GGN3与GGNBP2的相互作用及作用区域确定

生殖细胞缺陷症(gcd)小鼠突变体是上世纪90年代初发现的一种不育突变小鼠,FancL(也叫Pog)的缺失是产生god突变小鼠的原因。FANCL是一种含有PHD结构域的泛素E3连接酶,是Fanconi贫血复合物中的组分之一。在生殖细胞中,FANCL与GGN1和GGN3相互作用,而GGN1和GGN3蛋白的功能还不清楚。为了研究GGN3的功能,揭示更多的参与该过程的蛋白质,运用Clontech公司新开发的第三套酵母双杂交系统以GGN3为诱饵从成年小鼠睾丸cDNA库中筛选与其相互作用的蛋白分子。发现了一个精子生成期间在睾丸中特异性高表达的基因Ggnbp2,免疫共沉淀分析表明,Ggnbp2编码的蛋白质产物GGNBP2在哺乳动物细胞中与GGN3特异相互作用。通过构建突变体,确定了GGNBP2蛋白与GGN3相互作用的区域。以上结果为揭示GGN3和GGNBP2在生殖发育中的功能、丰富生殖细胞发育的蛋白调控网络及其调控规律奠定了一定的基础。     

FANCL在原始生殖细胞的形成和范可尼贫血中的功能研究

Fanconi氏贫血是一种罕见的常染色体隐性遗传性疾病,表现为进行性骨髓衰竭、先天性骨骼畸形和易患癌症等。Fanconi aremia（FA）病人细胞染色体自发不稳定,并对DNA交联剂如丝裂霉素C高度敏感。目前已发现11种FA蛋白参与形成了一种DNA损伤应答途径。新蛋白FANCL是FA复合物蛋白,作为E3连接酶催化FANCD2单一泛素化,泛素化FANCD2导向染色质与BRCA2相互作用,修复DNA损伤。FANCL、FANCC和FANCA等FA蛋白缺失造成生殖细胞缺失性不育,胚胎期生殖细胞中FA途径可能调控原始生殖细胞的增殖。FANCL和睾丸特异性蛋白质GGNBP1、GGNBP2以及OAZ3都与睾丸特异性蛋白质GGN1相互作用,形成睾丸特异性复合物,有可能在成年睾丸中影响精子生成。     

睾丸特异蛋白GGN1稳定表达细胞株的建立

GGN1是1种功能未知的睾丸特异表达蛋白,它是睾丸特异性基因Ggn的表达产物。Ggn基因的原初转录产物有多种剪接方式,并最终翻译产生3种蛋白,GGN1就是其中的1种。研究发现Ggn的表达与精子的生成过程紧密相关。GGN1还可以与多种蛋白相互作用,其中包括FANCL,GGNBP1,GGNBP2和OAZ3。为了能够在体外更方便的研究Ggn及其相关基因的功能,通过脂质体转染和G418加压法筛选获得了能稳定表达pEGFP-N2／GGN1的CHO—K1细胞株。     

小鼠FANCL抗体制备及组织表达谱分析

FANCL是一个范可尼氏贫血新蛋白,它作为泛素E3连接酶催化FANCD2的单一泛素化,在修复DNA损伤、维持染色体稳定的FA途径中起着关键作用。胚胎期FANCL与小鼠原始生殖细胞增殖密切相关,成年睾丸中FANCL与几个生殖细胞特异性蛋白形成一个睾丸特异网络,可能参与影响精子的生成。采用RT-PCR方法从小鼠总RNA中扩增克隆FancL全长cDNA片段,构建表达质粒,在大肠杆菌中表达了6His-FANCL蛋白,用表达蛋白作为抗原免疫新西兰白兔制备了抗FANCL多抗血清。采用镍离子金属螯合柱纯化6His-FANCL蛋白后,通过与活性基团-NHS交联制备了FANCL抗原柱,亲和纯化了FANCL多抗。为了验证抗体活性和特异性,在HEK293T细胞中瞬时表达了HA-FANCL融合蛋白,分别用HA单抗和纯化多抗进行Western印迹分析,结果表明获得了特异性的FANCL抗体。为了观察FANCL在组织中的表达谱,制备了多种小鼠组织匀浆蛋白,使用纯化的FANCL多抗进行Western印迹分析,在脑、心、肺、肝、脾、肾、睾丸、卵巢、子宫和肌肉组织中都检测到FANCL蛋白的表达,说明FANCL在小鼠组织中是广泛表达的,这与其是DNA修复复合物中的重要成员相一致。     

