小鼠睾丸生精细胞凋亡相关基因mTSARG3的克隆

从在小鼠隐睾和正常睾丸对照中表达量有明显差异的EST片段 (BE6 4 4 5 37)出发 ,利用GeneScan软件分析该片段所在染色体基因组序列 ,获得一个包含该EST的新基因序列。设计该基因特异性引物从小鼠睾丸cDNA文库中进行PCR扩增 ,分离出小鼠睾丸生精细胞凋亡相关基因mTSARG3(GenBank登录号为AF4 192 92 )。该基因定位于小鼠 7号染色体 7E1 E2区带 ,全长为 11kb ,cDNA全长为 132 8bp ,包含 8个外显子 ,编码由 316个氨基酸组成的、分子量为 36kD的蛋白质。该蛋白质含有DnaJ区和DnaJ- c区 ,与热激蛋白 4 0家族多种蛋白质有较高相似性 ,其中与小鼠DJB4 - MOUSE在 336aa的范围内有 4 6 %的相似性 ,属热激蛋白 4 0家族新成员。多组织RT PCR和Northern印迹结果显示 ,该基因在小鼠睾丸组织高表达 ,转录本大小约为 1.35kb ;Southern杂交结果显示 ,该基因在小鼠正常睾丸和隐睾组织无缺失和重排。实验结果证明成功克隆到了一个小鼠睾丸生精细胞凋亡相关基因mT SARG3。     

利用电子差异展示方法克隆人类睾丸高表达新基因SPATA11

利用NCBI中的电子差异展示(digital differential display,DDD)软件,比较来自睾丸(包括睾丸癌)与来自其它组织的EST文库,从筛查人类睾丸中高表达而在其他组织中不表达或低表达的差异ESTs入手,成功克隆了一个在人类睾丸中高表达的新基因SPATA11．RT-PCR实验证实其在成人睾丸高表达．序列分析表明该基因含4个外显子,基因组跨越2．6kb,定位于19pl3．3．cDNA编码一个含221个氨基酸,相对分子质量为24．5kD的新蛋白．Northern杂交结果显示：该基因含有1．1kb大小的唯一转录本,主要在睾丸中强表达．肝脏、肺、卵巢和肾脏中有微弱表达．而其他组织中该基因无表达．     

一个新的睾丸特异表达基因的克隆及功能的初步分析

运用“数据库消减杂交”(digital differential display)方法来筛选人类睾丸特异表达新基因,获得了有差异显示的代表新基因的克隆重叠群。挑选其中一个克隆重叠群HS．326528进行多组织RT—PCR,初步获得该重叠群在人睾丸中有高表达。从该重叠群的IMAGE出发,采用生物信息学的方法快速克隆了一个人类新基因的全长cDNA序列,其全长1044bp,开放阅读框为214～529bp,定位于15q26．2,编码由105个氨基酸组成、分子量为11．7kD、等电点为10．09的一个碱性蛋白,该蛋白与已知蛋白无明显的同源性,克隆实验证明该基因的阅读框完全正确,RT—PCR和Northern blot显示该基因在人类睾丸中特异表达,实时PCR结果表明：该基因在成人睾丸中高表达,在精子中有中度表达,在胚胎睾丸中低表达,推测该基因与精子的生成有关,命名为SRG8(homo sapiens spermatogenesis—related gene 8)(GenBank登录号：AY489187),该基因编码的蛋白定位于细胞核。流式结果分析表明,SRG8基因能够促使HeLa细胞由S期向G2期的转变,从而加速细胞的分裂。这些结果表明SRG8基因可能在睾丸的发育及精子的形成过程中起重要的作用。     

一种新型锌指蛋白基因——人ZNF313的克隆、定位及表达

运用正常可育男性和无精症病人睾丸组织的mRNA差异显示和cDNA末端快速扩增（PACE）等方法,从人睾丸组织中分离了一个同时含有指环结构和C2H2结构域的新型锌指蛋白基因——人ZNF313。运用荧光原位杂交（FISH）方法,将该基因定位到人染色体20q13。该基因含6个外显子,编码228个氨基酸。基因组结构分析显示,外显子6含有的2个加尾信号,产生2种不同的3‘端非翻译区。Northern杂交及多组织RT-PCR的结果显示该基因含有0.75kb和2.4kb两种转录本,其中0.75kb转录本在正常睾丸中高表达,而其他组织、无精症患者及胎儿睾丸组织中该基因代表达。结果提示：人ZNF313基因对精子发生和男性可育性可能起重要作用。     

