调控鱼类性腺分化基因的研究进展

鱼类种类繁多, 其性别决定机制也几乎涵盖了所有的动物类型。近几年来, 随着分子生物学技术的不断更新, 关于鱼类性别决定机制的研究, 尤其是对调控性腺分化基因的克隆、表达及功能验证取得了突破性进展。文章从性腺分化、核受体家族、类固醇合成酶类和卵母细胞结构基因4个方面综述了调控鱼类性腺分化基因的研究进展。       

两栖动物的性别决定和分化

性别发育是进化生物学领域备受关注的研究热点之一。性别发育主要包括性别决定和性别分化,脊椎动物的性别决定主要分为基因性别决定和环境性别决定两种模式。两栖动物的性别决定属于基因型性别决定模式,其基因型性别由受精时两性配子的性染色体决定,但性腺分化所产生的表型性别还会受环境温度和性激素的修饰。在两栖动物中性别逆转的现象普遍存在,其相关的生理和分子机制也有一定的研究。本文从性别相关基因对性别决定的影响、温度对两栖动物性别分化的影响、性激素对两栖动物性别分化的影响、温度和性激素对性别相关基因表达的影响等四方面对两栖动物性别决定和性别分化的生理和分子机制进行一定的概述,并提出了未来两栖动物性别发育研究的重点。     

斑马鱼性腺发育的组织学观察

在过去几十年,斑马鱼(Danio rerio)由于其发育周期短且速度快,胚胎发育透明,已经成为众多研究领域的典型模式生物.斑马鱼的性腺发育和分化非常特殊,雄性和雌性幼鱼的性腺在早期全部发育成"类卵巢"结构.目前,对于斑马鱼的性别分化和性腺分化机制还不清楚.本文以孵化后不同时期的斑马鱼仔鱼和幼鱼的生殖腺为材料,经石蜡切片和苏木精染色后,荧光显微镜下观察了斑马鱼仔鱼性腺从出现、分化到成熟的发育过程.结果发现:孵化后5～10日龄仔鱼腹腔两侧可以观察到没有分化的生殖腺,其中的生殖细胞明显比周围的体细胞大;孵化后14～24日龄仔鱼的生殖腺中可见由卵原细胞分裂形成的生殖包囊,其中的生殖细胞进一步分化、分裂形成体积更大、数量更多的卵母细胞;25日龄左右的仔鱼,其性腺成为在腹腔两侧对称,而且在组织结构上也较为典型的卵巢样结构.到35日龄前后可见一部分仔鱼的性腺逐步由卵巢样结构向精巢结构转变的过程.我们在2周左右的仔鱼的性腺中观察到了生殖包囊存在,这一现象还未见有前人报道.在本试验中,我们不仅清楚地观察到类似卵巢的性腺中"卵母细胞"逐渐凋亡消失的过程,还观察到性腺由最初的类似卵巢样结构逐渐变成典型的精巢结构的整个过程.这些研究成果将为发育生物学提供有价值的信息和第一手资料.     

Rspo1对雌性脊椎动物性别分化的功能

长期以来雌性脊椎动物的性别分化被认为是一个“默认”的程序.但是近些年研究发现,Rspo1基因的突变或缺失可导致哺乳动物XX型个体性反转为雄性.Rspo1在鱼类、两栖爬行类、鸟类和哺乳类动物性腺发育的不同阶段表达,其表达在雌雄个体性别分化时期有差异,是潜在的性别调控基因.Rspo1在性别发育早期可通过Wnt/β-catenin信号通路调控性腺分化相关因子的表达,影响原始生殖细胞分裂增殖、细胞周期和生长发育,参与调控性腺中体细胞的分化.本文总结了近年来Rspo1在脊椎动物中的表达调控及其在雌性性别决定方面功能的研究进展.     