GGNBP1抗体制备及小鼠组织表达谱分析

体外实验研究表明配子生成素结合蛋白1(GGNBP1)可能与GGN1相互作用形成睾丸特异性复合物,在精子生成过程中发挥作用.从小鼠睾丸总RNA中反转录扩增Ggnbpl全长cDNA,构建表达质粒,在大肠杆菌中表达GGNBP1,经聚丙烯酰胺凝胶纯化后免疫新西兰白兔,制备兔多抗血清.镍离子金属螯合柱纯化表达的GGNBP1蛋白,与NHS活化基团交联,制备GGNBP1抗体亲和层析柱,纯化GGNBP1多抗.在293FT细胞中瞬时表达Myc-GGNBP1融合蛋白,用于Mvc单抗验证GGNBP1抗体特异性,结果证明获得了特异性的GGNBP1抗体.分别制备小鼠脑、心、肺、肝、脾、肾、肌肉、卵巢、睾丸和子宫组织匀浆,用GGNBP1抗体进行Western印迹分析,结果仅在睾丸组织匀浆中检测到GGNBP1特异性条带,证明GGNBP1是睾丸特异性表达蛋白.     

Nanos3与生殖细胞发育分化

小鼠Nanos3基因是果蝇Nanos的同源基因,是Nanos基因家族的一员. Nanos3是一种RNA结合蛋白,靠近其C端有两个非常保守且连续的Cys-Cys-His-Cys特异锌指结构域.研究显 示,Nanos3在小鼠生殖细胞中特异表达,不仅在原始生殖细胞（primordial germ cells, PGCs）的维持方面发挥重要作用,而且是一种启动雄性生殖细胞分化程序的内源性因子, 其在精子发生中的重要作用已引起越来越多的关注.探讨Nanos3的生物学功能,有助于了解生殖细胞发育过程中的部分重要机制.本文就Nanos3维持生殖细胞更新和原始生殖细胞的 维持等作用作一综述.     

《生物技术通讯》2005年分类索引（第16卷，总第67-72期）

研究报告稳定表达HCV1aNS5A和NS5A-ΔISDR细胞株的构廖继佩,薛小平,徐志凯,等1GGN3与GGNBP2的相互作用及作用区域确曹志国,张进,周煜,等5小鼠脂联素受体2基因编码区的克隆及序列分王会中,陈竞新,詹林盛,等9丙型肝炎病毒ns3区全长基因在大肠杆菌中的高效表达及纯杨敬,薛小平,雷迎峰,等13大鼠转铁蛋白受体单链抗体和芋螺毒素SO3的融合蛋白在大肠杆菌中的表蒋世卫,周晓巍,颜冰,等16重组人脑源性神经营养因子在大肠杆菌中的可溶性表达及纯林艳丽,彭清忠,汤国营,等19TAT蛋白质转导结构域与SV40启动子特异的三锌指结构融合蛋白的表达…     

小鼠雄性生殖干细胞转录组分析揭示成熟精原干细胞特征

精原干细胞(spermatogonial stem cells, SSCs)是成年动物睾丸中的成体干细胞,具有自我更新与分化的能力。小鼠(Mus musculus)精原干细胞来源于胚胎期的原始生殖细胞(primodial germ cells, PGCs),小鼠出生前原始生殖细胞处于有丝分裂静止状态,出生后恢复增殖并由曲细精管中央迁移至管壁基质,建立稳定的精原干细胞克隆。成熟小鼠的精原干细胞周期性地启动精子发生以维持雄性动物长期稳定的生殖能力。精原干细胞在其建立和成熟后是否具有特征上的差异目前尚不清楚。本研究在前期建立的不同年龄小鼠精原干细胞(表达多能性基因Pou5f1编码的OCT4)转录组数据基础上,对小鼠新生期(出生后3天)、幼年期(出生后7天)和成熟期(2～3月龄)精原干细胞的基因表达差异进行了生物信息学分析,包括差异表达基因(differentially expression genes,DEGs)的筛选、DEGs编码的蛋白相互作用网络(protein-protein interaction,PPI)的建立、功能聚类富集(Gene Ontology,GO)和通路分析(Kyoto...     

