Genomic organization, physical mapping, and involvement in Yq microdeletions of the VCY2 (BPY 2) gene

The AC006262.5-miR-7855-5p-BPY2C axis facilitates hepatocellular carcinoma proliferation and migration

Hepatocellular carcinoma (HCC) is typically fatal, and patients with hepatocellular carcinoma are usually diagnosed at the late stages. Although the treatments for HCC have been rapidly advancing, novel targets for HCC are still desperately needed, especially for targeted therapies. Here, we identified an enriched long non-coding RNA, AC006262.5, associated with HCC, that promoted the proliferation, migration, and invasiveness of HCC cells, both in vitro and in vivo. In addition, our results revealed that AC006262.5 bound to and regulated miR-7855-5p, a tumor-suppressive miRNA, in HCC. Moreover, our data show that AC006262.5 regulates the expression of BPY2C via miR-7855-5p. Finally, we found that AC006262.5 and miR-7855-5p formed a regulatory loop. Upregulation of AC006262.5 resulted in decreased expression of miR-7855-5p, and downregulation of miR-7855-5p further facilitated the expression of AC006262.5. Our work provides novel targets for HCC diagnosis and treatment, and sheds light on the lncRNA-miRNA regulatory nexus that controls the pathology of HCC.

Yq Microdeletion in a Patient with VACTERL Association and Shawl Scrotum with Bifid Scrotum: A Real Pathogenetic Association or a Coincidence?

VACTERL association is defined by the occurrence of congenital malformations: vertebral defects, anal atresia, cardiac defects, tracheoesophageal fistula with esophageal atresia, radial and renal dysplasia, and limb defects. No genetic alterations have been discovered except for some sporadic chromosomal rearrangements and gene mutations. We report a boy with VACTERL association and shawl scrotum with bifid scrotum who presented with a de novo Yq11.223q11.23 microdeletion identified by array CGH. The deletion spans 3.1 Mb and encompasses several genes in the AZFc region, frequently deleted in infertile men with severe oligozoospermia or azoospermia. Herein, we discuss the possible explanation for this unusual genotype-phenotype correlation. We suggest that the deletion of the BPY2 (previously VCY2) gene, located in the AZFc region and involved in spermatogenesis, contributed to the genesis of the phenotype. In fact, BPY2 interacts with a ubiquitin-protein ligase, involved in the SHH pathway which is known to be implicated in the genesis of VACTERL association.

De novo origin of VCY2 from autosome to Y-transposed amplicon

The formation of new genes is a primary driving force of evolution in all organisms. The de novo evolution of new genes from non-protein-coding genomic regions is emerging as an important additional mechanism for novel gene creation. Y chromosomes underlie sex determination in mammals and contain genes that are required for male-specific functions. In this study, a search was undertaken for Y chromosome de novo genes derived from non-protein-coding sequences. The Y chromosome orphan gene variable charge, Y-linked (VCY)2, is an autosome-derived gene that has sequence similarity to large autosomal fragments but lacks an autosomal protein-coding homolog. VCY2 locates in the amplicon containing long DNA fragments that were transposed from autosomes to the Y chromosome before the ape-monkey split. We confirmed that VCY2cannot be encoded by autosomes due to the presence of multiple disablers that disrupt the open reading frame, such as the absence of start or stop codons and the presence of premature stop codons. Similar observations have been made for homologs in the autosomes of the chimpanzee, gorilla, rhesus macaque, baboon and out-group marmoset, which suggests that there was a non-protein-coding ancestral VCY2 that was common to apes and monkeys that predated the transposition event. Furthermore, while protein-coding orthologs are absent, a putative non-protein-coding VCY2 with conserved disablers was identified in the rhesus macaque Y chromosome male-specific region. This finding implies that VCY2 might have not acquired its protein-coding ability before the ape-monkey split. VCY2 encodes a testis-specific expressed protein and is involved in the pathologic process of male infertility, and the acquisition of this gene might improve male fertility. This is the first evidence that de novo genes can be generated from transposed autosomal non-protein-coding segments, and this evidence provides novel insights into the evolutionary history of the Y chromosome.

Azoospermia factor and male infertility

Recently, work has shown that azoospermia factor (AZF) microdeletions result from homologous recombination between almost identical blocks in this gene region. These microdeletions in the Y chromosome are a common molecular genetic cause of spermatogenetic failure leading to male infertility. After completion of the sequencing of the Y chromosome, the classical definition of AZFa, AZFb, and AZFc was modified to five regions, namely AZFa, P5/proximal-P1, P5/distal-P1, P4/distal-P1, and AZFc, as a result of the determination of Y chromosomal structure. Moreover, partial AZFc deletions have also been reported, resulting from recombination in their sub-ampliconic identical pair sequences. These deletions are also implicated in a possible association with Y chromosome haplogroups. In this review, we address Y chromosomal complexity and the modified categories of the AZF deletions. Recognition of the association of Y deletions with male infertility has implications for the diagnosis, treatment, and genetic counseling of infertile men, in particular candidates for intracytoplasmic sperm injection.

