Genetic etiological spectrum of sperm morphological abnormalities.

IF 3.2 3区医学 Q2 GENETICS & HEREDITY

Journal of Assisted Reproduction and Genetics Pub Date : 2024-10-17 DOI:10.1007/s10815-024-03274-8

Manvi Arora, Poonam Mehta, Shruti Sethi, George Anifandis, Mary Samara, Rajender Singh

{"title":"Genetic etiological spectrum of sperm morphological abnormalities.","authors":"Manvi Arora, Poonam Mehta, Shruti Sethi, George Anifandis, Mary Samara, Rajender Singh","doi":"10.1007/s10815-024-03274-8","DOIUrl":null,"url":null,"abstract":"Purpose: Male infertility manifests in the form of a reduction in sperm count, sperm motility, or the loss of fertilizing ability. While the loss of sperm production can have mixed reasons, sperm structural defects, cumulatively known as teratozoospermia, have predominantly genetic bases. The aim of the present review is to undertake a comprehensive analysis of the genetic mutations leading to sperm morphological deformities/teratozoospermia.Methods: We undertook literature review for genes involved in sperm morphological abnormalities. The genes were classified according to the type of sperm defects they cause and on the basis of the level of evidence determined by the number of human studies and the availability of a mouse knockout.Results: Mutations in the SUN5, CEP112, BRDT, DNAH6, PMFBP1, TSGA10, and SPATA20 genes result in acephalic sperm; mutations in the DPY19L2, SPATA16, PICK1, CCNB3, CHPT1, PIWIL4, and TDRD9 genes cause globozoospermia; mutations in the AURKC gene cause macrozoospermia; mutations in the WDR12 gene cause tapered sperm head; mutations in the RNF220 and ADCY10 genes result in small sperm head; mutations in the AMZ2 gene lead to vacuolated head formation; mutations in the CC2D1B and KIAA1210 genes lead to pyriform head formation; mutations in the SEPT14, ZPBP1, FBXO43, ZCWPW1, KATNAL2, PNLDC1, and CCIN genes cause amorphous head; mutations in the SEPT12, RBMX, and ACTL7A genes cause deformed acrosome formation; mutations in the DNAH1, DNAH2, DNAH6, DNAH17, FSIP2, CFAP43, AK7, CHAP251, CFAP65, ARMC2 and several other genes result in multiple morphological abnormalities of sperm flagella (MMAF).Conclusions: Altogether, mutations in 31 genes have been reported to cause head defects and mutations in 62 genes are known to cause sperm tail defects.","PeriodicalId":15246,"journal":{"name":"Journal of Assisted Reproduction and Genetics","volume":" ","pages":""},"PeriodicalIF":3.2000,"publicationDate":"2024-10-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Assisted Reproduction and Genetics","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1007/s10815-024-03274-8","RegionNum":3,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"GENETICS & HEREDITY","Score":null,"Total":0}

引用次数: 0

Abstract

Purpose: Male infertility manifests in the form of a reduction in sperm count, sperm motility, or the loss of fertilizing ability. While the loss of sperm production can have mixed reasons, sperm structural defects, cumulatively known as teratozoospermia, have predominantly genetic bases. The aim of the present review is to undertake a comprehensive analysis of the genetic mutations leading to sperm morphological deformities/teratozoospermia.

Methods: We undertook literature review for genes involved in sperm morphological abnormalities. The genes were classified according to the type of sperm defects they cause and on the basis of the level of evidence determined by the number of human studies and the availability of a mouse knockout.

