DPY19L2 deletion as a major cause of globozoospermia

Globozoospermia, characterized by round-headed spermatozoa, is a rare (< 0.1% in male infertile patients) and severe teratozoospermia consisting primarily of spermatozoa lacking an acrosome. Studying a Jordanian consanguineous family in which five brothers were diagnosed with complete globozoospermia, we showed that the four out of five analyzed infertile brothers carried a homozygous deletion of 200 kb on chromosome 12 encompassing only DPY19L2. Very similar deletions were found in three additional unrelated patients, suggesting that DPY19L2 deletion is a major cause of globozoospermia, given that 19% (4 of 21) of the analyzed patients had such deletion. The deletion is most probably due to a nonallelic homologous recombination (NAHR), because the gene is surrounded by two low copy repeats (LCRs). We found DPY19L2 deletion in patients from three different origins and two different breakpoints, strongly suggesting that the deletion results from recurrent events linked to the specific architectural feature of this locus rather than from a founder effect, without fully excluding a recent founder effect. DPY19L2 is associated with a complete form of globozoospermia, as is the case for the first two genes found to be associated with globozoospermia, SPATA16 or PICK1. However, in contrast to SPATA16, for which no pregnancy was reported, pregnancies were achieved, via intracytoplasmic sperm injection, for two patients with DPY19L2 deletion, who then fathered three children.     

The acrosome: comparative morphology and development, contribution of a human familial globozoospermia case report

Sperm acrosome is known to play a role in the fertilization of the majority of animal species studied. As a general rule, the acrosome appeared as soon as the fertilization occurred out of aquaeous phase. The biochemical content of acrosome as well as its release mode could suggest it is a simple lysosome. But this would by pass its important morphogenic role in spermiogenesis. Its development is strongly linked to the development of the microtubules manchette system.Molecular data of animal mutagenesis contribute to the understanding of acrosome biogenesis mechanisms. Globozoospermia is a rare but severe human teratozoospermia, characterized by ejaculates entirely consisting of round-headed spermatozoa that lack an acrosome. It originates from a disturbed acrosome biogenesis. Recently, the genetic study of a familial globozoospermia led to highlight a homozygote mutation of the gene SPATA16, linked to the globozoospermic phenotype. This study contributes to the understanding of the mechanisms implied in human acrosome formation.     

Molecular characterization, polymorphism and association of porcine SPATA19 gene

Spermatogenesis associated 19 (SPATA19) is an important reproduction related gene. In this study, we cloned the full-length cDNA sequence of porcine SPATA19 gene through the rapid amplification of cDNA ends (RACE) method. The porcine SPATA19 gene encodes a protein of 154 amino acids which shares high homology with the SPATA19 of ten species: giant panda (87?%), dog (86?%), cattle (84?%), rabbit (78?%), sumatran orangutan (72?%), human (71?%), rhesus monkey (71?%), chimpanzee (70?%), mouse (71?%) and rat (69?%). The phylogenetic analysis revealed that the porcine SPATA19 gene has a closer genetic relationship with the SPATA19 gene of dog. This gene is structured in six exons and five introns as revealed by computer-assisted analysis. PCR-RFLP was established to detect the GU475012:c.515T>C substitution of porcine SPATA19 gene mRNA and association of this mutation with litter size traits was assessed in Large White (n?=?100) and Landrace (n?=?100) pig populations. Results demonstrated that this polymorphic locus was significantly associated with the litter size of all parities in Large White sows and Landrace sows. Therefore, SPATA19 gene could be an useful candidate gene in selection for increasing litter size in pigs. These data serve as a foundation for further insight into this novel porcine gene.     

Cloning and characterization of chicken SPATA4 gene and analysis of its specific expression

The spermatogenesis associated 4 gene (SPATA4, previously named TSARG2) was first cloned from a mouse testis cDNA library and was reported to be a candidate apoptosis-related gene in male germ cells. In this study, we cloned and characterized the SPATA4 gene from chicken (Gallus gallus). Bioinformatics analysis shows that the chicken SPATA4 gene is located on chromosome 4, is made up of six exons, and contains an 860 bp open reading frame encoding a putative protein of 250 amino acids. Further analysis of the SPATA4 gene sequence indicates that it is highly conserved between avian and mammalian species. Multi-tissue RT-PCR results indicate that the chicken SPATA4 gene is specifically expressed in the testis. Moreover, according to multi-time RT-PCR results, the expression of chicken SPATA4 occurs in a development stage-dependent pattern, and is gradually upregulated during the developmental process in chicken testis. All of these results suggest that SPATA4 may play an important role in the chicken spermatogenesis process.     