Genetic dissection of the AZF regions of the human Y chromosome: thriller or filler for male (in)fertility?

The azoospermia factor (AZF) regions consist of three genetic domains in the long arm of the human Y chromosome referred to as AZFa, AZFb and AZFc. These are of importance for male fertility since they are home to genes required for spermatogenesis. In this paper a comprehensive analysis of AZF structure and gene content will be undertaken. Particular care will be given to the molecular mechanisms underlying the spermatogenic impairment phenotypes associated to AZF deletions. Analysis of the 14 different AZF genes or gene families argues for the existence of functional asymmetries between the determinants; while some are prominent players in spermatogenesis, others seem to modulate more subtly the program. In this regard, evidence supporting the notion that DDX3Y, KDM5D, RBMY1A1, DAZ, and CDY represent key AZF spermatogenic determinants will be discussed.

Alu sequence variants of the BPY2 gene in proven fertile and infertile men with Sertoli cell-only phenotype

OBJECTIVE

The basic protein on Y chromosome, 2 gene (BPY2) is implicated in the spermatogenic process. Three copies (paralogs) of the BPY2 sequence lie in the AZFc region, within huge palindromic repeats consisting of Alu sequences located in 5' flanking regions. Our objective was to screen the single nucleotide variation of BPY2 gene paralogously.

METHODS

Mutation screening of the exons and 5' flanking region of the BPY2 genes was carried out by polymerase chain reaction (PCR) and sequencing in 106 infertile patients with a Sertoli cell-only (SCO) phenotype and in 126 fertile men.

RESULTS

No sequence variation was detected in any of the BPY2 exons. Paralogous A/A/A and mixed A/G genotypes are referred to the promoter of the gene. The G/G/G genotype (wild type) was observed at the rates of 89.6% (95/106) in the SCO subjects and 96.0% (121/126) in the proven-fertile subjects. The G/G/G plus mixed A/G paralogous variants and the A/A/A paralogous variant were detected in 96.2% (102/106) and 3.8% (4/106) of infertile patients with SCO, respectively. The G/G/G plus mixed A/G paralogous variants were detected in 100% (126/126) of the fertile controls, with no instances of the A/A/A phenotype, and this difference was statistically significant (P = 0.038, Fisher's exact test).

CONCLUSION

The A/A/A genotype may be associated with the SCO phenotype. The alteration of all three copies of BPY2 within the AZFc region on the Y chromosome may affect spermatogenic process.

Male infertility: role of genetic background

Male infertility represents one of the clearest examples of a complex disease with a substantial genetic basis. Numerous male mouse models, mutation screening and association studies reported over the last few years reveal the high prevalence of genetic causes of spermatogenic impairment, accounting for 10-15% of severe male infertility, including chromosomal aberrations and single gene mutations. Natural selection prevents the transmission of mutations causing infertility, but this protective mechanism may be overcome by assisted reproduction techniques. Consequently, the identification of genetic factors is important for appropriate management of the infertile couple. However, a large proportion of infertile males are diagnosed as idiopathic, reflecting poor understanding of the basic mechanisms regulating spermatogenesis and sperm function. Furthermore, the molecular mechanisms underlying spermatogenic damage in cases of genetic infertility (for example Yq microdeletions) are not known. These problems can be addressed only by large scale association studies and testicular or spermatozoal expression studies in well-defined alterations of spermatogenesis. It is conceivable that these studies will have important diagnostic and therapeutic implications in the future. This review discusses the genetic causes of male infertility known to date, the genetic polymorphisms possibly associated with male infertility, and reports novel results of global gene expression profiling of normal human testis by microarray technology.

Genetic causes of male infertility

Genetic causes account for 10-15% of severe male infertility, including chromosomal aberrations and single gene mutations. Natural selection prevents the transmission of mutations causing infertility, while this protective mechanism may be overcome by assisted reproduction techniques. Consequently the identification of genetic factors has become good practice for appropriate management of the infertile couple. Furthermore, patients affected by some forms of genetic alterations produce a higher frequency of sperm with aneuploidies. Sperm aneuploidies are the direct result of the constitutional genetic abnormality or are caused by meiotic errors induced by the altered testicular environment that these men present. In this review we will report and discuss the genetic causes of male infertility known up to date and we will analyse genetic polymorphisms possibly associated with male infertility.

