Identification of two novel proteins that interact with germ-cell-specific RNA-binding proteins DAZ and DAZL1

The human DAZ (deleted in azoospermia) gene family on the Y chromosome and an autosomal DAZ-like gene, DAZL1, encode RNA-binding proteins that are expressed exclusively in germ cells. Their role in spermatogenesis is supported by their homology with a Drosophila male infertility gene boule and sterility of Daz11 knock-out mice. While all mammals contain a DAZL1 homologue on their autosomes, DAZ homologues are present only on the Y chromosomes of great apes and Old World monkeys. The DAZ and DAZL1 proteins differ in the copy numbers of a DAZ repeat and the C-terminal sequences. We studied the interaction of DAZ and DAZL1 with other proteins as an approach to investigate functional similarity between these two proteins. Using DAZ as bait in a yeast two-hybrid system, we isolated two DAZAP (DAZ-associated protein) genes. DAZAP1 encodes a novel RNA-binding protein that is expressed most abundantly in the testis, and DAZAP2 encodes a ubiquitously expressed protein with no recognizable functional motif. DAZAP1 and DAZAP2 bind similarly to both DAZ and DAZL1 through the DAZ repeats. The DAZAP genes were mapped to chromosomal regions 19p13.3 and 2q33-q34, respectively, where no genetic diseases affecting spermatogenesis are known to map.     

DAZ family proteins exist throughout male germ cell development and transit from nucleus to cytoplasm at meiosis in humans and mice

The human DAZ gene family is expressed in germ cells and consists of a cluster of nearly identical DAZ (deleted in azoospermia) genes on the Y chromosome and an autosomal homolog, DAZL (DAZ-like). Only the autosomal gene is found in mice. Y-chromosome deletions that encompass the DAZ genes are a common cause of spermatogenic failure in men, and autosomal homologs of DAZ are essential for testicular germ cell development in mice and DROSOPHILA: Previous studies have reported that mouse DAZL protein is strictly cytoplasmic and that human DAZ protein is restricted to postmeiotic cells. By contrast, we report here that human DAZ and human and mouse DAZL proteins are present in both the nuclei and cytoplasm of fetal gonocytes and in spermatogonial nuclei. The proteins relocate to the cytoplasm during male meiosis. Further observations using human tissues indicate that, unlike DAZ, human DAZL protein persists in spermatids and even spermatozoa. These results, combined with findings in diverse species, suggest that DAZ family proteins function in multiple cellular compartments at multiple points in male germ cell development. They may act during meiosis and much earlier, when spermatogonial stem cell populations are established.     

Primate evolution of the alpha-globin gene cluster and its Alu-like repeats

The arrangement of alpha-globin genes in Old World and New World monkeys and a prosimian, galago, has been determined by restriction mapping. Recombinant DNAs containing galago and Old World monkey alpha-globin genes have been isolated and subjected to a partial sequence determination for comparison to alpha-globin genes in human, chimpanzee and non-primate mammals. The results of this extensive structural analysis are relevant to several topics concerning the evolution of primate alpha-globin genes and Alu family repeats. All orders of higher primates (i.e. Old and New World monkeys, chimpanzee and human) have the same arrangement of alpha-globin genes. In contrast, the arrangement and correction of galago alpha-globin genes differ from those of higher primates, but are similar to those of non-primate mammals. The 5' and 3'-flanking regions of the human alpha 1 gene are orthologous to the corresponding region in galago, identifying the human alpha 2 gene as the more recently duplicated gene. The human psi alpha 1 gene is found to be inactivated after divergence of the human and galago lineages but prior to the divergence of human and monkey. Orthologous Alu family members in human and monkey DNAs indicate that the dispersion of some Alu repeats occurred prior to the divergence of these lineages. However, the Alu-like repeats of prosimian and higher primates result from entirely independent events giving rise to different repeat elements inserted at distinct genomic positions.     