Overexpression a novel zebra fish spermatogenesis-associated gene 17 (<Emphasis Type="Italic">SPATA17</Emphasis>) induces apoptosis in GC-1 cells

The spermatogenesis-associated 17 gene (SPATA17, previously named MSRG-11) was reported to be a candidate spermatocyte apoptosis-related gene which may play a critical role in human spermatogenesis, especially in meiosis. Analysis of SPATA17 expression and regulation in zebra fish may provide insight into the understanding of the complicated process of gonadogenesis and its potential function in spermatocyte cell apoptosis. In this study, we cloned and characterized the SPATA17 gene from zebra fish which consists of nine exons separated by eight introns. The consensus open reading frame (1258 bp) encodes a polypeptide of 357 amino acids which shares 44% identity with the human SPATA17 gene. Bioinformatic analysis reveals that SPATA17 protein contains three short calmodulin-binding motifs (IQ motif) and is considered to play a critical role in interactions with CaM proteins. Multi-tissue RT-PCR and Northern blot results demonstrated that the zebra fish SPATA17 gene was expressed strongly in testis and a slight amount of expression in ovary. Flow cytometry analysis and genomic DNA ladders result showed that the expression of SPATA17 protein in the GC-1 cell line could accelerate cell apoptosis. Analysis of the SPATA17 sequence and its spatial expression pattern indicate that this gene is highly conserved and may play an important role in the process of zebra fish gonadogenesis.     

小鼠睾丸凋亡基因MSRG-11的人类同源基因SPATA17的克隆

利用生物信息学方法结合实验手段克隆了一个在睾丸组织中特异高表达的小鼠生精细胞凋亡相关基因Spata17的人类同源基因SPATA17（GenBank登录号为AY963797）。应用生物信息学分析显示该基因定位在染色体1q41,包含11个外显子,内含子和外显子交界区均符合gt—ag规则;该基因开放阅读框为1083bp编码一个由361个氨基酸组成的、分子量为43．49kD、等电点为9．71、含有三个保守IQ功能域的蛋白;对SPATA17编码蛋白质进行生物信息学分析,无跨膜区,无信号肽序列,推测为一非分泌性蛋白。多组织和Northern blot结果显示该基因只在睾丸组织中特异高表达,转录本大小为2．0kb。总之,研究表明SPATA17在睾丸组织生精细胞凋亡起重要作用。     

SPATA4 improves aging‐induced metabolic dysfunction through promotion of preadipocyte differentiation and adipose tissue expansion

Spermatogenesis‐associated protein 4 (SPATA4) is conserved across multiple species. However, the function of this gene remains largely unknown. In this study, we generated Spata4 transgenic mice to explore tissue‐specific function of SPATA4. Spata4 overexpression mice displayed increased subcutaneous fat tissue compared with wild‐type littermates at an old age, while this difference was not observed in younger mice. Aging‐induced ectopic fat distribution, inflammation, and insulin resistance were also significantly attenuated by SPATA4. In vitro, SPATA4 promoted preadipocyte differentiation through activation of the ERK1/2 and C/EBPβ pathway and increased the expression of adipokines. These data suggest SPATA4 can regulate lipid accumulation in a tissue‐specific manner and improve aging‐induced dysmetabolic syndromes. Clarifying the mechanism of SPATA4 functioning in lipid metabolism might provide novel therapeutic targets for disease interventions.     

Molecular characterization and chromosomal localization of spermatogenesis related sequences in Torpedo torpedo (Chondrichthyes, Torpediniformes)

Cytogenetic data in cartilaginous fishes are currently very inconsistent, considering that the karyotype morphology of only about seventy living species is actually known. Only in the last few years different molecular approaches, first of all physical mapping on metaphase chromosomes, have been used to investigate the cytotaxonomic relationship existing inside this interesting group of vertebrates. The aim of the work was to characterize new molecular chromosomal markers both to discriminate the different chromosome pairs and to distinguish the probable sex chromosomes in the species Torpedo torpedo, since its karyotype does not seem to exhibit heterochromosomes. Evolution of the SRY gene has received considerable attention, mainly because it has been shown to be the sex-determining locus in mammals. The gene is located in the Y chromosome where it normally occurs as a single copy. Using primers taken from the conserved SRY sequences, we characterized these regions at the molecular level and localized them on metaphase chromosomes. The PCR products revealed similar patterns in specimens of both sexes of T. torpedo, but only one fragment of the male amplification product showed a high percentage of identity with human spermatogenesis related genes, SPATA 16, SPATA 18 and UTY. Fluorescent in situ hybridization with these sequences showed the presence of spots at the subtelomeric level of two chromosome pairs in the male and of one pair in the female. Finally, these sequences are particularly useful as chromosome markers to differentiate between the male and the female karyotypes in this species.     

