Genetically Triggered Sexual Differentiation of Brain and Behavior

The dominant theory of sexual differentiation of the brain holds that sex differences in brain anatomy and function arise because of the action of gonadal steroids during embryonic and neonatal life. In mammals, testicular steroids trigger masculine patterns of neural development, and feminine patterns of neural development occur in the absence of such testicular secretions. In contrast, gonadal differentiation in mammals is not initiated by hormonal mechanisms, but is regulated by the action of gene products such as SRY, a testis-determining gene on the Y chromosome. This paper argues that such genetic, nonhormonal signals may also trigger specific examples of sexual differentiation of the brain. This thesis is supported by two arguments. The first is that “direct genetic” (i.e., nonhormonal) control of sexual differentiation may be as likely to evolve as hormonal control. The second line of argument is that neural and nonneural dimorphisms have already been described that are not well explained by classical theories of steroid-dependent sexual differentiation and for which other factors need to be invoked.     

Sex determination: a hypothesis based on steroid ratios

This paper presents a hypothesis for sex determination based on the ratio of androgen to estrogen in the gonad during sexual differentiation. In vertebrates the ratio of these steroids, and therefore, the sex of an individual is controlled by the quantity of the enzyme aromatase. For animals with a ZZ, ZW sex determining mechanism, such as birds, in which the heterogametic sex is female, an inducer for the aromatase gene is postulated to be on the W chromosome. In animals with an XX, XY system in which the heterogametic sex is male, such as mammals, the Y chromosome is postulated to code for a repressor of the aromatase gene. This hypothesis can account for naturally occurring sex reversal such as seen in some fish and amphibians, experimentally induced sex reversal by administration of steroids in birds, reptiles, fish and amphibians, and temperature-dependent sex determination as in reptiles. For invertebrates the same hypothetical model applies though the specific androgenic and estrogenic steroids differ. Both the X-to-autosome ratio method of sex determination typified by fruit flies and the haplodiploid method of bees as well as hormonal control of sexual differentiation in crustaceans are accounted for by this hypothesis.     

黄瓜性型分化的分子机制

黄瓜(Cucumis sativus)是雌雄异花植物性型分化研究的重要模式植物,近年来虽然其性型分化的分子机制研究取得了一定的成果,但其性型分化的调控机制尚未完全阐明。该文综合花器官发育基因、性别决定基因、内源激素、环境因子、性型分化假说,在分子水平构建了黄瓜性型分化的表达调控网络。同时对激素和性别决定基因协控的黄瓜单性花器官凋亡机制进行了阐述,并就miRNA在黄瓜性型分化调控中的作用进行了探讨。     

Essential functions of androgen signaling emerged through the developmental analysis of vertebrate sex characteristics

Androgen-androgen receptor (AR) signaling plays key roles in the development of sex characteristics for vertebrates. The essential role of androgen-AR signaling can be analyzed by interdisciplinary approaches including molecular and evolutionary analyses. Recent evolutionally analyses of AR gene revealed that the most ancient AR appeared in cartilaginous fish, the common ancestor of all the extant, jawed vertebrates. Sexual differentiation is a remarkably complex process, which depends on the orchestration of the signaling network. Recent molecular analyses of reproductive organ development indicate the presence of putative effectors for growth factor signaling that can potentially interact with hormonal signaling. The Wnt/β-catenin pathway is an indispensable masculinizing factor for the external genitalia development of mice. Sonic hedgehog pathway, with expression induced by androgen is involved in the copulatory organ outgrowth in teleosts. This review focuses on the interaction of androgen and growth factor pathways that promote the sexual differentiation of reproductive organs in vertebrates.     

Sexual differentiation and the Kiss1 system: hormonal and developmental considerations

The nervous system (both central and peripheral) is anatomically and physiologically differentiated between the sexes, ranging from gender-based differences in the cerebral cortex to motoneuron number in the spinal cord. Although genetic factors may play a role in the development of some sexually differentiated traits, most identified sex differences in the brain and behavior are produced under the influence of perinatal sex steroid signaling. In many species, the ability to display an estrogen-induced luteinizing hormone (LH) surge is sexually differentiated, yet the specific neural population(s) that allows females but not males to display such estrogen-mediated "positive feedback" has remained elusive. Recently, the Kiss1/kisspeptin system has been implicated in generating the sexually dimorphic circuitry underlying the LH surge. Specifically, Kiss1 gene expression and kisspeptin protein levels in the anteroventral periventricular (AVPV) nucleus of the hypothalamus are sexually differentiated, with females displaying higher levels than males, even under identical hormonal conditions as adults. These findings, in conjunction with accumulating evidence implicating kisspeptins as potent secretagogues of gonadotropin-releasing hormone (GnRH), suggest that the sex-specific display of the LH surge (positive feedback) reflects sexual differentiation of AVPV Kiss1 neurons. In addition, developmental kisspeptin signaling via its receptor GPR54 appears to be critical in males for the proper sexual differentiation of a variety of sexually dimorphic traits, ranging from complex social behavior to specific forebrain and spinal cord neuronal populations. This review discusses the recent data, and their implications, regarding the bi-directional relationship between the Kiss1 system and the process of sexual differentiation.     

