UBE2B mRNA alterations are associated with severe oligozoospermia in infertile men.

Oligozoospermia (low sperm count) is a common semen deficiency. However, to date, few genetic defects have been identified to cause this condition. Moreover, even fewer molecular genetic diagnostic tests are available for patients with oligozoospermia in the andrology clinic. Based on animal and gene expression studies of oligozoospermia, several molecular pathways may be disrupted in post-meiotic spermatozoa. One of the disrupted pathways is protein ubiquitination and cell apoptosis. A critical protein involved in this pathway is the ubiquitin-conjugating enzyme 2B, UBE2B. Absence of Ube2b in male mice causes spermatogenic meiotic disruption with increased apoptosis, leading to infertility. To examine the association between messenger RNA defects in UBE2B and severe oligozoospermia (0.1-10 × 10(6) cells/ml), sequencing of sperm cDNA in 326 oligozoospermic patients and 421 normozoospermic men was performed. mRNA alterations in UBE2B were identified in sperm in 4.6% (15 out of 326) of the oligozoospermic patients, but not found in control men, suggesting strong association between mRNA defects and oligozoospermia (χ(2) = 19, P = 0.0001). Identified UBE2B alterations include nine splicing, four missense and two nonsense alterations. The follow-up screen of corresponding DNA regions did not reveal causative DNA mutations, suggesting a post-transcriptional nature of identified defects. None of these variants were reported in the dbSNP database, although other splicing abnormalities with low level of expression were present in 11 out of 421 (2.6%) controls. Our findings suggest that two distinct molecular mechanisms, mRNA editing and splicing processing, are disrupted in oligozoospermia. We speculate that the contribution of post-transcriptional mRNA defects to oligozoospermia could be greater than previously anticipated.

Association of mutations in the zona pellucida binding protein 1 (ZPBP1) gene with abnormal sperm head morphology in infertile men.

Nearly 7% of men are afflicted by male infertility worldwide, and genetic factors are suspected to play a significant role in the majority of these patients. Although sperm morphology is an important parameter measured in the semen analysis, only a few genetic causes of teratozoospermia are currently known. The objective of this study was to define the association between alterations in the genes encoding the Golgi-associated PDZ- and coiled-coil motif containing protein (GOPC), the protein interacting with C kinase 1 (PICK1) and the acrosomal protein zona pellucida binding protein 1 (ZPBP1/sp38) with abnormal sperm head morphology in infertile men. Previous reports demonstrated that mice lacking Gopc, Pick1 and Zpbp1 are infertile due to abnormal head morphology. Herein, using our validated RNA-based method, we studied spermatozoal cDNA encoding the human GOPC, PICK1 and ZPBP1 genes in 381 teratozoospermic and 240 controls patients via direct sequencing. Among these genes, we identified missense and splicing mutations in the sperm cDNA encoding ZPBP1 in 3.9% (15/381) of men with abnormal sperm head morphology. These mutations were not observed in 240 matched controls and the dbSNP database (χ(2) = 9.3, P = 0.002). In contrast, statistically significant and functionally relevant mutations were not discovered in the GOPC and PICK1 genes. In our study ZPBP1 mutations are associated with abnormal sperm head morphology, defined according to strict criteria, resembling the mouse Zpbp1 null phenotype. We hypothesize that missense mutations exert a dominant-negative effect due to altered ZPBP1 protein folding and protein:protein interactions in the acrosome.

Non-invasive genetic diagnosis of male infertility using spermatozoal RNA: KLHL10 mutations in oligozoospermic patients impair homodimerization.

Infertility affects an estimated 7% of men worldwide, nearly a quarter of whom are diagnosed as idiopathic. The genetic etiologies of idiopathic male infertility are unknown, partly due to lack of simple diagnostic techniques. Moreover, the transmission risk of such genetic defects to offspring born from assisted reproductive techniques is increasingly becoming a concern for physicians and infertile couples. We explored the feasibility of obtaining full-length mRNAs from transcriptionally inert human spermatozoa in semen as a non-invasive diagnostic tool for identifying germline mutations in candidate infertility-associated genes. The efficacy of reverse-transcription PCR on spermatozoal RNA from infertile patients with wide-ranging sperm concentrations varied between 91 and 99% for multiple haploid germ cell-expressed genes. Using this methodology, we identified seven oligozoospermic patients with missense and splicing mutations in the germ cell-specific gene, KLHL10. Three of 270 (1.1%) severely oligozoospermic patients (<10(6) sperm/ml) harbor KLHL10 alterations that were absent in 394 controls and exhibited significant association (P=0.02). Two KLHL10 missense mutations (A313T and Q216P) resulted in impaired homodimerization with the wild-type protein in yeast interaction assays, suggesting a functional deficiency. This study demonstrates the utility of this approach for analysis of haploid germ cell-expressed genes regulating post-meiotic events including sperm maturation, motility and fertilization. The development of non-invasive techniques to analyze genetic defects of human spermatogenesis, previously possible only with invasive testis biopsies, provides important diagnostic and therapeutic implications for reproductive medicine.