Results: Mutations in the SUN5, CEP112, BRDT, DNAH6, PMFBP1, TSGA10, and SPATA20 genes result in acephalic sperm; mutations in the DPY19L2, SPATA16, PICK1, CCNB3, CHPT1, PIWIL4, and TDRD9 genes cause globozoospermia; mutations in the AURKC gene cause macrozoospermia; mutations in the WDR12 gene cause tapered sperm head; mutations in the RNF220 and ADCY10 genes result in small sperm head; mutations in the AMZ2 gene lead to vacuolated head formation; mutations in the CC2D1B and KIAA1210 genes lead to pyriform head formation; mutations in the SEPT14, ZPBP1, FBXO43, ZCWPW1, KATNAL2, PNLDC1, and CCIN genes cause amorphous head; mutations in the SEPT12, RBMX, and ACTL7A genes cause deformed acrosome formation; mutations in the DNAH1, DNAH2, DNAH6, DNAH17, FSIP2, CFAP43, AK7, CHAP251, CFAP65, ARMC2 and several other genes result in multiple morphological abnormalities of sperm flagella (MMAF).

Conclusions: Altogether, mutations in 31 genes have been reported to cause head defects and mutations in 62 genes are known to cause sperm tail defects.

查看原文本刊更多论文

精子形态异常的遗传病因谱。

目的：男性不育表现为精子数量减少、精子活力降低或丧失受精能力。虽然精子生成的丧失可能有多种原因，但精子结构缺陷，即畸形精子症，主要是由遗传因素造成的。本综述旨在全面分析导致精子形态畸形/畸形精子症的基因突变：我们对涉及精子形态异常的基因进行了文献综述。方法：我们对涉及精子形态异常的基因进行了文献综述，并根据这些基因导致的精子缺陷类型以及人类研究数量和小鼠基因敲除的证据水平对这些基因进行了分类：结果：SUN5、CEP112、BRDT、DNAH6、PMFBP1、TSGA10和SPATA20基因突变导致畸形精子；DPY19L2、SPATA16、PICK1、CCNB3、CHPT1、PIWIL4和TDRD9基因突变导致无精子症；AURKC 基因突变导致大无精症；WDR12 基因突变导致精子头部变细；RNF220 和 ADCY10 基因突变导致精子头部变小；AMZ2 基因突变导致头部形成空泡；CC2D1B和KIAA1210基因突变导致梨形头形成；SEPT14、ZPBP1、FBXO43、ZCWPW1、KATNAL2、PNLDC1和CCIN基因突变导致无定形头；SEPT12、RBMX和ACTL7A基因突变导致畸形顶体形成；DNAH1、DNAH2、DNAH6、DNAH17、FSIP2、CFAP43、AK7、CHAP251、CFAP65、ARMC2 和其他几个基因的突变导致精子鞭毛的多种形态异常（MMAF）。结论据报道，31 个基因的突变可导致精子头部缺陷，62 个基因的突变可导致精子尾部缺陷。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Journal of Assisted Reproduction and Genetics 医学-妇产科学

CiteScore

5.70

自引率

9.70%

发文量

286

审稿时长

1 months

期刊介绍： The Journal of Assisted Reproduction and Genetics publishes cellular, molecular, genetic, and epigenetic discoveries advancing our understanding of the biology and underlying mechanisms from gametogenesis to offspring health. Special emphasis is placed on the practice and evolution of assisted reproduction technologies (ARTs) with reference to the diagnosis and management of diseases affecting fertility. Our goal is to educate our readership in the translation of basic and clinical discoveries made from human or relevant animal models to the safe and efficacious practice of human ARTs. The scientific rigor and ethical standards embraced by the JARG editorial team ensures a broad international base of expertise guiding the marriage of contemporary clinical research paradigms with basic science discovery. JARG publishes original papers, minireviews, case reports, and opinion pieces often combined into special topic issues that will educate clinicians and scientists with interests in the mechanisms of human development that bear on the treatment of infertility and emerging innovations in human ARTs. The guiding principles of male and female reproductive health impacting pre- and post-conceptional viability and developmental potential are emphasized within the purview of human reproductive health in current and future generations of our species. The journal is published in cooperation with the American Society for Reproductive Medicine, an organization of more than 8,000 physicians, researchers, nurses, technicians and other professionals dedicated to advancing knowledge and expertise in reproductive biology.