Association of the mouse infertility factor DAZL1 with actively translating polyribosomes

The DAZ (Deleted in AZoospermia) gene family was isolated from a region of the human Y chromosome long arm that is deleted in about 10% of infertile men with idiopathic azoospermia. DAZ and an autosomal DAZ-like gene, DAZL1, are expressed in germ cells only. They encode proteins with an RNA recognition motif and with either a single copy (in DAZL1) or multiple copies (in DAZ) of a DAZ repeat. A role for DAZL1 and DAZ in spermatogenesis is supported by their homology to a Drosophila male infertility protein Boule and by sterility of Dazl1 knock-out mice. The biological function of these proteins remains unknown. We found that DAZL1 and DAZ bound similarly to various RNA homopolymers in vitro. We also used an antibody against the human DAZL1 to determine the subcellular localization of DAZL1 in mouse testis. The sedimentation profiles of DAZL1 in sucrose gradients indicate that DAZL1 is associated with polyribosomes, and further capture of DAZL1 on oligo(dT) beads demonstrates that the association is mediated through the binding of DAZL1 to poly(A) RNA. Our results suggest that DAZL1 is involved in germ-cell specific regulation of mRNA translation.     

Ancestry of a human endogenous retrovirus family.

The human endogenous retrovirus type II (HERVII) family of HERV genomes has been found by Southern blot analysis to be characteristic of humans, apes, and Old World monkeys. New World monkeys and prosimians lack HERVII proviral genomes. Cellular DNAs of humans, common chimpanzees, gorillas, and orangutans, but not lesser ape lar gibbons, appear to contain the HERVII-related HLM-2 proviral genome integrated at the same site (HLM-2 maps to human chromosome 1). This suggests that the ancestral HERVII retrovirus(es) entered the genomes of Old World anthropoids by infection after the divergence of New World monkeys (platyrrhines) but before the evolutionary radiation of large hominoids.     

Evolution of a repeat sequence in the parathyroid hormone-related peptide gene in primates

A polymorphism of the variable number of tandem repeat (VNTR) type is located 97 bp downstream of exon VI of the parathyroid hormone-related peptide (PTHrP) gene in humans. The repeat unit has the general sequence G(TA)_nC, where n equals 4–11. In order to characterize the evolutionary history of this VNTR, we initially tested for its presence in 13 different species representing four main groups of living primates. The sequence is present in the human, great apes, and Old World monkeys, but not in New World monkeys; and this region failed to PCR amplify in the Loris group. Thus, the evolution of the sequence as part of the PTHrP gene started at least 25–35 millions years ago, after divergence of the Old World and New World monkeys, but before divergence of Old World monkeys and great apes and humans. The structural changes occurring during evolution are characterized by a relatively high degree of sequence divergence. In general, the tandem repeat region tends to be longer and more complex in higher primates with the repeat unit motifs all being based on a TA-dinucleotide repeat sequence. Intra-species variability of the locus was demonstrated only in humans and gorilla. The divergence of the TA-dinucleotide repeat sequence and the variable mutation rates observed in different primate species are in contrast to the relative conservation of the flanking sequences during primate evolution. This suggests that the nature of the TA-dinucleotide repeat sequence, rather than its flanking sequences, is responsible for generating variability. Particular features of the sequence may allow it to form stable secondary structures during DNA replication, and this, in turn, could promote slipped-strand mispairing to occur.     

On the loss of uricolytic activity during primate evolution--I. Silencing of urate oxidase in a hominoid ancestor

Urate oxidase activity is not detectable in liver homogenates from the gibbon, orangutan, chimpanzee, gorilla and human. Liver homogenates from five genera of Old World and two genera of New World monkeys have easily detectable levels of urate oxidase activity. There is no evidence for extant detectable intermediate steps in the loss of urate oxidase activity in the hominoids. Urate oxidase activity from Old World and New World monkeys is stable, a simple observation which debunks a long-standing myth. Urate oxidase activity was silenced in an ancestor to the five living genera of hominoids after divergence from the Old World monkeys.     

Molecular evolution of the psi eta-globin gene locus: gibbon phylogeny and the hominoid slowdown

