Transformer基因与果蝇和线虫的性别决定

黑腹果蝇(Drosophila melanogaster)和秀丽隐杆线虫（Caeborhabditis elegans）的性别决定的问题已研究得比较详细,且transformer基因是这两种生物性别决定中最重要的基因之一,其有关的性别决定研究在近几年取得了很大的进展。本文就线虫和果蝇的transformer基因及其相关基因的特性与功能进行了特别介绍,并在此基础上对其性别决定的分子机制进行初步的比较和分析。Abstract : Sex determination of Drosophila melanogaster and Caeborhabditis elegans has been known in detail. Great progress, is achieved in recent years, is the research of transformer genes, which are those of most important genes in sex determination in both species. In this paper, molecular character, genetic function and the relative genes of transformer genes are particularly described. On the basis,a primary compariso and analysis between the molecular mechanism of sex determination in C.elegans and D. melanogaster are presented.     

性别决定基因的研究进展

SRY基因在哺乳动物性别分化中起着关键作用,目前研究认为SRY仅是性别决 定过程的基因之一,其他基因如SOX基因家族、MIS、SF-1、DAX1、DSS等基因都参与了性腺分化与发育。性别决定研究取得很大进展并建立了一些假说,但仍有一些问题有待于进一步研究。 Abstract:In mammals the male sex determination switch is controlled by a single gene on the Y chromosome SRY.Apart from SRY,other genes,such as SOX gene family、MIS、SF-1、DAX1、DSS also take part in sex determination.Scientists have made great progress in research on sex determination and proposed some hypotheses.,but there are still many questions to be solved.     

利用孕妇血浆DNA检测胎儿性别的研究

本文探讨应用孕妇血浆中游离DNA进行无创性产前性别诊断的可行性。用柱分离法提取73例孕妇血浆中DNA,用巢式PCR技术检测其胎儿SRY基因。 结果73位孕妇血浆DNA含量为0.0062~0.3399μg/μL。巢式PCR检测胎儿SRY基因的灵敏度为97.37%（37/38）,假阴性率2.86%(1/35),特异度85.71%（30/35）,假阳性率13.16%(5/38),总符合率91.78%（67/73）。采用孕妇血浆胎儿DNA和巢式PCR技术可以快速简便的进行无创性产前性别诊断,诊断结果的准确率为91.8%,对性连锁遗传病的预防具有重要意义。 Abstract:To investigate the feasibility and possibility of application of fetal DNA from maternal plasma for noninvasive prenatal diagnosis of fetal sex,plasma DNAs in blood samples of 73 pregnant women at the gestational period of 26 to 41 weeks were extracted by column separation and nested polymerase chain reaction were employed to amplify the SRY gene.A comparison was made between the amplification results and the real sex of the fetus after their delivery.The concordance rate of SRY gene amplification results of plasma free DNA with real fetal sex was 91.78% (67/73),the sensitivity rate was 97.37% (37/38),and the specific rate was 85.71% (30/35).The cell-free fetal DNA in maternal blood can be one of the valuable material sources for noninvasive prenatal diagnosis and the method of nested PCR could be useful for fetal sex determination.The specific rate of the test was 91.78%.It is of significance to prevent sex-linked inheritant diseases.     

鸡Z染色体上DMRT1基因的多重跨染色体剪接

性别决定与分化发育是同时涉及生命现象中两种细胞分裂(有丝分裂和减数分裂)形式的惟一的分化发育过程。对该过程中关键基因DMRT1的转录分析,发现位于鸡Z染色体上的DMRT1基因分别同时与4号染色体上的CENPC1基因、5号染色体上CD5R基因和2号染色体上37LRP/p40基因发生跨染色体剪接,由此构成了新的跨染色体剪接本DMRT1-CENPC1、DMRT1-CD5R和DMRT1-37LRP/p40。对其剪接位点的分析,发现两段染色体序列存在的重叠区可能在这种剪接中起着重要作用。DMRT1基因在转录过程中同时与多个染色体上基因发生多次跨染色体剪接的发现,无疑有助于对在转录水平上的多样性基因调控以及性别决定与分化发育等的认识开辟另一新途径。     

