硬骨鱼中vasa基因的研究

vasa基因编码一个DEAD-box家族的ATP依赖性RNA解旋酶,最早在果蝇中发现.在绝大多数的脊椎动物和非脊椎动物中,vasa基因的杂交信号仅在生殖细胞系中特异性表达,因此它可以作为一种分子标签,广泛用于性腺发生、配子发生、原生殖细胞(primordial germ cells,PGCs)的起源、迁移、分化等方面的研究.综述了国内外有关硬骨鱼类vasa基因结构,表达与功能等方面的研究报道,并对其应用前景作了展望.     

优雅蝈螽VASA蛋白cDNA序列的克隆与生物信息学分析

Vasa基因属于DEAD-box家族,其功能主要是特定mRNA的翻译调控。在许多动物中,它都是生殖系细胞发育所必须,对生殖干细胞分化具有重要作用。为探究vasa基因在半变态类昆虫生殖系细胞发育中的作用,本研究首先从基于Illumina高通量测序平台测得的优雅蝈螽Gampsocleis gratiosa成体转录组数据中筛选出一段长度为1215 bp的vasa基因片段,进而设计引物并利用RT-PCR和RACE技术获得其c DNA序列全长,最后利用生物信息学技术进行分析。结果显示:优雅蝈螽vasa基因的c DNA序列全长3359 bp,其中,5'端非编码区82bp,3'端非编码区1306 bp,开放阅读框1971 bp编码656个氨基酸,理论蛋白相对分子量(Mw)72.3 k Da,等电点(p I)5.48。通过与Gen Bank数据库中收录的其他VASA蛋白序列比对,发现优雅蝈螽VASA蛋白具有DEAD-box蛋白家族所共有的9个保守基序,Ax TGo GKT(I)、PTRELA(Ia)、TPGR(Ib)、DEAD(Ⅱ)、SAT(Ⅲ)、LVFVE(Ⅳ)、TDVu ARGID(Ⅴ)、HRIGRTGR(Ⅵ)和Gacc Poh1Q(Q),其中,Gacc Poh1Q(Q)的第3个氨基酸残基存在显著变化,建议将Gacc Poh1Q(Q)修改为Gaxc Poh1Q(Q)。此外,优雅蝈螽VASA蛋白的N端还具有10个RG和2个RGG重复序列、起始及终止密码子附近的色氨酸(W)、C末端的7个氨基酸残基中有4个为酸性氨基酸残基(E),表明其具有ATP依赖的RNA解旋酶活性。基于氨基酸序列聚类结果显示:优雅蝈螽位于六足动物分枝末梢,与双斑蟋Gryllus bimaculatus的亲缘关系最近,这与二者的分类学地位相符。本研究表明基于短读长二代测序平台获得的转录组数据可以很好地服务于功能基因研究,所获得的优雅蝈螽vasa基因c DNA全长对于进一步深入研究VASA蛋白在半变态类昆虫生殖系细胞发育研究具有重要意义。     

山羊生殖细胞特异报告载体pVASA-EGFP的构建及表达

为监测成体干细胞向生殖细胞分化的过程,分析生殖细胞特异性DEAD-box家族ATP依赖RNA解旋酶vasa在不同日龄山羊睾丸组织中的表达情况并构建山羊生殖细胞特异性报告载体p VASA-EGFP。通过免疫荧光及RT-PCR法监测vasa的表达情况,利用分子技术构建报告载体p VASA-EGFP,脂质体法转染山羊骨髓间充质干细胞(Bone mesenchymal stem cells,BMSCs),经过视黄酸(Retinoic acid,RA)诱导后,观察绿色荧光蛋白表达情况以鉴定该报告载体的有效性。免疫荧光结果显示,Vasa在性成熟不同阶段的山羊睾丸组织中均有表达,RT-PCR结果表明vasa基因在3月龄、10月龄山羊睾丸组织中显著高于10日龄组。测序及酶切鉴定结果表明,扩增的vasa基因启动子片段成功连至N1载体,转染BMSCs后经4 d的RA诱导,发现有绿色荧光蛋白表达,表明成功构建了山羊vasa基因启动子调控的报告载体p VASA-EGFP。以上结果表明,vasa基因在不同日龄山羊睾丸组织中均有表达,所构建的山羊生殖细胞特异性报告载体p VASA-EGFP具有示踪山羊成体干细胞向生殖细胞分化过程的能力,为下一步监测山羊BMSCs向生殖细胞分化的过程提供了鉴定和筛选方法。     