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。     

Stra 8基因的激活与精原干细胞的特异性分化研究

视黄酸对维持正常的雄性睾丸结构和功能起着重要的作用。近来的研究发现,在雄性生殖腺发育过程中有一组基因,它们可以被视黄酸特异性的诱导活化,称为Stra(Stimulated by Retinoic Acid)基因。从鼠源分离得到的Stra8基因编码一种细胞质蛋白,该基因只特异性的在成熟雄性生殖细胞中表达,其功能被认为与精子形成有关。为研究Stra8基因的表达特性,我们从小鼠的基因组中克隆了Stra8基因的启动子序列(1.4kb)。将Stra8基因的1.4kb启动子序列克隆到pEGFP-1载体的EGFP基因之前,构建成由Stra8基因1.4kb启动子序列调控表达绿色荧光蛋白的pStra8-EGFP载体。将其分别转化到不同类型的细胞中,如小鼠ES-129细胞、人胎儿胰腺干细胞、小鼠骨髓间充质干细胞和小鼠精原干细胞等,通过荧光显微镜观察发现,绿色荧光蛋白只在小鼠精原干细胞中表达,表明Stra8基因是组织特异性表达的基因。将pStra8-EGFP转化小鼠骨髓间充质干细胞,经G418筛选2周后,用视黄酸诱导,12h培养后,有一部分转化pStra8-EGFP载体的细胞表达绿色荧光蛋白。RT-PCR证明这些细胞中有精原干细胞特异表达基因Stra8的转录,还有生殖细胞特异表达基因CyclinA8和Oct4的转录,这些结果说明小鼠骨髓间充质细胞经视黄酸的诱导可以向生殖细胞方向分化。     

Yeast two-hybrid screens imply that GGNBP1, GGNBP2 and OAZ3 are potential interaction partners of testicular germ cell-specific protein GGN1

Gametogenetin (Ggn) is a testicular germ cell-specific gene specifically expressed from late pachytene spermatocytes through round spermatids. The function of gametogenetin protein 1 (GGN1) remains unknown. Here, we used the yeast two-hybrid approach to look for more GGN1 interacting proteins. We found that gametogenetin binding protein 1 (GGNBP1), gametogenetin binding protein 2 (GGNBP2) and ornithine decarboxylase antizyme 3 (OAZ3) were potential GGN1 interaction partners. We determined the regions mediating the interactions and further showed the interactions between the proteins in mammalian cells by colocalization and coimmunoprecipitation experiments. Our work suggested that GGN1, GGNBP1, GGNBP2 and OAZ3 could be involved in a common process associated with spermatogenesis.     

Identification and characterization of a novel testicular germ cell-specific gene Ggnbp1

A novel gene Ggnbp1 was identified during yeast two-hybrid screening of gametogenetin protein 1 (GGN1)-interacting proteins. Ggnbp1 gene was found in mouse, rat, and human genomes but not in sequenced yeast, worms, fly, or fish genomes. Northern blotting analysis revealed that the gene was specifically expressed in the testis but not expressed in the other tissues. In situ hybridization showed that it was testicular germ cell-specific and was specifically expressed in later primary spermatocytes, meiotic cells, and early round spermatids. Western blotting analysis detected a protein of expected size in and only in the testis. By making membrane and cytosolic fractions of germ cells, we were able to show that GGNBP1 associated with the membrane. The identification and characterization of a novel germ cell-specific gene Ggnbp1 is the first step toward the defining of the functions of Ggnbp1 in spermatogenesis.     

Loss of GGN Leads to Pre-Implantation Embryonic Lethality and Compromised Male Meiotic DNA Double Strand Break Repair in the Mouse

The integrity of male germ cell genome is critical for the correct progression of spermatogenesis, successful fertilization, and proper development of the offspring. Several DNA repair pathways exist in male germ cells. However, unlike somatic cells, key components of such pathways remain largely unidentified. Gametogenetin (GGN) is a testis-enriched protein that has been shown to bind to the DNA repair protein FANCL via yeast-two-hybrid assays. This finding and its testis-enriched expression pattern raise the possibility that GGN plays a role in DNA repair during spermatogenesis. Herein we demonstrated that the largest isoform GGN1 interacted with components of DNA repair machinery in the mouse testis. In addition to FANCL, GGN1 interacted with the critical component of the Fanconi Anemia (FA) pathway FANCD2 and a downstream component of the BRCA pathway, BRCC36. To define the physiological function of GGN, we generated a Ggn null mouse line. A complete loss of GGN resulted in embryonic lethality at the very earliest period of pre-implantation development, with no viable blastocysts observed. This finding was consistent with the observation that Ggn mRNA was also expressed in lower levels in the oocyte and pre-implantation embryos. Moreover, pachytene spermatocytes of the Ggn heterozygous knockout mice showed an increased incidence of unrepaired DNA double strand breaks (DSBs). Together, our results suggest that GGN plays a role in male meiotic DSB repair and is absolutely required for the survival of pre-implantation embryos.     

