Reorganization of the sex-determining pathway with the evolution of placentation

In mammals, the sex determination system has already been unraveled in considerable detail, and the genes involved are increasingly used to investigate this system in non-mammalian vertebrates. Data available so far indicate that many of the genes identified are involved in this pathway throughout the vertebrate phylum, suggesting that the mechanism of sex determination was essentially conserved in this taxonomic category. However, a rather fundamental difference between mammals and non-mammalian vertebrates is the role of steroid sex hormones which are critical for gonadal differentiation in the latter, while during mammalian evolution an innovation occurred, whereby genes that superseded steroids as factors acting in early gonadogenesis were co-opted to the pathway. An intermediate stage of this evolutionary switch may still be represented by extant marsupials. Referring to the central role of aromatase in steroid-mediated, and of SRY in eutherian gonadal determination/differentiation, it is argued here that the "aromatase system" was replaced by the "SRY system" as a prerequisite for the evolution of placentation. It is proposed that in co-evolution with placentation, new specificities and extensions of the pleiotropic spectrum of sex-determining genes have appeared. The evolutionary innovation of placentation may thus have been materialized by reorganization of the sex-determining system whereby genes were recruited at the top of the pathway and genes at the bottom remained rather conservative but became increasingly pleiotropic.     

文昌鱼核性类固醇激素受体信号研究进展

核性类固醇激素受体属核受体超家族成员,是配体依赖转录因子,在脊椎动物和无脊椎动物生殖内分泌中起关键作用。本文介绍了文昌鱼核性类固醇激素受体的结构、信号转导以及配体与受体结合的作用机制。同时,本综述将可为核性类固醇受体的进化研究提供新的资料。     

浅析斑马鱼性别决定的调控因素

性别决定是经典而高度保守的生物过程。在许多物种中性别决定是以遗传为基础的,个体所携带的性染色体决定了性别。然而,由于鱼类性腺发育呈现高度可变性、复杂性的特点,其性别决定机制仍未有定论。斑马鱼作为一个研究发育和疾病的重要脊椎模式动物,性别决定和分化的高度可塑性使其成为研究生理和环境因素对性腺发育影响及其作用机制的独特模型。本综述总结近年来对斑马鱼性别决定及分化过程的研究,为探索鱼类性别决定机制提供新的见解。     

The lens in focus: a comparison of lens development in Drosophila and vertebrates

The evolution of the eye has been a major subject of study dating back centuries. The advent of molecular genetics offered the surprising finding that morphologically distinct eyes rely on conserved regulatory gene networks for their formation. While many of these advances often stemmed from studies of the compound eye of the fruit fly, Drosophila melanogaster, and later translated to discoveries in vertebrate systems, studies on vertebrate lens development far outnumber those in Drosophila. This may be largely historical, since Spemann and Mangold's paradigm of tissue induction was discovered in the amphibian lens. Recent studies on lens development in Drosophila have begun to define molecular commonalities with the vertebrate lens. Here, we provide an overview of Drosophila lens development, discussing intrinsic and extrinsic factors controlling lens cell specification and differentiation. We then summarize key morphological and molecular events in vertebrate lens development, emphasizing regulatory factors and networks strongly associated with both systems. Finally, we provide a comparative analysis that highlights areas of research that would help further clarify the degree of conservation between the formation of dioptric systems in invertebrates and vertebrates.     

Sex Steroids and the Differentiation of Avian Reproductive Behavior

Experiments in which avian embryos are treated with sex steroidsor steroid antagonists suggest that sexual differentiation ofreproductive behavior (and thus differentiation of the brainmechanisms for such behavior) is controlled by steroids producedby the embryonic gonads. In chickens and Japanese quail, maleshatched from eggs treated with estradiol or testosterone duringincubation are feminized (demasculinized); they fail to exhibitmasculine sexual behavior as adults, and no longer are behaviorallydistinguishable from females. Some evidence suggests that testosteronemay mimic the feminizing action of estradiol by being convertedto an estrogen in the embryonic brain. Genetic female quailexposed to an antiestrogen during embryonic development aremasculinized; they exhibit an increased ability to display themasculine copulatory pattern. Thus the behavior of these speciesis feminized by embryonic exposure to sex steroids, the anhormonal(neutral) sex for behavioral differentiation appears to be themale, and females appear to result from estrogen produced bythe embryonic ovaries. In contrast, sex steroid treatment ofmammals early in development masculinizes behavior, the femaleis the neutral sex, and males result from fetal androgen secretion.These opposite patterns of psychosexual differentiation in birdsand mammals are correlated with a major difference between theavian and mammalian sex-determining mechanism. Implicationsfor other vertebrates are discussed.     