特异性PCR反应鉴别携带W染色体的嵌合体公鸡子代性别的研究

利用聚合酶链式反应(PCR)特异扩增家鸡W染色体高度重复序列EcoRI家族的447bp片段,作为鉴定家鸡W染色体存在的依据.4个表现型为雄性的嵌合体公鸡的精液中检测到了W染色体,通过人工授精获得嵌合体子一代.检测了其中188个雏鸡的血液,51.6%(97/188)含有W染色体,x2检验结果显示,雌雄后代符合1:1的比例,这表明在这188个成活的嵌合体子代中,基本上没有W染色体精子所产生的雏鸡,携带W染色体的精子没有将其W染色体传递到其子代雏鸡中.本研究利用PGR性别鉴定技术,从分子水平上对精液中携带W染色体的嵌合体公鸡(ZW→ZZ型)子代的性别分化作了初步的探讨。 Abstract:The W chromosome was detected in four cocks' sperms by a method based on the polymerase chain reaction which amplifies the EcoRI repeat unit of the chicken W chromosome.188 offsprings of these chimeric cocks were obtained by artificial insemination and 51.6% (97/188) was detected W chromosome in blood.The result of χ2 test suggests that the sex ratio is 1:1.It seems as if no evidence was found for skewed sex ratios of these offsprings.Therefore it seems as if the sperms with W chromosome could not contribute to these 188 offspring chicks.     

脊椎动物性别决定和分化的分子机制研究进展

哺乳类性别决定是多种转录因子和生长因子相继表达和相互调控的结果。SRY的表达启动雄性通路并诱导下游雄性特异基因SOX9、AMH等的表达。FOXL2在雌性未分化性腺表达,WNT-4和DAX1也在雌性性别决定或分化时期表达,表明雌性通路也是受特定基因调控的,而并非“默认通路”。鸟类的性别也是由遗传基因决定的,EFT1(雌性)和DMRT1(雄性)可能是性别决定候选基因。爬行类为温度性别决定的典型,温度可能通过调节雌激素水平和控制性别特异遗传基因表达决定性别。大部分两栖类性别受环境因素影响,但发现DMRT1和DAX1可能与其精巢发育有关。鱼类性别决定和分化方式差异很大,多种因素(遗传基因、环境因素、类固醇激素等)参与了这一过程。从青Q鳉Y染色体定位克隆的DMY,被认为是第一个非哺乳类脊椎动物雄性性别决定基因。所有这些表明脊椎动物性别决定和分化机制是多样化的。     

大鳞副泥鳅ZZ/ZW型性别决定的细胞遗传学证据

大鳞副泥鳅是鲤形目、鳅科的鱼类。其2n数为48,核型组成为12m+4sm+32 t(雄性),11m+5sm+32t(雌性)。根据银染带和C带特征分析,证实大鳞副泥鳅为ZZ/ZW型性别决定。Z染色体为中部着丝粒染色体,在其长臂端部有Ag -NOR存在。 W染色体为亚中部着丝粒染色体,在其长臂末端也有Ag-NOR存在,同时还有一深染的居间C带,这是W染色体独有的带纹特征。 Abstract:Paramisgurnus dabryanus belongs to Cypriniformes,Cobitidae.Its 2n is 48.The karyotype formula is 12m+4sm+32t(in male),11m+5sm+32t(in female).According to the Ag-NORs band and C-band patterns,we consider that its sex determination is of ZZ/ZW type.The Z chromosome is a metacentric one with Ag-NORs located on its arm end.The W chromosome is a submetacentric with Ag-NORs located on the terminal of its long arm.There is a darkly stained C-band on the long arm of W chromosome.This band is a characteric of the W chromosome.     

