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.     

Interaction of the conserved meiotic regulators, BOULE (BOL) and PUMILIO-2 (PUM2)

Germ cell development is complex; it encompasses specification of germ cell fate, mitotic replication of early germ cell populations, and meiotic and postmeiotic development. Meiosis alone may require several hundred genes, including homologs of the BOULE (BOL) and PUMILIO (PUM) gene families. Both BOL and PUM homologs encode germ cell specific RNA binding proteins in diverse organisms where they are required for germ cell development. Here, we demonstrate that human BOL forms homodimers and is able to interact with a PUMILIO homolog, PUM2. We mapped the domain of BOL that is required for dimerization and for interaction with PUM2. We also show that BOL and PUM2 can form a complex on a subset of PUM2 RNA targets that is distinct from targets bound by PUM2 and another deleted in azoospermia (DAZ) family member, DAZ-like (DAZL). This suggests that RNA sequences bound by PUM2 may be determined by protein interactions. This data also suggests that although the BOL, DAZ, and DAZL proteins are all members of the same gene family, they may function in distinct molecular complexes during human germ cell development.     

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.     

The DAZL family proteins are PABP-binding proteins that regulate translation in germ cells

DAZL proteins are germ-cell-specific RNA-binding proteins essential for gametogenesis. The precise molecular role of these proteins in germ-cell development remains enigmatic; however, they appear to function in the cytoplasm. In order to directly address the function of vertebrate DAZL proteins, we have used Xenopus laevis oocytes as a model system. Here we demonstrate that members of this family, including Xdazl, mouse Dazl, human DAZL, human DAZ and human BOULE, have the ability to stimulate translation and function at the level of translation initiation. We show that DAZL proteins interact with poly(A)-binding proteins (PABPs), which are critical for the initiation of translation. Mapping and tethered function experiments suggest that these interactions are physiologically important. This leads to an attractive hypothesis whereby DAZL proteins activate translationally silent mRNAs during germ cell development through the direct recruitment of PABPs.     

In vivo and in vitro analysis of homodimerisation activity of the mouse Dazl1 protein

In Drosophila RNA-binding proteins play a fundamental role in key developmental pathways, such as sex determination. There is emerging evidence suggesting that RNA-binding proteins play a central role in regulation of development in mammals as well. We are interested in spermatogenesis as a model for cell differentiation and development in mammals. Two Y-encoded candidate spermatogenesis genes, RBMY and DAZ, have been isolated by positional cloning from infertile patients. They both encode putative RNA-binding proteins of the RRM (RNA recognition motif) type, and the high degree of conservation of both these gene families suggests an important role in spermatogenesis. Mice with a null allele for Dazl1, the mouse homologue of DAZ, are infertile due to a meiotic entry defect. Male flies mutant for boule, the Drosophila homologue of Dazl1, are infertile due to a G(2)/M meiotic block. However, no data has been published yet about the biochemical properties of the DAZ/DAZL1 proteins. We report here that Dazl1 is able to form homoheterodimers both in vivo and in vitro, that this activity is due to a novel protein-protein interaction domain, and that homotypic interaction activity is RNA-independent.     

Characterization of the mouse Dazap1 gene encoding an RNA-binding protein that interacts with infertility factors DAZ and DAZL

Background  

DAZAP1 (DAZ Associated Protein 1) was originally identified by a yeast two-hybrid system through its interaction with a putative male infertility factor, DAZ (Deleted in Azoospermia). In vitro, DAZAP1 interacts with both the Y chromosome-encoded DAZ and an autosome-encoded DAZ-like protein, DAZL. DAZAP1 contains two RNA-binding domains (RBDs) and a proline-rich C-terminal portion, and is expressed most abundantly in the testis. To understand the biological function of DAZAP1 and the significance of its interaction with DAZ and DAZL, we isolated and characterized the mouse Dazap1 gene, and studied its expression and the subcellular localization of its protein product.     

Single-nucleotide variant in multiple copies of a deleted in azoospermia (DAZ) sequence - a human Y chromosome quantitative polymorphism

The evolution of the deleted in azoospermia (DAZ) gene family supports prevalent theories on the origin and development of sex chromosomes and sexual dimorphism. The ancestral DAZL gene in human chromosome 3 is known to be involved in germline development of both males and females. The available phylogenetic data suggest that some time after the divergence of the New World and Old World monkey lineages, the DAZL gene, which is found in all mammals, was copied to the Y chromosome of an ancestor to the Old World monkeys, but not New World monkeys. In modern man, the Y-linked DAZ gene complex is located on the distal part of the q arm. It is thought that after being copied to the Y chromosome, and after the divergence of the human and great ape lineages, the DAZ gene in the former underwent internal rearrangements. This included tandem duplications as well as a T > C transition altering an MboI restriction enzyme site in a duplicated sequence. In this study, we report on the ratios of MboI-/MboI+ variant sequences in individuals from seven worldwide human populations (Basque, Benin, Egypt, Formosa, Kungurtug, Oman and Rwanda) in the DAZ complex. The ratio of PCR MboI- and MboI+ amplicons can be used to characterize individuals and populations. Our results show a nonrandom distribution of MboI-/MboI+ sequence ratios in all populations examined, as well as significant differences in ratios between populations when compared pairwise. The multiple ratios imply that there have been more than one recent reorganization events at this locus. Considering the dynamic nature of this locus and its involvement in male fertility, we investigated the extent and distribution of this polymorphism.     