An Immune-Related Gene Evolved into the Master Sex-Determining Gene in Rainbow Trout, Oncorhynchus mykiss

Since the discovery of Sry in mammals [1, 2], few other master sex-determining genes have been identified in vertebrates [3-7]. To date, all of these genes have been characterized as well-known factors in the sex differentiation pathway, suggesting that the same subset of genes have been repeatedly and independently selected throughout evolution as master sex determinants [8, 9]. Here, we characterized in rainbow trout an unknown gene expressed only in the testis, with a predominant expression during testicular differentiation. This gene is a male-specific genomic sequence that is colocalized along with the sex-determining locus. This gene, named sdY for sexually dimorphic on the Y?chromosome, encodes a protein that displays similarity to the C-terminal domain of interferon regulatory factor 9. The targeted inactivation of sdY in males using zinc-finger nuclease induces ovarian differentiation, and the overexpression of sdY in females using additive transgenesis induces testicular differentiation. Together, these results demonstrate that sdY is a novel vertebrate master sex-determining gene not related to any known sex-differentiating gene. These findings highlight an unexpected evolutionary plasticity in vertebrate sex determination through the demonstration that master sex determinants can arise from the de novo evolution of genes that have not been previously implicated in sex differentiation.     

Evolution of vertebrate central nervous system is accompanied by novel expression changes of duplicate genes

The evolution of the central nervous system (CNS) is one of the most striking changes during the transition from invertebrates to vertebrates. As a major source of genetic novelties, gene duplication might play an important role in the functional innovation of vertebrate CNS. In this study, we focused on a group of CNS-biased genes that duplicated during early vertebrate evolution. We investigated the tempo-spatial expression patterns of 33 duplicate gene families and their orthologs during the embryonic development of the vertebrate Xenopus laevis and the cephalochordate Brachiostoma belcheri. Almost all the identified duplicate genes are differentially expressed in the CNS in Xenopus embryos, and more than 50% and 30% duplicate genes are expressed in the telencephalon and mid-hindbrain boundary, respectively, which are mostly considered as two innovations in the vertebrate CNS. Interestingly, more than 50% of the amphioxus orthologs do not show apparent expression in the CNS in amphioxus embryos as detected by in situ hybridization, indicating that some of the vertebrate CNS-biased duplicate genes might arise from non-CNS genes in invertebrates. Our data accentuate the functional contribution of gene duplication in the CNS evolution of vertebrate and uncover an invertebrate non-CNS history for some vertebrate CNS-biased duplicate genes.     

基因倍增和脊椎动物起源

有机体基因复制导致基因复杂性增加及其和脊椎动物起源的关系已经成为进化生物学研究的热点。20世纪70年代由Ohno提出后经Holland等修正的原始脊索动物经两轮基因组复制产生脊椎动物的假设目前已被广泛接受。脊椎动物起源和进化过程中发生过两轮基因组复制的主要证据有三点：（1）据估计脊椎动物基因组内编码基因数目大约相当于果蝇、海鞘等无脊椎动物的4倍;原口动物如果蝇和后口动物如头索动物文昌鱼的基因组大都只有单拷贝的基因,而脊椎动物的基因组则通常有4个同属于一个家族的基因。（2）无脊椎动物如节肢动物、海胆和头索动物文昌鱼都只有一个Hox基因簇,而脊椎动物除鱼类外,有7个具有Hox基因簇,其余都具有4个Hox基因簇。（3）基因作图证明,不但在鱼类和哺乳动物染色体广大片段上基因顺序相似,而且有证据显示哺乳动物基因组不同染色体之间存在相似性。据认为第一次基因倍增发生在脊椎动物与头索动物分开之后,第二次基因倍增发生在有颌类脊椎动物和无颌类脊椎动物分开以后。但是,基因是逐个发生倍增,还是通过基因组内某些DNA片段抑或整个基因组的加倍而实现的,目前还颇有争议。     

Three rounds (1R/2R/3R) of genome duplications and the evolution of the glycolytic pathway in vertebrates

Background  

Evolution of the deuterostome lineage was accompanied by an increase in systematic complexity especially with regard to highly specialized tissues and organs. Based on the observation of an increased number of paralogous genes in vertebrates compared with invertebrates, two entire genome duplications (2R) were proposed during the early evolution of vertebrates. Most glycolytic enzymes occur as several copies in vertebrate genomes, which are specifically expressed in certain tissues. Therefore, the glycolytic pathway is particularly suitable for testing theories of the involvement of gene/genome duplications in enzyme evolution.     

Estradiol-stimulated nitric oxide release in nervous tissue, vasculature, and gonads of the giant cockroach Blaberus craniifer

The vertebrate system of steroid hormones appears to have been conserved widely throughout the animal kingdom. The sex hormone estrogen, 17-beta-estradiol (E2), long considered to be exclusively a vertebrate hormone, is found also in invertebrates related to reproductive and developmental processes such as spawning, vitellogenesis and molting. These processes are affected by estrogen induced changes at the genomic level and take place at a large time scale. The discovery of surface membrane receptors for E2 has opened new possibilities for the involvement of estrogen in biological functions other than reproductive. These processes take place within a few seconds to minutes and involve sudden cytosolic calcium transients, activation of adenylate cyclase or activation of phospholipase C (PLC). E2 can modulate the production of nitric oxide (NO) in endotheliar and other cells. A similar mechanism linking estrogen to cNOS catalized nitric oxide (NO) release is reported herein for the first time in several tissues of the giant cockroach Blaberus craniifer. This process has been identified in the brain, nerve cord, vasculature and ovaries. This effect is concentration dependent and is inhibited by tamoxifen an estrogen receptor blocker.     