毛冠鹿ZFY、ZFX基因片段的克隆与性别鉴定

根据人和鼠性别分化相关的ZFY、ZFX基因序列设计引物,以雌雄毛冠鹿的基因组DNA为模板进行PCR扩增,将扩增产物克隆到pMD18T上,获得ZFY、ZFX重组克隆,并测定了ZFY、ZFX基因片段的序列,序列比较显示两者同源性达 91%,仅在少数位点有差异,以此确定AvaⅡ为ZFX上特异酶切位点,通过PCR扩增和AvaⅡ特异酶切对毛冠鹿性别进行鉴定。 Abstract: According to the human sex differentiation related ZFY and ZFX genes, a pair of primers were designed , and fragments were amplified from the genomic DNA of male or female tufted deer. Subsequently the amplified fragments were cloned into the vector pMD18T and were sequenced. It is found that the sequences of ZFY gene and ZFX gene have 91% homology. Based on the different nucleotides, restriction site of AvaⅡ was found to be specific to ZFX gene. The results show that the combination of PCR with AvaⅡ digestion is a simple and sensitive way to identify the tufted deer sex.     

Sex Determination: Two Copies for One Cock

The molecular mechanism of sex determination in birds has long remained mysterious. Genetically male chicken embryos, which have two Z sex chromosomes, develop female gonads when the Z chromosome-linked gene DMRT1 is knocked out. This suggests that sex is determined by Z chromosome dosage.     

Sex Determination by Sex Chromosomes in Dioecious Plants

Abstract: Sex chromosomes have been reported in several dioecious plants. The most general system of sex determination with sex chromosomes is the XY system, in which males are the heterogametic sex and females are homogametic. Genetic systems in sex determination are divided into two classes including an X chromosome counting system and an active Y chromosome system. Dioecious plants have unisexual flowers, which have stamens or pistils. The development of unisexual flowers is caused by the suppression of opposite sex primordia. The expression of floral organ identity genes is different between male and female flower primordia. However, these floral organ identity genes show no evidence of sex chromosome linkage. The Y chromosome of Rumex acetosa contains Y chromosome-specific repetitive sequences, whereas the Y chromosome of Silene latifolia has not accumulated chromosome-specific repetitive sequences. The different degree of Y chromosome degeneration may reflect on evolutionary time since the origination of dioecy. The Y chromosome of S. latifolia functions in suppression of female development and initiation and completion of anther development. Analyses of mutants suggested that female suppressor and stamen promoter genes are localized on the Y chromosome. Recently, some sex chromosome-linked genes were isolated from flower buds of S. latifolia.     

Sex chromosome polymorphism in guppies

Sex chromosomes differ from autosomes by dissimilar gene content and, at a more advanced stage of their evolution, also in structure and size. This is driven by the divergence of the Y or W from their counterparts, X and Z, due to reduced recombination and the resulting degeneration as well as the accumulation of sex-specific and sexually antagonistic genes. A paradigmatic example for Y-chromosome evolution is found in guppies. In these fishes, conflicting data exist for a morphological and molecular differentiation of sex chromosomes. Using molecular probes and the previously established linkage map, we performed a cytogenetic analysis of sex chromosomes. We show that the Y chromosome has a very large pseudoautosomal region, which is followed by a heterochromatin block (HCY) separating the subtelomeric male-specific region from the rest of the chromosome. Interestingly, the size of the HCY is highly variable between individuals from different population. The largest HCY was found in one population of Poecilia wingei, making the Y almost double the size of the X and the largest chromosome of the complement. Comparative analysis revealed that the Y chromosomes of different guppy species are homologous and share the same structure and organization. The observed size differences are explained by an expansion of the HCY, which is due to increased amounts of repetitive DNA. In one population, we observed also a polymorphism of the X chromosome. We suggest that sex chromosome-linked color patterns and other sexually selected genes are important for maintaining the observed structural polymorphism of sex chromosomes.     

Z and W chromosomes of chickens: studies on their gene functions in sex determination and sex differentiation

Since the discovery of SRY/SRY as a testis-determining gene on the mammalian Y chromosome in 1990, extensive studies have been carried out on the immediate target of SRY/SRY and genes functioning in the course of testis development. Comparative studies in non-mammalian vertebrates including birds have failed to find a gene equivalent to SRY/SRY, whereas they have suggested that most of the downstream factors found in mammals including SOX9 are also involved in the process of gonadal differentiation. Although a gene whose function is to trigger the cascade of gene expression toward gonadal differentiation has not been identified yet on either W or Z chromosomes of birds, a few interesting genes have been found recently on the sex chromosomes of chickens and their possible roles in sex determination or sex differentiation are being investigated. It is the purpose of this review to summarize the present knowledge of these sex chromosome-linked genes in chickens and to give perspectives and point out questions concerning the mechanisms of avian sex determination.     

