and 0.4 Mbp, respectively, and are located at the tips of the short and the long arm of the X and Y chromosome. The unique biology of these regions has attracted considerable interest, and complete long-range restriction maps as well as comprehensive physical maps of overlapping YAC clones are already available. A dense genetic linkage map has disclosed a high rate of recombination at the short arm telomere. A consequence of the obligatory recombination within the pseudoautosomal region is that genes show only partial sex linkage. Pseudoautosomal genes are also predicted to escape X-inactivation, thus guaranteeing an equal dosage of expressed sequences between the X and Y chromosomes. Gene pairs that are active on the X and Y chromosomes are suggested as candidates for the phenotypes seen in numerical X chromosome disorders, such as Klinefelter's (47,XXY) and Turner's syndrome (45,X). Several new genes have been assigned to the Xp/Yp pseudoautosomal region. Potential associations with clinical disorders such as short stature, one of the Turner features, and psychiatric diseases are discussed. Genes in the Xq/Yq pseudoautosomal region have not been identified to date.     

Toxoplasma gondii: microneme protein MIC2

The phylum Apicomplexa contains parasites responsible for a variety of diseases including malaria, cryptosporidiosis, and toxoplasmosis. One of the common features of these parasites is that they contain a set of apical organelles whose sequential secretion is required for the invasion of host cells. Microneme proteins are the main adhesins involved in the attachment to the host cell surface by apicomplexans. The microneme protein MIC2, produced by Toxoplasma gondii, is conserved in apicomplexans and serves as a model to understand the first steps of invasion by the phylum. New data about the structure-function relationship of MIC2 reinforce the critical role of this protein in the successful invasion of cells by Toxoplasma and reveal potential therapeutic targets that may be used to control toxoplasmosis.     

High mutation rates in human and ape pseudoautosomal genes

It has been suggested that recombination may be mutagenic, which, if true, would inflate intraspecies diversity and interspecies silent divergence in regions of high recombination. Here, we test this hypothesis comparing human/orangutan genome-wide non-coding divergence (K) to that in the pseudoautosomal genes which were reported to recombine much more frequently than the rest of the genome. We demonstrate that, compared to the average human/orangutan non-coding divergence (K=3%), the substitution rate is significantly elevated in the introns of SHOX (K=5.7%), PPP2R3L (K=8.7%) and ASMT (K=6.5%) genes located in the human and orangutan Xp/Yp pseudoautosomal region (p-PAR), where recombination is over 20-fold higher than the genomic average. On the other hand, human/orangutan non-coding divergence at the Xp/Yp pseudoautosomal boundary (K=3.5%) and in the SYBL1 gene (K=2.7%), located in the human Xq/Yq pseudoautosomal region (q-PAR), where recombination is known to be less frequent than in p-PAR, was not significantly higher than the genome average. The data are consistent with the hypothesis that recombination may be mutagenic.     

Elevated DNA sequence diversity in the genomic region of the phosphatase PPP2R3L gene in the human pseudoautosomal region

The evolution, inheritance and recombination rate of genes located in the pseudoautosomal region 1 (PAR1) is exceptional within the human genome. Pseudoautosomal genes are identical on X and Y chromosomes and are not inherited in a sex linked manner. Due to an obligatory recombination event in male meiosis, pseudoautosomal genes are exchanged frequently between X and Y chromosomes. During the isolation, characterization and sequencing of a novel gene PPP2R3L, which was classified by sequence homology as a novel member of the protein phosphatase regulatory subunit families, it became apparent that cosmids of different origin harboring this gene are highly polymorphic between individuals, both at the nucleotide level and in the number.     

A physical map of the human pseudoautosomal region.

A physical map of the human pseudoautosomal region has been constructed using pulsed field gel electrophoresis and the infrequently cutting restriction enzymes BssHIII, EagI, SstII, NotI, MluI and NruI. This map extends 2.3 Mbp from the telomere to sex-chromosome-specific DNA, includes at least seven CpG islands and locates four genetically mapped loci. Five of the CpG islands are organized into two clusters. One cluster is adjacent to the telomere, the other extends into sex-chromosome-specific DNA. There is congruence between the genetic and physical maps which implies that the frequency of recombination is approximately uniform throughout the DNA.     

Recombination, GC-content and the human pseudoautosomal boundary paradox

The pseudoautosomal boundary of mammalian sex chromosomes separates a low-recombination region (X- or Y-specific) from a high-recombination region (the pseudoautosomal region), providing a good opportunity to investigate the influence of recombination on molecular evolutionary processes. The mouse and human patterns of sequence variation, however, are discordant: a striking difference of GC-content and evolutionary rate was reported between the proximal and distal sides of the pseudoautosomal boundary in the mouse genome, whereas this difference was not found in the human genome. The paradox might be explained by the mirror histories of the pseudoautosomal boundary in the two species, and by the asymmetric nature of the forces driving GC-content evolution in mammalian genomes.     

