Ask about this productRelated genes to: SPIN2B antibody
- Gene:
- SPIN2B NIH gene
- Name:
- spindlin family member 2B
- Previous symbol:
- -
- Synonyms:
- SPIN-2, TDRD26
- Chromosome:
- Xp11.21
- Locus Type:
- gene with protein product
- Date approved:
- 2006-12-05
- Date modifiied:
- 2016-10-05
Related products to: SPIN2B antibody
Related articles to: SPIN2B antibody
- X chromosome-wide association studies (XWAS) have successfully identified risk loci on the X chromosome associated with Parkinson's disease (PD) susceptibility. However, only three such studies have been completed to date. Here, we present the first XWAS using an African cohort, comprising 690 PD cases and 826 controls. We applied an established XWAS workflow to perform male- and female-stratified analyses, as well as a combined meta-analysis. The male-stratified analysis identified five significant variants, including one lead locus (rs200539602), while the female-stratified analysis revealed 29 significant variants and two lead loci (rs2499550 and rs58045540), where rs2499550 is an upstream variant of the protein-coding gene . The remaining female-stratified significant variants are expression quantitative trait loci for , , and , which are highly expressed in the brain and nerve tissues, making them strong candidates for further investigation. One previously reported PD XWAS locus (rs28602900) was also replicated at a significance threshold of 0.05. The meta-analysis identified five variants surpassing chromosome-wide significance, including two lead loci (rs140715059 and rs141026964), the latter has no significant expression quantitative trait locus information but lies closest to the protein-coding gene , which may warrant further follow-up. None of the meta-analysis signals replicated in prior neurodegenerative disease XWAS. Overall, this study provides novel insights into the contribution of the X chromosome to PD susceptibility and represents the first PD XWAS to include participants of African ancestry, highlighting the importance of extending genetic studies to diverse populations. - Source: PubMed
Publication date: 2025/12/26
Step KathrynWaldo EmilyLeal Thiago PeixotoMendes MarlaBardien SorayaMata Ignacio F - Testicular development and spermatogenesis are complex phenomena controlled by various genetic factors, including miRNA-based post-transcriptional gene expression regulation. Exploring the miRNA expression patterns during testicular development in Dezhou donkeys would enhance our understanding of equine fertility and spermatogenesis. In this investigation, we examined the testicular miRNA profiles at various stages of development. The experimental animals were divided into three groups based on their developmental stages: 2 months old (juvenile: n = 3), 12 months old (adolescent; n = 3) and 24 months old (adult; n = 3) donkeys. Total RNA was extracted from dissected testicles for miRNA sequencing and analysis. In total, 586 miRNAs, including 451 known miRNAs and 135 novel miRNAs, were identified. Among identified miRNAs, 315 displayed age-dependent expression differences. The levels of miRNA expression in the juvenile group were significantly higher than in the adolescent or adult groups. The MiR-483 exhibited the maximum fold change between juvenile and adolescent groups. Several screened genes, including SLC45A4 and TFCP2L1, have been linked to male reproductive pathways in donkeys. In addition, miR-744 was predicted to regulate SPIN2B, a gene implicated in spermatocyte cell cycle progression and genomic integrity of spermatozoa. These results contribute to our comprehension of microRNA regulation during testicular development and spermatogenesis in Dezhou donkeys. The identified microRNAs and their target genes have the potential to serve as biomarkers for evaluating the reproductive capacity of stud donkeys. - Source: PubMed
Publication date: 2023/12/07
Ahmed ZulfiqarLiu WeiYu JieDong HongNaseer ZahidAhmad ImtiazAhmed ImranWang Xijun - Cattleyak exhibit equivalent adaptability to harsh environment as yak and much higher performances than yak. However, male infertility of cattleyak due to spermatogenic arrest greatly restricts their effective utilization in yak breeding. Although much work has been done to investigate the mechanisms of spermatogenic arrest, there is little information available in regard to the differences in transcriptomic profiling between cattleyak and yak testes. In this work, histologic observation indicated that spermatogonia were the main type of germ cells present in cattleyak testis, whereas all types of germ cells in differentiation were present in yak testis. Transcriptomic profiling identified 2960 differentially expressed genes (DEGs) in which 679 were upregulated and 2281 were downregulated in cattleyak. Significantly enriched gene ontology terms comprised a large number of DEGs associated with male infertility of cattleyak. The upregulation of STRA8 and NLRP14 may be associated with the accumulation of undifferentiated spermatogonial cells and serious cellular apoptosis in cattleyak. However, downregulated SPP1, SPIN2B, and PIWIL1 were associated with cell cycle progression and spermatogonial genome integrity, whereas CDKN2C, CYP26A1, OVOL1, GGN, MAK, INSL6, RNF212, TSSK1B, TSSK2, and TSSK6 were involved in meiosis. Furthermore, scores of genes associated with sperm components were also downregulated in cattleyak. Wnt/β-catenin signaling pathway was involved in the top-listed three significantly enriched pathways, and the downregulation of Wnt3a, PP2A, and TCF/LEF-1 may have contributed to the arrest of spermatogonial differentiation in cattleyak. The data suggest that spermatogenic arrest of cattleyak might occur at the stage of spermatogonial differentiation and get aggravated during meiosis, which results in minimal number of sperms with morphologic abnormalities and structural deficiency lacking fertilization ability. - Source: PubMed
Publication date: 2016/10/03
Cai XinYu ShuminMipam TserangDonkoYang FangZhao WangshengLiu WenjingCao SuiZhongShen LiuhongZhao FangfangSun LeiXu ChuanfeiWu Shixin