Rspo1在雌性脊椎动物性别分化中的功能

长期以来雌性脊椎动物的性别分化被认为是一个"默认"的程序.但是近些年研究发现,Rspo1基因的突变或缺失可导致哺乳动物XX型个体性反转为雄性.Rspo1在鱼类、两栖爬行类、鸟类和哺乳类动物性腺发育的不同阶段表达,其表达在雌雄个体性别分化时期有差异,是潜在的性别调控基因.Rspo1在性别发育早期可通过Wnt/β-catenin信号通路调控性腺分化相关因子的表达,影响原始生殖细胞分裂增殖、细胞周期和生长发育,参与调控性腺中体细胞的分化.本文总结了近年来Rspo1在脊椎动物中的表达调控及其在雌性性别决定方面功能的研究进展.     

青鳉(Oryzias latipes)smad3的克隆与表达分析

鱼类性染色体的原始性导致性别决定基因的多样性.高等动物中的单个基因,在鱼类中因为基因组复制而产生多个同源基因,呈遗传多样性.TGF-β家族在硬骨鱼性别决定和性别分化的过程中发挥关键作用.smad3是性腺体细胞衍生因子(gsdf)的下游基因,可将TGF-β信号从细胞表面传递至细胞核.本研究从青鳉精巢和卵巢组织cDNA中克隆了smad3a、smad3b基因的CDS全长序列.蛋白序列的同源性比对和系统发生分析显示,smad3在高等脊椎动物中只有一种,而在鱼类却有两种.RT和定量PCR分析结果显示,smad3在多组织中普遍表达,在精巢中表达高于卵巢.青鳉smad3a和smad3b的表达同性腺分化紧密关联,提示其在性腺雌雄性分化和发育中可能具有重要作用.     

红斑马鱼体色观察及敲除mitfa基因对其体色发育的影响

斑马鱼(Danio rerio)是一种常见的模式生物,红斑马鱼为小型观赏性鱼类之一.鱼类体色主要是由皮肤或鳞片上的色素细胞的种类和分布决定的.黑色素细胞诱导转录因子(MITF)主要调控动物黑色素细胞发育和分化.本文观察了红斑马鱼成鱼的背鳍、臀鳍、腹鳍、胸鳍色素细胞的组成和分布,跟踪观察了红斑马鱼早期体色发育过程.通过C...     

Sry基因与动物性别决定

性别决定(sex determining)是生命科学的重要课题之一。性别决定包括初级性别决定(即性染色体决定性腺发育)和次级性别决定(随性腺分化,由其产生的激素诱导体细胞分化)。     

早期胚胎的发育选择:性别决定

性别决定是一个复杂的发育调控过程, 早期胚胎发育过程中, 雌雄二者必居其一的发育选择是胚胎性腺形成必须的发育决定。文章综述了动物性别决定的遗传系统、性腺发生、性别决定关键基因及其作用机制, 从分子进化的角度分析了性染色体与性别决定形成机制, 提示性别决定基因在进化中总是趋向异配性染色体。     

Molecular players involved in temperature-dependent sex determination and sex differentiation in Teleost fish

The molecular mechanisms that underlie sex determination and differentiation are conserved and diversified. In fish species, temperature-dependent sex determination and differentiation seem to be ubiquitous and molecular players involved in these mechanisms may be conserved. Although how the ambient temperature transduces signals to the undifferentiated gonads remains to be elucidated, the genes downstream in the sex differentiation pathway are shared between sex-determining mechanisms. In this paper, we review recent advances on the molecular players that participate in the sex determination and differentiation in fish species, by putting emphasis on temperature-dependent sex determination and differentiation, which include temperature-dependent sex determination and genetic sex determination plus temperature effects. Application of temperature-dependent sex differentiation in farmed fish and the consequences of temperature-induced sex reversal are discussed.     