果蝇原生殖细胞特化的分子机制

原生殖细胞在许多有性生殖动物的胚胎发育早期就已特化出来,并进一步分化为生殖细胞以产生新的子代。动物原生殖细胞的特化主要有生殖质决定和诱导两种模式,果蝇原生殖细胞的特化模式属于前者。研究表明,果蝇原生殖细胞特化过程中生殖质组装的关键基因是osk,其调控下游基因转录产物的定位和翻译,如vas和tud。此外,基因转录沉默是原生殖细胞特化过程的一个重要特征,其与生殖质中的成分如基因nos、gcl、pgc的表达产物密切相关。现对果蝇原生殖细胞特化分子机制进行综述。     

中华鳖vasa基因克隆及在卵母细胞中的表达分析

研究利用中华鳖为研究模型进行爬行类生殖细胞发育分化成熟等生物学研究,克隆了中华鳖vasa基因的cDNA序列,全长3865 bp,包括5'端非编码区90 bp,3'端非编码区1699 bp,开放阅读框长2076 bp,共编码691个氨基酸。中华鳖Vasa氨基酸序列包含DEAD-box家族蛋白8个保守保守功能域,在N末端有4个RGG重复序列和2个GG富集区,与小鼠Vasa蛋白的同源性较高（72%）。荧光定量PCR的结果表明,中华鳖vasa mRNA主要精巢和卵巢中表达,其他体组织中均难检测到表达。卵巢冰冻切片原位杂交结果显示:中华鳖vasa mRNA在生殖细胞中特异表达;在卵子发生过程中的不同发育期卵母细胞中呈现动态的变化。即vasa mRNA在初级卵母细胞及生长期卵母细胞中表达最强,且均匀分布在细胞质中,随着卵母细胞的逐渐增大,信号逐渐减弱,直至在成熟的卵母细胞中几乎检测不到表达信号,说明vasa可能在中华鳖早期卵母细胞发育中起重要作用。同时,vasa基因可作为中华鳖生殖细胞分子标记物,根据其mRNA的表达水平来鉴别不同发育时期的卵母细胞。研究结果为进一步开展中华鳖胚胎生殖细胞发育及配子生成,特别是研究中华鳖,乃至爬行类原始生殖细胞（Primordial Germ Cells,PGCs）的起源、迁移、分化等研究奠定了基础。     

马氏珠母贝Pm-vasa基因的克隆与表达分析

vasa蛋白是DEAD-box家族蛋白的一员,在真核生物原生殖细胞形成过程中起关键作用。本实验利用RACE技术克隆获得了马氏珠母贝vasa基因(Pm-vasa),并对其结构和组织表达模式进行了分析。结果表明:Pm-vasa c DNA序列全长为1 709 bp,其中开放式阅读框1 431 bp、5'UTR 148 bp、3'UTR 131 bp,共编码476个氨基酸,分子量为52.139 k D,理论等电点为6.24。SMART软件分析显示Pm-vasa蛋白具有典型的DEAD-box结构域,且具DEAD-box家族蛋白9个典型保守基序。多序列比对结果表明Pm-vasa与紫贻贝vasa同源性最高,为74%;系统进化分析发现,Pm-vasa与紫贻贝等软体动物聚为一支。组织表达定量分析发现Pm-vasa基因m RNA在性腺中显著高表达。我们的研究结果表明Pm-vasa可能参与马氏珠母贝的性腺发育。     