运用数字差异展示方法克隆一个人类新的锌指蛋白基因ZNF474

运用数字差异展示方法,克隆一个与生精相关的睾丸高表达基因。借助公共ESTs数据库,利用DDD软件比较分析各种睾丸文库与其他组织或细胞系文库有差异表达的ESTs,成功克隆到一个在人类睾丸中高表达的新基因。结合实验获得新基因cDNA全长,该基因被国际人类基因命名委员会命名为ZNF474(GeneBank登陆号AY461732)。ZNF474的cDNA全长为1 972 bp,定位在5 q23.2。通过RT-PCR及测序验证,其开放阅读框的位置在377 bp~1 471 bp处,编码364个氨基酸,在氨基酸水平与小鼠同源基因有66%的一致性,而与其他已知蛋白质无明显同源性。Northern杂交分析显示ZNF474在成体睾丸组织特异高表达,卵巢组织弱表达,在多种其他组织中不表达,为单一转录本。原位杂交显示ZNF474基因在正常成人睾丸组织各级生精细胞、隐睾组织以及精原细胞癌组织中均有较高表达。综上考虑,推测ZNF474作为生殖细胞中特异的转录因子,对人类的精子发生和卵母细胞的发育可能起重要作用。     

睾丸生精细胞凋亡相关基因TSARG1与Mtsarg1的分子克隆及Mtsarg1基因的表达谱分析

从已获得的在隐睾和正常睾丸对照中表达量有明显差异的EST片段（GenBank登录号：BE644538）出发,利用生物信息学和实验技术,克隆了小鼠睾丸生精细胞凋亡相关新基因Mtsarg1及相应的人类新基因TSARG1,Gen-Bank登录号分别为AF399971和AY032925。小鼠Mtsargl与人类TSARGl基因在氨基酸水平有55％的一致性和61％相似性,与其他已知蛋白质无明显同源性。小鼠10种组织的RT-PCR分析结果表明,Mtsargl基因在睾丸中高表达,在附睾中呈微弱表达,在其他组织不表达,提示Mtsargl和TSARGl基因在生精细胞凋亡或精子发生中具有潜在的重要作用。     

一种新型锌指蛋白基因——人ZNF313的克隆、定位及表达(英文 )

运用正常可育男性和无精症病人睾丸组织的mRNA差异显示和cDNA末端快速扩增 (RACE)等方法 ,从人睾丸组织中分离了一个同时含有指环结构和C2 H2 结构域的新型锌指蛋白基因———人ZNF3 13。运用荧光原位杂交 (FISH)方法 ,将该基因定位到人染色体 2 0q13。该基因含 6个外显子 ,编码 2 2 8个氨基酸。基因组结构分析显示 ,外显子 6含有的 2个加尾信号 ,产生 2种不同的 3′端非翻译区。Northern杂交及多组织RT PCR的结果显示该基因含有 0 .75kb和 2 .4kb两种转录本 ,其中0 .75kb转录本在正常睾丸中高表达 ,而其他组织、无精症患者及胎儿睾丸组织中该基因低表达。结果提示 :人ZNF3 13基因对精子发生和男性可育性可能起重要作用     

包含BTB锌指结构的新基因Bsg2结构特性及其在发育阶段的组织表达特异性

通过消减差异筛选法寻找小鼠胚胎发育过程中在脑中特异表达的基因 .克隆得到的脑特异表达新基因 2 (brainspecificgene 2 ,简称Bsg2 )长 36 91bp ,通过生物信息学方法预测其编码一个含713个氨基酸的锌指蛋白 .此蛋白N端有一个BTB(BR C ,ttkandbab)结构域 ,C端有 9个连续的C2H2锌指结构 .该基因定位在小鼠 12号染色体上 ,包含 1个内含子和 2个外显子 .应用生物信息学和RT PCR方法分别检验该基因在小鼠各组织中的表达 .结果表明 ,Bsg2基因在小鼠胚胎及成体的各组织中普遍表达 ,在脾、肾、睾丸、肠、子宫和脑的表达水平较强 .利用整体 (wholemount)原位杂交研究其时空表达模式 .结果显示 ,Bsg2在早期的小鼠胚胎和不同时期鸡胚的头部均特异表达 ,在11d鼠胚的肢芽里也有较强的表达 .Bsg2基因的结构和表达特征预示它编码 1个具有DNA结合功能的转录调控因子 ,同时揭示它在脑的发育和器官形成过程中发挥着重要作用     

非洲爪蟾基因MGC64236的克隆及初步分析

MGC64236基因是本实验室用脐静脉内皮细胞免疫的兔血清筛选非洲爪蟾cDNA文库而鉴定的一个功能未知的基因.本研究提取非洲爪蟾受精卵总RNA通过RT-PCR得到基因MGC64236的开放读码框651 bp、编码202个氨基酸;运用生物信息学研究工具进行分析,发现该基因编码的蛋白有3个潜在的跨膜域,有一保守的结构域DUF1370, 可能通过其胞内部分的磷酸化机制在介导细胞内外的信号转导中发挥重要作用;在非洲爪蟾胚胎各个发育时期用RT-PCR检测该基因的表达情况,发现在非洲爪蟾胚胎发育的几个重要时期该基因都有高表达,而在成体则特异地表达于脑和眼等神经组织;构建绿色荧光融合蛋白真核表达载体并转染HEK293细胞, 对MGC64236蛋白的亚细胞定位,发现MGC64236蛋白比较特异地表达在细胞膜.     

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.     

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.     

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.