An 8.4-kb genomic region spanning both the psi eta-globin gene locus and flanking DNA was sequenced from the common gibbon (Hylobates lar). In addition, sequencing of the entire orthologous region from galago (Galago crassicaudatus) was completed. The gibbon and galago sequences, along with published orthologous sequences from 10 other species, were aligned. These noncoding nucleotide sequences represented four human alleles, four apes (chimpanzee, gorilla, organgutan, and gibbon), an Old World monkey (rhesus monkey), two New World monkeys (spider and owl monkeys), tarsier, two strepsirhines (galago and lemur), and goat. Divergence and maximum parsimony analyses of the psi eta genomic region first groups humans and chimpanzees and then, at progressively more ancient branch points, successively joins gorillas, orangutans, gibbons, Old World monkeys, New World monkeys, tarsiers, and strepsirhines (the lemuriform-lorisiform branch of primates). This cladistic pattern supports the taxonomic grouping of all extant hominoids into family Hominidae, the division of Hominidae into subfamilies Hylobatinae (gibbons) and Homininae, the division of Homininae into tribes Pongini (orangutans) and Hominini, and the division of Hominini into subtribes Gorillina (gorillas) and Hominina (chimpanzees and humans). The additional gibbon and galago sequence data provide further support for the occurrence of a graded evolutionary-rate slowdown in the descent of simian primates, with the slowing rate being more pronounced in the great-ape and human lineages than in the gibbon or monkey lineages. A comparison of global versus local molecular clocks reveals that local clock predictions, when focused on a specific number of species within a narrow time frame, provide a more accurate estimate of divergence dates than do those of global clocks.     

A primate transfer RNA gene cluster and the evolution of human chromosome 1.

The localisation of tRNA(Asn) gene clusters in the karyotypes of primates has been studied by means of in situ hybridisation. In the human and orangutan (Pongo pygmaeus) karyotypes there are two such gene clusters, one each on the long and short arms of chromosome 1. Old World monkeys, however, contain both gene clusters on their equivalent of the human chromosome 1 short arm, which can be explained by a pericentric inversion which (amongst other chromosome changes) distinguishes the human and Old World monkey chromosomes 1. The capuchin (Cebus appella), however, a New World monkey, has only one tRNA(Asn) gene cluster, at least on the elements equivalent to human chromosome 1. This cluster is located proximal to the centromere on a chromosome that has been tentatively identified (by others) as the equivalent of the long arm of human chromosome 1. Should this prove to be correct, it would indicate that the large primate metacentric came into being in the form found today in the great apes, rather than in the form currently found in Old World monkeys. These data further show that the tRNA(Asn) gene cluster has been split in two since before the Old World monkeys and hominids diverged, i.e., over 30 million years ago, and also that the original transfer of these genes from one arm of chromosome 1 to the other was unlikely to have involved a pericentric inversion but, rather, some form of replicative transposition.     

No evidence for natural selection on endogenous borna-like nucleoprotein elements after the divergence of Old World and New World monkeys

Endogenous Borna-like nucleoprotein (EBLNs) elements were recently discovered as non-retroviral RNA virus elements derived from bornavirus in the genomes of various animals. Most of EBLNs appeared to be defective, but some of primate EBLN-1 to -4, which appeared to be originated from four independent integrations of bornavirus nucleoprotein (N) gene, have retained an open reading frame (ORF) for more than 40 million years. It was therefore possible that primate EBLNs have encoded functional proteins during evolution. To examine this possibility, natural selection operating on all ORFs of primate EBLN-1 to -4 was examined by comparing the rates of synonymous and nonsynonymous substitutions. The expected number of premature termination codons in EBLN-1 generated after the divergence of Old World and New World monkeys under the selective neutrality was also examined by the Monte Carlo simulation. As a result, natural selection was not identified for the entire region as well as parts of ORFs in the pairwise analysis of primate EBLN-1 to -4 and for any branch of the phylogenetic trees for EBLN-1 to -4 after the divergence of Old World and New World monkeys. Computer simulation also indicated that the absence of premature termination codon in the present-day EBLN-1 does not necessarily support the maintenance of function after the divergence of Old World and New World monkeys. These results suggest that EBLNs have not generally encoded functional proteins after the divergence of Old World and New World monkeys.     

Formation of a new solo-LTR of the human endogenous retrovirus H family in human chromosome 21

Human endogenous retroviruses (HERVs) contribute to various kinds of genomic instability via rearrangement and retrotransposition events. In the present study the formation of a new human-specific solo-LTR belonging to the HERV-H family (AP001667; chromosome 21q21) was detected by a comparative analysis of human chromosome 21 and chimpanzee chromosome 22. The solo-LTR was formed as a result of an equal homologous recombination excision event. Several evolutionary processes have occurred at this locus during primate evolution, indicating that mammalian-wide interspersed repeat (MIR) and full-length HERV-H elements integrated into hominoid genomes after the divergence of Old World monkeys and hominoids, and that the solo-LTR element was created by recombination excision of the HERV-H only in the human genome.     