Identification in chromosome 8q11 of a region of homology with the g1 amplicon of the Y chromosome and functional analysis of the BEYLA gene

The male-specific region (MSY) of the Y chromosome contains genes involved mainly in male sex determination and in spermatogenesis. The majority of genes involved in male fertility are localized in multiple copies in the long arm of the Y chromosome, within specific regions defined as "ampliconic regions." It has been suggested that these genes derived from X-linked or autosomal ancestors during evolution, providing a benefit for male fertility when transposed onto the Y chromosome. So far, the autosomal origin has been demonstrated only for two MSY genes, DAZ and CDY. In the present study we report on the identification within chromosome 8q11.2 of a region homologous to the g amplicon, containing the VCY2 (approved gene symbol BPY2), TTTY4, and TTTY17 genes. A search for ancestor genes within the 8q11.2 region allowed us to identify a gene named BEYLA and to characterize the genomic organization and the expression patterns of this gene.

Identification and characterization of human VCY2-interacting protein: VCY2IP-1, a microtubule-associated protein-like protein

VCY2 is a testis-specific protein that locates in a frequently deleted azoospermia factor c region on chromosome Yq. Although its genomic structure has been characterized, the function of VCY2 is still unknown. To gain insight regarding the likely function of VCY2, we investigated the proteins that interact with VCY2 using the yeast two-hybrid system. We identified a novel VCY2 interaction partner, named VCY2IP-1, that encodes an open reading frame of 1059 amino acids. The amino acid sequence of VCY2IP-1 shows 59.3% and 41.9% homology to two human microtubule-associated proteins (MAPs), MAP1B and MAP1A, respectively. VCY2IP-1 has an extensive homology to the N-terminus and C-terminus regions of MAP1B and MAP1A, placing it within a large family of MAPs. We mapped VCY2IP-1 to chromosome 19p13.11. The VCY2IP-1 gene spans 15 kilobases (kb) and consists of seven exons. Northern blot analysis identified a single, intense band of approximately 3.2-kb VCY2IP-1 transcript, predominantly expressed in human testis. In situ hybridization of human testicular sections showed the localization of VCY2IP-1 transcripts in germ cells, and reverse transcription-polymerase chain reaction analysis demonstrated the presence of VCY2 and VCY2IP-1 transcripts in human ejaculated spermatozoa. Our expression data support the involvement of VCY2 and VCY2IP-1 in spermatogenesis. Based on the high homology of VCY2IP-1 with MAPs, we propose the involvement of VCY2 in the cytoskeletal network via interaction with VCY2IP-1.

Specific expression of VCY2 in human male germ cells and its involvement in the pathogenesis of male infertility

Abnormal spermatogenesis in men with Y-chromosome microdeletions suggests that genes important for spermatogenesis have been removed from these individuals. VCY2 is a testis-specific gene that locates in the most frequently deleted azoospermia factor c region in the Y chromosome. We have raised an antiserum to VCY2 and used it to characterize the localization of VCY2 in human testis. Using Western blot analysis, the affinity-purified polyclonal VCY2 antibody gave a single specific band of approximately 14 kDa in size, corresponding to the expected size of VCY2 in all the collected human testicular biopsy specimens with normal spermatogenesis. Immunohistochemical analyses showed that VCY2 localized to the nuclei of spermatogonia, spermatocytes, and round spermatids, except elongated spermatids. At the ultrastructural level, VCY2 expression was found in the nucleus of human ejaculated spermatozoa. To determine the possible relationship of VCY2 with the pathogenesis of male infertility, we examined a group of infertile men with and without Y-chromosome microdeletions and with known testicular pathology using VCY2 antibody. VCY2 was weakly expressed at the spermatogonia and immunonegative in spermatocytes and round spermatids in testicular biopsy specimens with maturation arrest or hypospermatogenesis. The specific localization of the protein in germ cell nuclei indicates that VCY2 is likely to function in male germ cell development. The impaired expression of VCY2 in infertile men suggests its involvement in the pathogenesis of male infertility.

VCY2 protein interacts with the HECT domain of ubiquitin-protein ligase E3A

VCY2 locates in the AZFc region on chromosome Yq and is frequently deleted in infertile men with severe oligozoospermia or azoospermia. VCY2 is a testis-specific protein with unknown function. This study was to identify the protein that interacts with VCY2. We used the full-length VCY2 as bait to screen the human testis cDNA library using yeast two-hybrid approach. We identified a number of positive-interacting clones that encode ubiquitin-protein ligase E3A (UBE3A). UBE3A contains a HECT domain that binds VCY2. The specificity of the interaction was confirmed by co-immunoprecipitation and yeast mating. Northern blot analyses revealed two UBE3A transcripts 1.4 and 2kb that were abundantly expressed in human testis. We also showed that both VCY2 and UBE3A mRNAs were expressed in ejaculated human spermatozoa, indicating that both genes localize in the germ cell compartment. These data suggest that UBE3A ubiquitination may be required for VCY2 function.