哺乳动物性别决定和性反转

目前已知SRY仅是涉及性别决定过程的基因之一.近年来又发现和克隆了许多可能参与性腺分化与发育的基因,如副中肾抑制基因MIS,也称抗副中肾激素基因AMH;SRY相关基因SOX9;编码甾类因子的基因SFI;X-连锁的DAX基因;Wilm′s肿瘤抑制基因WTI;以及X-连锁的剂量敏感基因DSS等,并新建立了性别决定的Z-基因模型,DSS-基因模型和Jimenez等的模型,较合理地解释了哺乳动物性别决定的分子机理和以前难以解释的各种奇特的性反转现象,使性别决定的研究取得了长足的进展,但仍有一些悬而未决的问题有待于进一步探索.     

The great escape

Epigenetic mechanisms precisely regulate sex chromosome inactivation as well as genes that escape the silencing process. In male germ cells, DNA damage response factor RNF8 establishes active epigenetic modifications on the silent sex chromosomes during meiosis, and activates escape genes during a state of sex chromosome-wide silencing in postmeiotic spermatids. During the course of evolution, the gene content of escape genes in postmeiotic spermatids recently diverged on the sex chromosomes. This evolutionary feature mirrors the epigenetic processes of sex chromosomes in germ cells. In this article, we describe how epigenetic processes have helped to shape the evolution of sex chromosome-linked genes. Furthermore, we compare features of escape genes on sex chromosomes in male germ cells to escape genes located on the single X chromosome silenced during X-inactivation in females, clarifying the distinct evolutionary implications between male and female escape genes.     

Sex determining of cat embryo and some feline species

Sex identification in mammalian preimplantation embryos is a technique that is used currently for development of the embryo transfer industry for zootechnical animals and is, therefore, a resource for biodiversity preservation. The aim of the present study was to establish a rapid and reliable method for the sexing of preimplantation embryos in domestic cats. Here we describe the use of nested PCR identify Y chromosome-linked markers when starting from small amounts of DNA and test the method for the purpose of sexing different species of wild felids. To evaluate the efficiency of the primers, PCR analysis were performed first in blood samples of sex-known domestic cats. Cat embryos were produced both in vitro and in vivo and the blastocysts were biopsied. A Magnetic Resin System was used to capture a consistent amount of DNA from embryo biopsy and wild felid hairs. The results from nested PCR applied on cat blood that corresponded to the phenotypical sex. Nested PCR was also applied to 37 embryo biopsies and the final result was: 21 males and 16 females. Furthermore, beta-actin was amplified in each sample, as a positive control for DNA presence. Subsequently, nested PCR was performed on blood and hair samples from some wild felines and again the genotyping results and phenotype sex corresponded. The data show that this method is a rapid and repeatable option for sex determination in domestic cat embryos and some wild felids and that a small amount of cells is sufficient to obtain a reliable result. This technique, therefore, affords investigators a new approach that they can insert in the safeguard programmes of felida biodiversity.     

Genetic Linkage Map of Fishes of the Genus Xiphophorus (Teleostei: Poeciliidae)

Analysis of genotypes of 76 polymorphic loci in more than 2600 backcross hybrid individuals derived from intra- and interspecific genetic crosses of fishes of the genus Xiphophorus (Poeciliidae) resulted in the identification of 17 multipoint linkage groups containing 55 protein-coding loci and one sex chromosome-linked pigment pattern gene. Multipoint linkage analyses identified highly probable gene orders for 10 linkage groups. The total genome length was estimated to be approximately 18 Morgans. Comparisons of the Xiphophorus linkage map with those of other fishes, amphibians and mammals suggested that fish gene maps are remarkably similar and probably retain many syntenic groups present in the ancestor of all vertebrates.