金鱼配子发生中vasa基因的表达和分布特征

用原位杂交技术,以地高辛标记的反义RNA为探针,检测了金鱼(Carassiusauratus)DEAD box家族基因vasa在卵子及精子发生中的分布及表达。结果表明在金鱼卵子发生中,在各个时期的卵母细胞的胞质中均有金鱼vasaRNA的杂交信号表达。在Ⅰ、Ⅱ期卵母细胞中vasaRNA的杂交信号强烈,均匀地分布在整个胞质。随着卵母细胞的生长发育及卵黄的积累,Ⅲ、Ⅳ期卵母细胞胞质中vasaRNA的杂交信号急剧减弱,而外周皮层区域,其阳性信号仍较强。在金鱼精子发生中,在精原细胞和初级精母细胞中可检测到金鱼vasaRNA杂交信号,后者的阳性信号比前者微弱;而精子细胞中没有阳性信号。推测vasa基因在金鱼精子发生早期发挥着重要作用;而在卵子发生中主要作为遗传信息储备物质,用于调控早期胚胎发育过程中原始生殖细胞的形成与分化。     

鹌鹑gcl基因BTB/POZ结构域编码序列的克隆及组织中的表达

Germ cell-less(GCL)是与原始生殖细胞发生相关的重要因子,果蝇、斑马鱼、青鳉鱼和小鼠的GCL蛋白都含有一个进化上保守的BTB/POZ结构域。本研究应用简并PCR克隆技术,在鹌鹑(Coturnix coturnix)中扩增得到319bp的gcl基因(包含BTB/POZ结构域编码序列)保守序列。通过与线虫、果蝇、斑马鱼、小鼠和人gcl同源序列的比对,发现该片段与它们的同源性分别为52.4%、55.4%、84.6%、79.6%和76.8%。采用RT-PCR和mRNA整体原位杂交方法,研究了gcl基因在不同组织和原条期胚胎中的表达。结果显示,该基因在卵巢、精巢和肝中表达;gcl mRNA存在于原条期胚胎的生殖新月区。     

黄鳝性腺自然逆转过程中vasa基因的表达分析

本研究采用RNA反义探针原位杂交技术,对vasa基因在黄鳝(Monopterusalbus)性腺发育过程中的表达情况进行了分析。结果表明:vasamRNA在Ⅰ、Ⅱ、Ⅲ期卵母细胞的胞质中均匀分布,在Ⅳ、Ⅴ期卵母细胞中vasamRNA有向胞质外周皮层迁移集中的趋势,但不明显;退化的卵粒也呈现vasamRNA阳性反应;在Ⅲ、Ⅳ期卵巢的被膜中检测到带有vasa阳性信号的细胞,这些细胞可能是待向精原细胞分化、迁移到卵巢被膜上的原始生殖细胞(Primordialgermcell,PGC),在性逆转过程中这些PGC可能由卵巢被膜迁移到精小叶中并发育成精子;在成熟精巢中,vasa在精原细胞和初级精母细胞中表达。进一步采用碱性磷酸酶染色法分析黄鳝卵巢及精巢后发现:在卵巢中,除了卵母细胞外,卵巢被膜中也检测到了带有碱性磷酸酶阳性信号的细胞;在成熟精巢中,只在生殖腺囊内的雄性生殖细胞中检测到碱性磷酸酶,而精巢被膜中没有检测到带有碱性磷酸酶阳性信号的细胞。本研究结果初步表明:黄鳝的雄性生殖细胞可能起源于雌性阶段卵巢被膜中的原始生殖细胞[动物学报51(3):469-475,2005]。     

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.     

Vasa homolog genes in mammalian germ cell development

Many vasa homologue genes to Drosophila vasa have been isolated in various animal species. They provide specific molecular probes to analyze the establishment and the differentiation of germ cell lineage. In mammals, the expression of VASA protein becomes detectable in PGCs at the late migrating stage. Interestingly, during spermatogenesis the intracellular localization of VASA protein is closely associated with the chromatoid body.     