SPATA2 promotes CYLD activity and regulates TNF‐induced NF‐κB signaling and cell death

K63‐ and Met1‐linked ubiquitylation are crucial posttranslational modifications for TNF receptor signaling. These non‐degradative ubiquitylations are counteracted by deubiquitinases (DUBs), such as the enzyme CYLD, resulting in an appropriate signal strength, but the regulation of this process remains incompletely understood. Here, we describe an interaction partner of CYLD, SPATA2, which we identified by a mass spectrometry screen. We find that SPATA2 interacts via its PUB domain with CYLD, while a PUB interaction motif (PIM) of SPATA2 interacts with the PUB domain of the LUBAC component HOIP. SPATA2 is required for the recruitment of CYLD to the TNF receptor signaling complex upon TNFR stimulation. Moreover, SPATA2 acts as an allosteric activator for the K63‐ and M1‐deubiquitinase activity of CYLD. In consequence, SPATA2 substantially attenuates TNF‐induced NF‐κB and MAPK signaling. Conversely, SPATA2 is required for TNF‐induced complex II formation, caspase activation, and apoptosis. Thus, this study identifies SPATA2 as an important factor in the TNF signaling pathway with a substantial role for the effects mediated by the cytokine.     

Molecular cloning and bioinformatic analysis of SPATA4 gene

Full-length cDNA sequences of four novel SPATA4 genes in chimpanzee, cow, chicken and ascidian were identified by bioinformatic analysis using mouse or human SPATA4 cDNA fragment as electronic probe. All these genes have 6 exons and have similar protein molecular weight and do not localize in sex chromosome. The mouse SPATA4 sequence is identified as significantly changed in cryptorchidism, which shares no significant homology with any known protein in swissprot databases except for the homologous genes in various vertebrates. Our searching results showed that all SPATA4 proteins have a putative conserved domain DUF1042. The percentages of putative SPATA4 protein sequence identity ranging from 30 % to 99 %. The high similarity was also found in 1 kb promoter regions of human, mouse and rat SPATA4 gene. The similarities of the sequences upstream of SPATA4 promoter also have a high proportion. The results of searching SymAtlas (http://symatlas.gnf.org/SymAtlas/) showed that human SPATA4 has a high expression in testis, especially in testis interstitial, leydig cell, seminiferous tubule and germ cell. Mouse SPATA4 was observed exclusively in adult mouse testis and almost no signal was detected in other tissues. The pI values of the protein are negative, ranging from 9.44 to 10.15. The subcellular location of the protein is usually in the nucleus. And the signal peptide possibilities for SPATA4 are always zero. Using the SNPs data in NCBI, we found 33 SNPs in human SPATA4 gene genomic DNA region, with the distribution of 29 SNPs in the introns. CpG island searching gives the data about CpG island, which shows that the regions of the CpG island have a high similarity with each other, though the length of the CpG island is different from each other. This research is a fundamental work in the fields of the bioinformational analysis, and also put forward a new way for the bioinformatic analysis of other genes.     

Evaluation of SPATA1-associated markers for stallion fertility

Stallion fertility is an economically important trait because the use of artificial insemination is increasing in the horse industry and superior sires are used more intensely. Molecular genetic markers may be useful as early indicators for a stallion's fertility and genetic improvement programmes. The testis-specific SPATA1 protein is involved in shaping the sperm head during spermatogenesis. Thus, the spermatogenesis associated 1 ( SPATA1 ) gene was chosen as candidate for stallion fertility, and we analysed intragenic single nucleotide polymorphisms (SNPs) as genetic markers for the least square means (LSM) of the pregnancy rate per oestrus of stallions and breeding values (BV) for the paternal and embryonic component of the pregnancy rate per oestrus. We sequenced the cDNA of SPATA1 to verify the annotated mRNA sequence. One SPATA1 -associated intronic SNP ( BIEC2-968854 ) showed a significant association with the embryonic component of BVs of stallions for the pregnancy rate per oestrus. The embryonic component of BVs was positively associated with homozygous C/C stallions. Both the additive and dominance effects were significant with values of −5.8% ( P  = 0.01) and −6.4% ( P  = 0.02) for the embryonic component of BVs. For the same SNP, a suggestive association was found for the LSM of the pregnancy rate per oestrus of stallions. Heterozygous stallions had higher pregnancy rates per oestrus than homozygous stallions. The dominance effect was 4.1% with a nominal P -value of 0.02. The SNP BIEC2-968854 can change an SP1 binding site and thus we assume that gene regulation may be influenced through this intronic mutation. This is the first report on SPATA1 being associated with the pregnancy rate per oestrus for stallions.     