In search of determinants: gene expression during gonadal sex differentiation

The diversity of inputs that guide sexual fate during development is both intriguing and daunting. In the field of fish biology, the study of sex determination is of great importance. For example, in aquaculture, sexually dimorphic growth rates and overall size leads to one sex being more marketable than the other. Moreover, for breeding purposes it is important to maintain balanced sex ratios. Furthermore, sex determination is sensitive to environmental factors, such as temperature and contaminants, which can lead to skewed sex ratios, intersexes and sterility in wild or farmed fish. The gonad is typically the first organ to exhibit morphological signs of sexual dimorphism and therefore is likely to be the primary organ system whose fate is controlled by the sex determination cues in many fish species. Additionally, the sexual fate of the gonad has been shown to fully or partially control organismal sex differentiation. Thus, understanding the genetic regulation of gonadal sex differentiation is critical in studies of fish sex determination. This review summarizes recent knowledge of genes expressed during gonadal sex differentiation in gonochoristic teleost fish. Three species are discussed, which serve as excellent model systems for probing teleost sex differentiation: the Oreochromis niloticus, Oryzias latipes and Danio rerio. The similarities and differences between gonadal gene expression in these three species and in comparison to mammals suggest conserved roles during vertebrate gonadal sex differentiation. In the future, it will be essential to develop tools to assay the function of genes expressed during gonadal sex differentiation in fish.     

Ovotestes suggest cryptic genetic influence in a reptile model for temperature-dependent sex determination

Sex determination and differentiation in reptiles is complex. Temperature-dependent sex determination (TSD), genetic sex determination (GSD) and the interaction of both environmental and genetic cues (sex reversal) can drive the development of sexual phenotypes. The jacky dragon (Amphibolurus muricatus) is an attractive model species for the study of gene–environment interactions because it displays a form of Type II TSD, where female-biased sex ratios are observed at extreme incubation temperatures and approximately 50 : 50 sex ratios occur at intermediate temperatures. This response to temperature has been proposed to occur due to underlying sex determining loci, the influence of which is overridden at extreme temperatures. Thus, sex reversal at extreme temperatures is predicted to produce the female-biased sex ratios observed in A. muricatus. The occurrence of ovotestes during development is a cellular marker of temperature sex reversal in a closely related species Pogona vitticeps. Here, we present the first developmental data for A. muricatus, and show that ovotestes occur at frequencies consistent with a mode of sex determination that is intermediate between GSD and TSD. This is the first evidence suggestive of underlying unidentified sex determining loci in a species that has long been used as a model for TSD.     

Drosophila sex combs as a model of evolutionary innovations

The diversity of animal and plant forms is shaped by nested evolutionary innovations. Understanding the genetic and molecular changes responsible for these innovations is therefore one of the key goals of evolutionary biology. From the genetic point of view, the origin of novel traits implies the origin of new regulatory pathways to control their development. To understand how these new pathways are assembled in the course of evolution, we need model systems that combine relatively recent innovations with a powerful set of genetic and molecular tools. One such model is provided by the Drosophila sex comb—a male‐specific morphological structure that evolved in a relatively small lineage related to the model species D. melanogaster. Our extensive knowledge of sex comb development in D. melanogaster provides the basis for investigating the genetic changes responsible for sex comb origin and diversification. At the same time, sex combs can change on microevolutionary timescales and differ spectacularly among closely related species, providing opportunities for direct genetic analysis and for integrating developmental and population‐genetic approaches. Sex comb evolution is associated with the origin of novel interactions between Hox and sex determination genes. Activity of the sex determination pathway was brought under the control of the Hox code to become segment‐specific, while Hox gene expression became sexually dimorphic. At the same time, both Hox and sex determination genes were integrated into the intrasegmental spatial patterning network, and acquired new joint downstream targets. Phylogenetic analysis shows that similar sex comb morphologies evolved independently in different lineages. Convergent evolution at the phenotypic level reflects convergent changes in the expression of Hox and sex determination genes, involving both independent gains and losses of regulatory interactions. However, the downstream cell‐differentiation programs have diverged between species, and in some lineages, similar adult morphologies are produced by different morphogenetic mechanisms. These features make the sex comb an excellent model for examining not only the genetic changes responsible for its evolution, but also the cellular processes that translate DNA sequence changes into morphological diversity. The origin and diversification of sex combs provides insights into the roles of modularity, cooption, and regulatory changes in evolutionary innovations, and can serve as a model for understanding the origin of the more drastic novelties that define higher order taxa.     