Structural Basis of Toxoplasma gondii MIC2-associated Protein Interaction with MIC2

Toxoplasma gondii parasites must actively invade host cells to propagate. Secretory microneme proteins have been shown to be important for both gliding motility and active invasion. MIC2-M2AP is a protein complex that is essential for productive motility and rapid invasion by binding to host cell surface receptors. To investigate the architecture of the MIC2 and M2AP complex, we identified the minimal domains sufficient for interaction and solved the NMR solution structure of the globular domain of M2AP. We found that M2AP adopts a modified galectin fold similar to the C-terminal domain of another microneme protein, MIC1. NMR and immunoprecipitation analyses implicated hydrophobic residues on one face of the M2AP galectin fold in binding to the membrane proximal sixth thrombospondin type I repeat domain of MIC2. Our findings provide a second example of a galectin fold adapted for microneme protein-protein interactions and suggest a conserved strategy for the assembly and folding of diverse protein complexes.     

Cell surface differentiation antigen of human muscle encoded by a gene (MIC12) on chromosome 15

Monoclonal antibody 30.2A8 was produced by a hybridoma made by fusing cells from rats that had been immunized with rat-human muscle cell hybrids. The 30.2A8 reacts with a differentiation antigen in human skeletal muscle that is synthesized by myoblasts but not myotubes. The gene controlling synthesis of the antigen recognized by 30.2A8 was found to be encoded by human chromosome 15.     

A VNTR immediately adjacent to the human pseudoautosomal telomere.

The probe 29C1 detects a hypervariable locus 18kb from the telomere of the human X and Y chromosomes, in the pseudoautosomal region. Here we report that hypervariability of fragments containing this sequence in the human population arises by loss or gain of a 31 base pair GC rich repeat. Labelled 29C1 does not detect a DNA fingerprint at low stringency, though the consensus repeat sequence does show some similarity to previously reported minisatellites. Sequence within the repeat block has G and C rich strands, a feature associated with sequences at the telomeres of many higher organisms. The repeat block shows sequence characteristics normally associated with a low methylation island, though the locus is methylated and does not appear to be transcribed.     

The gene for catalase is assigned between the antigen loci MIC4 and MIC11

Genetic analysis of the cells of a WAGR patient (W, predisposition to Wilms tumor; A, aniridia; G, genitourinary abnormalities; R, mental retardation), bearing a partial deletion of band 11p13, was performed with biochemical and antigenic 11p markers by using gene dosage, somatic hybridization, molecular hybridization, and indirect immunofluorescence techniques. These studies allowed the regional assignment of the gene for catalase, which is linked to the Wilms tumor locus, between MIC4 and MIC11, two loci encoding for membrane antigens previously mapped to band 11p13.     

Rapid evolution of human pseudoautosomal genes and their mouse homologs

Comparative studies of genes in the pseudoautosomal region (PAR) of human and mouse sex chromosomes have thus far been very limited. The only comparisons that can presently be made indicate that the PARs of humans and mice are not identical in terms of gene content. Here we describe additional comparative studies of human pseudoautosomal genes and their mouse homologs. Using a somatic cell hybrid mapping panel, we have assigned the mouse homolog of the human pseudoautosomal interleukin 3 receptor alpha subunit (IL3RA) gene to mouse Chromosome (Chr) 14. Attempts to clone the mouse homolog of the human pseudoautosomal adenine nucleotide translocase-3 (ANT3) gene resulted in the isolation of the murine homologs of the human ANT1 and ANT2 genes. The mouse Ant1 and Ant2 genes are very similar in sequence to their human homologs, and we have mapped them to mouse Chromosomes (Chrs) (8 and X respectively) that exhibit conserved synteny with the chromosomes on which the human genes are located. In contrast, the homolog of ANT3 appears to be either very divergent or absent from the mouse genome. Southern blot analysis of DNA from a variety of mammalian species shows restricted conservation of human pseudoautosomal genes, a trend that also applies to the two cloned mouse homologs of these genes and to neighboring human genes in distal Xp22.3. Our observations combined with those of other workers lead us to propose a model for the evolution of the PAR that includes both rapid sequence evolution and the incremental reduction in size of the region during mammalian evolution. Received: 4 May 1995 / Accepted: 21 August 1995     