RNA silencing: a remarkable parallel to protein-based immune systems in vertebrates?

Sequence-specific gene silencing by double-strand RNA has been observed in many eukaryotes. Accumulating data suggest that it is the major antiviral defense mechanism in plants and invertebrates. The discovery that this cellular mechanism is also highly conserved though somewhat impaired in mammals has stimulated debate about the evolution of antiviral systems. Here we suggest that the existence of the interferon response as an evolutionary intermediate could account for both the relative decline of RNA silencing and the development of protein-based immune systems in vertebrates. In addition, we emphasize the opportunities presented by RNA silencing and the deeper understanding of vertebrate antiviral systems that is needed.     

Sexual differentiation of the zebra finch song system: Positive evidence,negative evidence,null hypotheses,and a paradigm shift

Permanent sex differences in the brain are found in many vertebrates, and are thought to be induced by sex differences in secretion of gonadal steroid hormones during critical periods of early development. This theory has received support primarily from many experiments conducted on mammals, but also from studies on other vertebrate classes, including birds. The only avian neural dimorphism that has allowed extensive tests of this hypothesis is the neural circuit for song in passerine birds, which is much larger in males than in females. Experiments in zebra finches have yielded contradictory results. Although it is relatively easy to induce masculine patterns of development in genetic females with estrogen, it has not been possible to induce feminine patterns of development in males with any treatments, including antiestrogens and inhibitors of estrogen synthesis. Moreover, genetic females that develop with large amounts of functional testicular tissue but with virtually no ovarian tissue nevertheless have a feminine song circuit. The latter studies fail to support the idea of steroid induction of sexual differentiation. An alternative to the steroidal control hypothesis is that nonhormonal gene products expressed in the brain early in development trigger sexually dimorphic patterns of development. Although current evidence in several neural and nonneural systems indicates that sexual differentiation of some somatic phenotypes cannot be explained by the actions of gonadal steroids, the idea of direct genetic (nonhormonal) induction of sexual differentiation has yet to be proved. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 572–584, 1997     

Sex inversion as a model for the study of sex determination in vertebrates

As a consequence of genetic sex determination, the indifferent gonadal blastema normally becomes either a testis or an ovary. This applies to mammals and to the majority of non-mammalian vertebrates. With the exception of placental mammals, however, partial or complete sex inversion can be induced in one sex by sexual steroid hormones of the opposite sex during a sensitive period of gonadogenesis. There is evidence that also during normal gonadogenesis in these species, in the XY/XX mechanism of sex determination testicular differentiation is induced by androgens, and in the ZZ/ZW mechanism, ovarian differentiation by oestrogens. In either case, the hormones may act via serological H-Y antigen as a morphogenetic factor. In contrast, in placental mammals including man, primary gonadal differentiation is independent of sexual steroid hormones, and factors directing differential gonadal development have not yet been conclusively identified. However, various mutations at the chromosome or gene level, resulting respectively in sex inversion or intersexuality, have provided clues as to some genes involved and their possible nature. In this context also, serological H-Y antigen is discussed as a possible factor acting on primordial gonadal cells and inducing differential growth or morphogenesis or both. The data available at present allow a tentative outline of the genetics of sex determination in placental mammals.     

Aryl hydrocarbon receptors: diversity and evolution

Animals have evolved inducible enzymatic defenses to facilitate the biotransformation and elimination of toxic compounds encountered in the environment. The sensory component of this system consists of soluble receptors that regulate the expression of certain isoforms of cytochrome P450, other enzymes, and transporters in response to environmental chemicals. These receptors include several members of the steroid/nuclear receptor superfamily as well as the aryl hydrocarbon receptor (AHR), a member of the bHLH-PAS gene superfamily. In addition to its adaptive functions, the AHR serves poorly understood physiological roles; interference with those roles by dioxins and related chemicals causes toxicity. One approach to understanding the physiological significance of the AHR is to characterize its structure, function, and regulation in diverse species, including mammals, birds, fish, and invertebrates. These animal groups include model species with unique features that can be exploited to broaden our understanding of AHR function. Studies carried out in diverse species also provide phylogenetic information that allows inferences about the evolutionary history of the AHR. This review summarizes the current understanding of AHR diversity among animal species and the evolution of the AHR signaling pathway, as inferred from molecular studies in vertebrate and invertebrate animals. The AHR gene has undergone duplication and diversification in vertebrate animals, resulting in at least three members of an AHR gene family: AHR1, AHR2, and AHR repressor. The inability of invertebrate AHR homologs to bind dioxins and related chemicals, along with other evidence, suggests that the adaptive role of the AHR as a regulator of xenobiotic metabolizing enzymes may have been a vertebrate innovation. The physiological functions of the AHR during development appear to be ancestral to the adaptive functions. Sensitivity to the developmental toxicity of dioxins and related chemicals may have had its origin in the evolution of dioxin-binding capacity of the AHR in the vertebrate lineage.