Structure and RNA binding of the mouse Pumilio-2 Puf domain

Puf proteins control translation through the interaction of a C-terminal Puf domain with specific sequences present in the 3′ untranslated region of messenger RNAs. In Drosophila, binding of the protein Pumilio to mRNA leads to translational repression which is required for anterior/posterior patterning during embryogenesis. The vertebrate Pumilio homologue 2 (Pum2) has been implicated in controlling germ cell development through interactions with the RNA binding proteins deleted in azoospermia (DAZ), DAZ-like (DAZL) and BOULE. We present the 1.6 Å resolution X-ray crystal structure of the Puf domain from murine Pum2 and demonstrate that this domain is capable of binding with nanomolar affinity to RNA sequences from the hunchback Nanos response element (NRE) and a previously identified Pum2 binding element (PBE).     

Molecular characterization and SNPs analysis of the porcine Deleted in AZoospermia Like (pDAZL) gene

The Deleted in AZoospermia Like (DAZL) gene is expressed in prenatal and postnatal germ cells. In this study, we cloned and characterized the porcine Deleted in AZoospermia Like (pDAZL) gene. We found the full-length coding sequence of the pDAZL encoded a protein of 295 amino acids with a RNA recognition motif (amino acids 41-111) and a DAZ repeat (amino acids 167-120). The deduced protein sequence of pDAZL is 92.5% and 91.5% similar to those of human and bovine, respectively. PCR-MspI-RFLP and PCR-TaqI-RFLP were established to detect an A/G mutation in intron 7 and a C/A mutation in intron 9, respectively. Associations of two SNPs with litter size traits were assessed in Large White (n=275) and DIV (n=128) pig populations, and the statistical analysis demonstrated that CC produced 0.716 more (P<0.05) piglets born alive than CD genotypes in Large White pigs at TaqI locus (C/A mutation in intron 9), and the dominance effect was 0.304 pig per litter (P<0.05). This result suggests that the pDAZL gene might be a good candidate gene of litter size trait and provides some marker information for marker-assisted selection (MAS).     

DAZ家族新成员BOULE蛋白的结构与功能

BOULE蛋白是2001年发现的DAZ家族的新成员,是人类精子发生过程中减数分裂的关键调控因子. BOULE基因表达的改变或BOULE蛋白的缺乏可引起减数分裂阻滞和精子生成障碍,从而导致无精子症并产生不育. BOULE蛋白的一级结构中含有DAZ家族的特征结构域,包括DAZ重复和RNA结合域（RBM）,因此,将其列为继DAZ、DAZL之后DAZ家族的第3个成员.本文对BOULE的发现过程、结构和定位进行了总结回顾,并重点介绍了其在精子发生减数分裂中的作用及其作用机制.     

DAZ Family Proteins,Key Players for Germ Cell Development

DAZ family proteins are found almost exclusively in germ cells in distant animal species. Deletion or mutations of their encoding genes usually severely impair either oogenesis or spermatogenesis or both. The family includes Boule (or Boll), Dazl (or Dazla) and DAZ genes. Boule and Dazl are situated on autosomes while DAZ, exclusive of higher primates, is located on the Y chromosome. Deletion of DAZ gene is the most common causes of infertility in humans. These genes, encoding for RNA binding proteins, contain a highly conserved RNA recognition motif and at least one DAZ repeat encoding for a 24 amino acids sequence able to bind other mRNA binding proteins. Basically, Daz family proteins function as adaptors for target mRNA transport and activators of their translation. In some invertebrate species, BOULE protein play a pivotal role in germline specification and a conserved regulatory role in meiosis. Depending on the species, DAZL is expressed in primordial germ cells (PGCs) and/or pre-meiotic and meiotic germ cells of both sexes. Daz is found in fetal gonocytes, spermatogonia and spermatocytes of adult testes. Here we discuss DAZ family genes in a phylogenic perspective, focusing on the common and distinct features of these genes, and their pivotal roles during gametogenesis evolved during evolution.     

DAZAP1 interacts via its RNA-recognition motifs with the C-termini of other RNA-binding proteins

The turnover and translation of many human mRNAs is regulated by AU-rich elements present in their 3′untranslated region, which bind various trans acting factors. We previously identified a trans acting factor that interacts with these cis elements as DAZAP1 (deleted in Azoospermia (DAZ)-Associated Protein 1), whose interaction with the germ cell-specific protein DAZ was disrupted by the phosphorylation of DAZAP1. Here we have identified several other RNA-binding proteins as binding partners for DAZAP1 in non-germinal cells. Unlike DAZ, these interactions occur between the RNA recognition motifs of DAZAP1 and the C-termini of the binding partners and in a phosphorylation-independent manner. The results suggest that DAZAP1 is a component of complexes that are crucial for the degradation and silencing of mRNA.