Generation of Mouse FANCL Antibody and Analysis of FANCL Protein Expression Profile in Mouse Tissues

Fanconi anemia complementation group L (FANCL) is a novel Fanconi anemia protein, which mono-ubiquitinates FANCD2 as a ubiquitin E3 ligase, and plays a crucial role in DNA damage repair and chromosome stability maintenance. FANCL is involved in the proliferation of primordial germ cells (PGC) in early embryonic stages, and may play a role in the development of germ cells by forming a novel testis-specific network with testis-specific proteins in the adult testis. FancL cDNA sequence was cloned by RT-PCR from mouse testis total RNA, and expressed in E. coli BL21(DE3). Rabbit FANCL polyclonal antiserum was generated using the recombinant protein as the antigen. To prepare an antigen column for affinity purification of FANCL-specific antibody, recombinant His-tagged FANCL was purified by Ni²⁺-charged HiTrap Chelating HP column and coupled to an NHS-activated HiTrap column. To confirm the activity and specificity of the FANCL antibody, we constructed plasmid pCMV-HA/FANCL to transfect HEK 293T cells. Transiently expressed HA-FANCL fusion protein was analyzed by immunoblotting with both the FANCL antibody and HA monoclonal antibody. The antibody was used in Western blotting to check the expression of FANCL protein in mouse tissues. We found wide expression of FANCL in brain, muscle, heart, lung, liver, spleen, kidney, testis, ovary and uterus, indicating the functional importance of this novel protein.     

Mouse GGN1 and GGN3, two germ cell-specific proteins from the single gene Ggn,interact with mouse POG and play a role in spermatogenesis

The germ cell-deficient (gcd) mutation is a recessive transgenic insertional mutation leading to a deficiency of primordial germ cells (PGCs). We have recently shown that the gene underlying this mutation is Pog, which is necessary for normal proliferation of PGCs. Here we show that Pog is also involved in spermatogenesis in that meiosis is impaired in Pog-deficient mice. Yeast two-hybrid screening revealed that POG interacted with GGN1 and GGN3, two proteins formed by alternate splicing of the same gene, gametogenetin (Ggn). Ggn had more than 10 different splice variants giving rise to three proteins, GGN1, GGN2, and GGN3. The three proteins had different subcellular localizations, with GGN1, GGN2, and GGN3 localized along the nuclear membrane, in the cytoplasm, and in the nucleus/nucleoli respectively. The expression of Ggn was confined to late pachytene spermatocytes and round spermatids, a time window concomitant with the occurrence of meiosis. Mouse Ggn and Pog were both expressed in primary spermatocytes. Co-expression of POG with GGN1 or GGN3 in HeLa cells changed the localization of POG to the perinuclear localization or the nucleoli, respectively. Our data showed that in addition to functioning in proliferation of primordial germ cells, POG also functioned in spermatogenesis. Two spatial and temporal regulated proteins, GGN1 and GGN3, interacted with POG, regulated the localization of POG, and played a role in spermatogenesis.     

Late onset of spermatogenesis and gain of fertility in POG-deficient mice indicate that POG is not necessary for the proliferation of spermatogonia

The germ cell-deficient (gcd) mouse mutation is a recessive, transgenic insertional mutation associated with the disruption of two Chr11 genes, Pog (proliferation of germ cells) and Vrk2 (vaccinia virus-related protein kinase 2). We have recently shown that like gcd/gcd mice, targeted Pog-/- males and females show virtually no spermatogenesis or oogenesis at 4-6 wk of age. Because Pog is deleted in gcd/gcd and Pog-/- mice, a comparison of the phenotypes of the two mouse models is appropriate. Here, we report that unlike in POG-deficient females, the germ cells in POG-deficient males eventually populate the seminiferous tubules at 9 wk, and fertility can be achieved by 12 wk. Homozygous gcd/gcd males did not show a similar degree of germ cell population, and most gcd/gcd males remained infertile at 16 and 22 wk of age. A comparison of the degree of germ cell deficiency at 13.5 days postcoitum and 1 day postpartum between Pog-/- and gcd/gcd males revealed that gcd/gcd males had far fewer germ cells than Pog-/- males at both time points. Our data suggest that Pog is essential for proper primordial germ cell proliferation in the embryonic stage but is not needed for spermatogonial proliferation after birth. Thus, the difference in the spermatogenetic potential in adult Pog-/- and gcd/gcd mice may result from the severity of germ cell deficiency rather than from the inability of gcd/gcd spermatogonia to proliferate efficiently. The greater deficiency of germ cells before the onset of spermatogenesis seen in gcd/gcd males compared to Pog-/- mice suggests either that the different background affects the outcome of Pog deletion or that Vrk2 has additional effects on germ cell development.