Sex determination: the amphibian models

We review and discuss current knowledge about sex determination in amphibians. The astonishing wide variety of mechanisms of genotypic sex determination is presented and discussed in an evolutionary context. We recall the natural occurrence of transitory juvenile hermaphroditism in some species. Our present knowledge of the mechanisms of sex determination in amphibians is compared to that in mammals. The influence of epigenetic factors, and especially temperature is highlighted. In amphibians, the influence of temperature on sexual differentiation, that can prevail over genotypic sex determination, remains poorly considered in publications. We suggest that studies on genetic and epigenetic factors of gonadal sex differentiation in amphibians could provide substantial information on the evolutionary process of sex determination mechanisms in current living vertebrates.     

Developmental expression of DAX1 in the European sea bass, Dicentrarchus labrax: lack of evidence for sexual dimorphism during sex differentiation

Background  

DAX1 (NR0B1), a member of the nuclear receptors super family, has been shown to be involved in the genetic sex determination and in gonadal differentiation in several vertebrate species. In the aquaculture fish European sea bass, Dicentrarchus labrax, and in the generality of fish species, the mechanisms of sex determination and differentiation have not been elucidated. The present study aimed at characterizing the European DAX1 gene and its developmental expression at the mRNA level.     

Problems of sex determination in birds exemplified by <Emphasis Type="Italic">Gallus gallus domesticus</Emphasis>

The current views of sex determination in birds are considered mostly with the example of Gallus gallus domesticus, the species best studied in this respect. Data on the appearance of primordial germ cells, their migration to the primordial gonads, the role of hormonal factors in the regulation of sex differentiation, the sex chromosomes, putative genetic mechanisms of sex determination, and a possible contribution of dosage compensation are described. The review discusses the two best-grounded hypotheses on the roles of the Z and W chromosomes in sex determination.     

性别决定相关因子的研究进展

有性生殖是多细胞生物的一个重要特征,最常见的就是人类的性染色体X和Y。性别决定(Sex determination)系统有着悠久的起源,在高等生物进化的历程中,不同物种采用的性别决定方式大相径庭,而同源转录因子在不同生物体内的功能和调控方式也是有区别的,比如DMRT转录因子家族,这说明性别决定机制具有高度多样性。本文介绍了近年来发现的具有代表性的性别决定相关的基因的发现过程,总结了性别决定相关转录调控因子的功能和结构方面的研究成果,从结构生物学视角来展望未来的研究方向,为进一步探索生物体内这一重大进程提供新思路。     

Increase of cortisol levels after temperature stress activates dmrt1a causing female‐to‐male sex reversal and reduced germ cell number in medaka

In vertebrates, there is accumulating evidence that environmental factors as triggers for sex determination and genetic sex determination are not two opposing alternatives but that a continuum of mechanisms bridge those extremes. One prominent example is the model fish species Oryzias latipes which has a stable XX/XY genetic sex determination system, but still responds to environmental cues, where high temperatures lead to female‐to‐male sex reversal. However, the mechanisms behind are still unknown. We show that high temperatures increase primordial germ cells (PGC) numbers before they reach the genital ridge, which, in turn, regulates the germ cell proliferation. Complete ablation of PGCs led to XX males with germ cell less testis, whereas experimentally increased PGC numbers did not reverse XY genotypes to female. For the underlying molecular mechanism, we provide support for the explanation that activation of the dmrt1a gene by cortisol during early development of XX embryos enables this autosomal gene to take over the role of the male determining Y‐chromosomal dmrt1bY.