Exploring embryonic germ line development in the water flea, Daphnia magna, by zinc-finger-containing VASA as a marker

VASA is an ATP-dependent RNA helicase belonging to the DEAD-box family that, in many organisms, is specifically expressed in germ line cells throughout the life cycle, making it a powerful molecular marker to study germ line development. To obtain further information on germ line development in crustaceans, we cloned VASA cDNAs from three branchiopod species: water fleas Daphnia magna and Moina macrocopa, and brine shrimp Artemia franciscana. RNA helicase domains in branchiopod VASA were highly conserved among arthropod classes. However, N-terminal RNA-binding domains in branchiopod VASA were highly diverged and, unlike other arthropod VASA reported so far, possessed repeats of retroviral-type zinc finger (CCHC) motifs. Raising specific antibodies against Daphnia VASA revealed that the primordial germ cells (PGCs) in this organism segregate at a very early cleavage stage of embryogenesis in parthenogenetic and sexual eggs. Clusters of PGCs then start to migrate inside the embryo and finally settle at both sides of the intestine, the site of future gonad development. RNA analyses suggested that maternally supplied vasa mRNA was responsible for early VASA expression, while zygotic expression started during blastodermal stage of development.     

Expression and intracellular localization of mouse Vasa-homologue protein during germ cell development

To demonstrate the cellular and subcellular localization of mouse vasa homologue protein during germ cell development, specific antibody was raised against the full-length MVH protein. The immunohistochemical analyses demonstrated that MVH protein was exclusively expressed in primordial germ cells just after their colonization of embryonic gonads and in germ cells undergoing gametogenic processes until the post-meiotic stage in both males and females. The co-culture of EG cells with gonadal somatic cells indicated inductive MVH expression caused by an intercellular interaction with gonadal somatic cells. In adult testis, MVH protein was localized in the cytoplasm of spermatogenic cells, including chromatoid bodies in spermatids, known to be a perinuclear nuage structure which includes polar granules that contain VASA protein in Drosophila.     

vasa and nanos expression patterns in a sea anemone and the evolution of bilaterian germ cell specification mechanisms

Most bilaterians specify primordial germ cells (PGCs) during early embryogenesis using either inherited cytoplasmic germ line determinants (preformation) or induction of germ cell fate through signaling pathways (epigenesis). However, data from nonbilaterian animals suggest that ancestral metazoans may have specified germ cells very differently from most extant bilaterians. Cnidarians and sponges have been reported to generate germ cells continuously throughout reproductive life, but previous studies on members of these basal phyla have not examined embryonic germ cell origin. To try to define the embryonic origin of PGCs in the sea anemone Nematostella vectensis, we examined the expression of members of the vasa and nanos gene families, which are critical genes in bilaterian germ cell specification and development. We found that vasa and nanos family genes are expressed not only in presumptive PGCs late in embryonic development, but also in multiple somatic cell types during early embryogenesis. These results suggest one way in which preformation in germ cell development might have evolved from the ancestral epigenetic mechanism that was probably used by a metazoan ancestor.     

Vasa expression and germ-cell specification in the spider mite <Emphasis Type="Italic">Tetranychus urticae</Emphasis>

The specification of germ cells is an important process during the development of all animals. Expression of an evolutionarily conserved gene such as vasa can be used as a marker for germ cell fate. We have isolated a vasa-related gene from the two-spotted spider mite (Tetranychus urticae) and used it to examine the segregation of germ cells in this animal. In spider mites, vasa expression first appears in a group of cells that do not join the initial blastoderm surface. Instead, these cells remain in the interior of the blastoderm and then migrate to posterior regions of the embryo, where they form a cluster that appears in regions of the embryo consistent with the gonads. The expression pattern of this spider mite vasa homologue implies a novel process acts to specify germ cells in this species and that the specification of germ cells is an evolutionarily labile process.