A gradient of silent substitution rate in the human pseudoautosomal region

It has been demonstrated that recombination in the human p-arm pseudoautosomal region (p-PAR) is at least twenty times more frequent than the genomic average of approximately 1 cM/Mb, which may affect substitution patterns and rates in this region. Here I report the analysis of substitution patterns and rates in 10 human, chimpanzee, gorilla, and orangutan genes across the p-PAR. Between species silent divergence in the p-PAR forms a gradient, increasing toward the telomere. The correlation of silent divergence with distance from the p-PAR boundary is highly significant (rho = 0.911, P < 0.001). After exclusion of the CpG dinucleotides this correlation is still significant (rho = 0.89, P < 0.01), thus the substitution rate gradient cannot be explained solely by the differences in the extent of methylation across the p-PAR. Frequent recombination in the PAR may result in a relatively strong effect of biased gene conversion (BGC), which, because of the increased probability of fixation of the G or C nucleotides at (A or T)/(G or C) segregating sites, may affect substitution rates. BGC, however, does not seem to be the factor creating the substitution rate gradient in the p-PAR, because the only gradient is still detactable if only A<-->T and G<-->C substitutions are taken into account (rho = 0.82, P < 0.01). I hypothesize that the substitution rate gradient in the p-PAR is due to the mutagenic effect of recombination, which is very frequent in the distal human p-PAR and might be lower near the p-PAR boundary.     

The E2 antigen, a 32 kd glycoprotein involved in T-cell adhesion processes, is the MIC2 gene product.

E2 is a 32 kd human T-cell surface glycoprotein involved in spontaneous rosette formation with erythrocytes. A 1.11 kb cDNA was isolated from a lambda gt11 expression library by screening with monoclonal antibodies directed against E2. The primary structure of E2, deduced from the nucleotide sequence of its gene, comprises 185 amino acids and is devoid of N-linked glycosylation sites. The E2 protein is rich in proline residues and displays an organization typical of an integral membrane protein. Northern blotting showed a good correlation between mRNA abundance, E2 surface density and the level of T cell differentiation. In fact, nucleotide sequencing revealed that E2 is the MIC2 gene product, previously identified with the 12E7 Mab. Xg(a-) female individuals have no E2 molecule on the surface of their red cells, in contrast with Xg(a+) individuals, but have the molecule in their cytoplasm, in the form of the 28 kd precursor. These findings show that the E2 antigen, a cell surface molecule involved in T cell adhesion processes, is the product of the MIC2 gene, the only pseudoautosomal gene to be described in man.     

Klinefelter's syndrome as a model of anomalous cerebral laterality: Testing gene dosage in the X chromosome pseudoautosomal region using a DNA microarray

Consistent handedness and language laterality are two of the most striking behavioral and cognitive asymmetries observed in humans. Alterations in the typical pattern of cerebral laterality, termed “anomalous dominance,” is observed in left-handers and some patients with verbal learning disabilities. We undertook the study of a genetically distinct group of subjects, XXY males (Klinefelter's syndrome; KS), who demonstrate anomalous dominance in a variety of testing paradigms in order to begin to elucidate the molecular basis of anomalous dominance in this population. KS subjects manifest specific verbal learning disability, evidence of altered functional laterality for phonologic processing, and an increase in left-handedness when measured by skill. It is proposed that an alteration in gene dosage in the pseudoautosomal region (PAR) of the sex chromosomes is the most likely explanation for anomalous dominance in these patients. This is especially intriguing in light of previously described genetic models of cerebral laterality that suggest a contributing locus in the PAR, or adjacent high homology regions of the X chromosome. We have developed an ordered DNA microarray covering the X chromosome PAR at high resolution for hybridization with two-color fluorescently labeled probes. We demonstrate the ability to detect changes in hybridization signal that will facilitate efficient large-scale screening of this region for alterations in gene dosage associated with features of anomalous dominance and other cognitive or behavioral phenotypes. Dev. Genet. 23:215–229, 1998. © 1998 Wiley-Liss, Inc.     

Toxoplasma MIC2 is a major determinant of invasion and virulence

Like its apicomplexan kin, the obligate intracellular protozoan Toxoplasma gondii actively invades mammalian cells and uses a unique form of gliding motility. The recent identification of several transmembrane adhesive complexes, potentially capable of gripping external receptors and the sub-membrane actinomyosin motor, suggests that the parasite has multiple options for host-cell recognition and invasion. To test whether the transmembrane adhesin MIC2, together with its partner protein M2AP, participates in a major invasion pathway, we utilized a conditional expression system to introduce an anhydrotetracycline-responsive mic2 construct, allowing us to then knockout the endogenous mic2 gene. Conditional suppression of MIC2 provided the first opportunity to directly determine the role of this protein in infection. Reduced MIC2 expression resulted in mistrafficking of M2AP, markedly defective host-cell attachment and invasion, the loss of helical gliding motility, and the inability to support lethal infection in a murine model of acute toxoplasmosis. Survival of mice infected with MIC2-deficient parasites correlated with lower parasite burden in infected tissues, an attenuated inflammatory immune response, and induction of long-term protective immunity. Our findings demonstrate that the MIC2 protein complex is a major virulence determinant for Toxoplasma infection and that MIC2-deficient parasites constitute an effective live-attenuated vaccine for experimental toxoplasmosis.