Dynamics of Sun5 Localization during Spermatogenesis in Wild Type and Dpy19l2 Knock-Out Mice Indicates That Sun5 Is Not Involved in Acrosome Attachment to the Nuclear Envelope

The acrosome is an organelle that is central to sperm physiology and a defective acrosome biogenesis leads to globozoospermia, a severe male infertility. The identification of the actors involved in acrosome biogenesis is therefore particularly important to decipher the molecular pathogeny of globozoospermia. We recently showed that a defect in the DPY19L2 gene is present in more than 70% of globozoospermic men and demonstrated that Dpy19l2, located in the inner nuclear membrane, is the first protein involved in the attachment of the acrosome to the nuclear envelope (NE). SUN proteins serve to link the nuclear envelope to the cytoskeleton and are therefore good candidates to participate in acrosome-nucleus attachment, potentially by interacting with DPY19L2. In order to characterize new actors of acrosomal attachment, we focused on Sun5 (also called Spag4l), which is highly expressed in male germ cells, and investigated its localization during spermatogenesis. Using immunohistochemistry and Western blot experiments in mice, we showed that Sun5 transits through different cellular compartments during meiosis. In pachytene spermatocytes, it is located in a membranous compartment different to the reticulum. In round spermatids, it progresses to the Golgi and the NE before to be located to the tail/head junction in epididymal sperm. Interestingly, we demonstrate that Sun5 is not, as initially reported, facing the acrosome but is in fact excluded from this zone. Moreover, we show that in Dpy19l2 KO spermatids, upon the detachment of the acrosome, Sun5 relocalizes to the totality of the NE suggesting that the acrosome attachment excludes Sun5 from the NE facing the acrosome. Finally, Western-blot experiments demonstrate that Sun5 is glycosylated. Overall, our work, associated with other publications, strongly suggests that the attachment of the acrosome to the nucleus does not likely depend on the formation of SUN complexes.     

Mutations in SPATA5 Are Associated with Microcephaly,Intellectual Disability,Seizures, and Hearing Loss

Using whole-exome sequencing, we have identified in ten families 14 individuals with microcephaly, developmental delay, intellectual disability, hypotonia, spasticity, seizures, sensorineural hearing loss, cortical visual impairment, and rare autosomal-recessive predicted pathogenic variants in spermatogenesis-associated protein 5 (SPATA5). SPATA5 encodes a ubiquitously expressed member of the ATPase associated with diverse activities (AAA) protein family and is involved in mitochondrial morphogenesis during early spermatogenesis. It might also play a role in post-translational modification during cell differentiation in neuronal development. Mutations in SPATA5 might affect brain development and function, resulting in microcephaly, developmental delay, and intellectual disability.     

Absence of Dpy19l2, a new inner nuclear membrane protein, causes globozoospermia in mice by preventing the anchoring of the acrosome to the nucleus

Sperm-head elongation and acrosome formation, which take place during the last stages of spermatogenesis, are essential to produce competent spermatozoa that are able to cross the oocyte zona pellucida and to achieve fertilization. During acrosome biogenesis, acrosome attachment and spreading over the nucleus are still poorly understood and to date no proteins have been described to link the acrosome to the nucleus. We recently demonstrated that a deletion of DPY19L2, a gene coding for an uncharacterized protein, was responsible for a majority of cases of type I globozoospermia, a rare cause of male infertility that is characterized by the exclusive production of round-headed acrosomeless spermatozoa. Here, using Dpy19l2 knockout mice, we describe the cellular function of the Dpy19l2 protein. We demonstrate that the protein is expressed predominantly in spermatids with a very specific localization restricted to the inner nuclear membrane facing the acrosomal vesicle. We show that the absence of Dpy19l2 leads to the destabilization of both the nuclear dense lamina (NDL) and the junction between the acroplaxome and the nuclear envelope. Consequently, the acrosome and the manchette fail to be linked to the nucleus leading to the disruption of vesicular trafficking, failure of sperm nuclear shaping and eventually to the elimination of the unbound acrosomal vesicle. Finally, we show for the first time that Dpy19l3 proteins are also located in the inner nuclear envelope, therefore implying that the Dpy19 proteins constitute a new family of structural transmembrane proteins of the nuclear envelope.