Identification of a novel gene, DZIP (DAZ-interacting protein), that encodes a protein that interacts with DAZ (deleted in azoospermia) and is expressed in embryonic stem cells and germ cells

Evidence from diverse organisms, including humans, suggests that the DAZ (Deleted in Azoospermia) gene and a closely related homolog, DAZL (DAZ-like), are required early in germ cell development to maintain initial germ cell populations. Here we report the identification and characterization of the DZIP (DAZ-Interacting Protein) gene, which encodes at least three different protein isoforms that contain a C2H2 zinc-finger domain. The DZIP gene is expressed predominantly in human embryonic stem cells and fetal and adult germ cells; moreover, two DZIP protein isoforms colocalize with DAZ and/or DAZL proteins in these tissues. Finally, we provide evidence indicating that DZIP may associate with DAZ and its other cofactors in an RNA-binding protein complex that functions in both ES cells and germ cells.     

灵长类动物中TRIMCyp融合基因模式及对逆转录病毒复制的限制作用

TRIM5-CypA融合基因(TRIMCyp)是一种独特的TRIM5基因形式。迄今已发现新大陆猴中包括鹰猴在内的夜猴属所有代表种,以及在北平顶猴、巽他平顶猴、食蟹猴、印度恒河猴和熊猴等旧大陆猴中均存在这种基因融合现象,但在新大陆猴与旧大陆猴中的TRIMCyp融合基因的基因融合模式和表达剪接方式不同。新大陆猴TRIMCyp融合基因是由CypA假基因的cDNA序列通过LINE-1逆转座子介导的逆转座方式插入至TRIM5α基因的第7和第8外显子之间的内含子中形成,而旧大陆猴TRIMCyp融合基因则是由CypA假基因的cDNA序列以相似的逆转座方式插入至TRIM5基因的3’非翻译区(untranslatedregions,UTR)形成。TRIMCyp融合基因在不同灵长类动物中的存在比例、基因型、TRIMCyp融合蛋白的表达以及对逆转录病毒的限制活性均有所差异。鹰猴和平顶猴的TRIMCyp融合基因研究较多,鹰猴TRIMCyp融合蛋白可能以与TRIM5α相似机制限制HIV-1的感染,而平顶猴TRIMCyp融合蛋白则丧失了限制HIV-1的作用。这两个功能截然不同的融合基因为TRIM5α作用机制研究提供了难得的实验材料,也为建立HIV-1感染的新型灵长类动物艾滋病模型奠定了科学依据。该文综述了TRIMCyp融合基因在灵长类动物中的分布、存在形式及其限制逆转录病毒复制的作用机制等方面的研究情况。     

A large AZFc deletion removes DAZ3/DAZ4 and nearby genes from men in Y haplogroup N

Deletion of the entire AZFc locus on the human Y chromosome leads to male infertility. The functional roles of the individual gene families mapped to AZFc are, however, still poorly understood, since the analysis of the region is complicated by its repeated structure. We have therefore used single-nucleotide variants (SNVs) across approximately 3 Mb of the AZFc sequence to identify 17 AZFc haplotypes and have examined them for deletion of individual AZFc gene copies. We found five individuals who lacked SNVs from a large segment of DNA containing the DAZ3/DAZ4 and BPY2.2/BPY2.3 gene doublets in distal AZFc. Southern blot analyses showed that the lack of these SNVs was due to deletion of the underlying DNA segment. Typing 118 binary Y markers showed that all five individuals belonged to Y haplogroup N, and 15 of 15 independently ascertained men in haplogroup N carried a similar deletion. Haplogroup N is known to be common and widespread in Europe and Asia, and there is no indication of reduced fertility in men with this Y chromosome. We therefore conclude that a common variant of the human Y chromosome lacks the DAZ3/DAZ4 and BPY2.2/BPY2.3 doublets in distal AZFc and thus that these genes cannot be required for male fertility; the gene content of the AZFc locus is likely to be genetically redundant. Furthermore, the observed deletions cannot be derived from the GenBank reference sequence by a single recombination event; an origin by homologous recombination from such a sequence organization must be preceded by an inversion event. These data confirm the expectation that the human Y chromosome sequence and gene complement may differ substantially between individuals and more variations are to be expected in different Y chromosomal haplogroups.