Temperature-dependent expression of turtle Dmrt1 prior to sexual differentiation

Vertebrates employ varied strategies, both chromosomal and nonchromosomal, to determine the sex of the developing embryo. Among reptiles, temperature-dependent sex determination (TSD) is common. The temperature of incubation during a critical period preceding sexual differentiation determines the future sex of the embryo, presumably by altering the activity or expression of a temperature-dependent regulatory factor(s). Here we examine the expression of the Dmrt1 gene, a candidate regulator of mammalian and avian sexual development, in the turtle. During the sex-determining period, Dmrt1 mRNA is more abundant in genital ridge/mesonephros complexes at male-promoting than at female-promoting temperatures. Dmrt1 is the first gene found to show temperature-dependent expression prior to sexual differentiation, and may play a key role in sexual development in reptiles. genesis 26:174-178, 2000.     

芦笋性别决定与性别分化研究进展

从芦笋性别表现及其决定的遗传基础、性别分化途径,性别决定基因的定位以及性别分化特异表达基因的分离与分析等方面来综述芦笋性别决定与性别分化最新研究进展。目前,已构建了围绕芦笋性别决定基因M比较精细的遗传图谱,将M定位在L5染色体着丝点附近的0.63 cM区域内,并构建了含有8个跨叠克隆群的物理图谱,但由于大量重复序列的存在,跨叠克隆之间的空隙不能闭合;同时先后分离得到11个芦笋花器官发育特异表达基因,并通过序列分析和原位杂交等技术对这些基因的功能进行了分析。最后,对今后进一步研究提出了建议。     

Germ cells, gonads and sex reversal in marsupials.

The formation of the testis or ovary is a critical step in development. Alterations in gonadal development during fetal or postnatal life can lead to intersexuality or infertility. Several model systems have been particularly useful in studying gonadal differentiation, the eutherian mammal and amphibia, fish, and birds. However, marsupials provide a unique opportunity to investigate gonadal development and the interactions of genes and hormones in gonadal differentiation and germ cell development in all mammals. On the one hand the genetic mechanisms appear to be identical to those in eutherian mammals, including the testis-determining SRY gene. On the other hand, marsupials retain in part the plasticity of the amphibian gonad to hormonal manipulation. It is possible to induce female to male and also male to female gonadal sex reversal in marsupials by hormonal manipulation, and oestradiol can induce male germ cells to enter meiosis at the time the oogonia do. In addition, in marsupials the development of the scrotum and mammary glands are independent of testicular androgens and instead are controlled by a gene or genes on the X-chromosome. Thus marsupials provide a number of opportunities for manipulating the sexual differentiation of the gonads that are not possible in eutherian mammals and so provide a unique perspective for understanding the common mechanisms controlling sexual development.     

The Candidate Sex-ReversingDAX1Gene Is Autosomal in Marsupials: Implications for the Evolution of Sex Determination in Mammals

The human X-linkedDAX1gene was cloned from the region of the short arm of the human X found in duplicate in sex-reversed X_dupY females (E. Zanariaet al.,1994,Nature372: 635–641).DAX1is suggested to be required for ovarian differentiation and to play an important role in mammalian sex determination or differentiation pathways. Its proposed dose-dependent effect on sexual development suggests thatDAX1could represent an evolutionary link with an ancestral sex-determining mechanism that depended on the dosage of an X-linked gene. Furthermore,DAX1could also represent the putative X-linked switch gene, which independently controls sexual dimorphisms in marsupial mammals in an X-dose-dependent manner (D. W. Cooperet al.,1993,Semin. Dev.4: 117–128). IfDAX1has a present role in marsupial sexual differentiation or had an ancestral role in mammalian sex determination, it would be expected to lie on the marsupial X chromosome, despite the autosomal localization of other human Xp genes. We therefore cloned and mapped theDAX1gene in the tammar wallaby (Macropus eugenii).DAX1was located on wallaby chromosome 5p near other human Xp genes, indicating that it was originally autosomal and that it is not involved in X-linked dose-dependent sex determination in an ancestral mammal nor in marsupial sexual differentiation.     

Sexual behaviour: Courting dissatisfaction

A nuclear receptor, the product of the dissatisfaction gene, has been found to regulate Drosophila sexual behaviour, probably via its action in a small subset of neurons. The results shed new light on the genetic determination of sexual behaviour.     

Role of the androgen receptor in male sexual differentiation.

The two androgens responsible for all aspects of male sexual differentiation are testosterone and dihydrotestosterone. The action of both these steroids is mediated by a specific intracellular receptor, the androgen receptor, which is a member of the nuclear receptor superfamily. The androgen receptor gene has been cloned and is located on the X chromosome at Xq11-12. Mutations of this gene have been found in subjects with both complete and partial androgen insensitivity. In a study of 27 subjects with the androgen insensitivity syndrome, we have identified mutations in 14, using a rapid mutation screening assay. The same technique has also been used to determine carrier status in an affected family. We have also identified a mutation in two brothers who show perineal hypospadias as the only evidence of undervirilisation. Familial severe hypospadias should therefore be included as part of the phenotypic spectrum of partial androgen insensitivity. The study of naturally occurring mutations of the androgen receptor gene is providing further information on the function of the androgen receptor and its role in normal male sexual differentiation.     

Sex determination and sexual differentiation in the avian model

The sex of birds is determined by the inheritance of sex chromosomes (ZZ male and ZW female). Genes carried on one or both of these sex chromosomes control sexual differentiation during embryonic life, producing testes in males (ZZ) and ovaries in females (ZW). This minireview summarizes our current understanding of avian sex determination and gonadal development. Most recently, it has been shown that sex is cell autonomous in birds. Evidence from gynandromorphic chickens (male on one side, female on the other) points to the likelihood that sex is determined directly in each cell of the body, independently of, or in addition to, hormonal signalling. Hence, sex-determining genes may operate not only in the gonads, to produce testes or ovaries, but also throughout cells of the body. In the chicken, as in other birds, the gonads develop into ovaries or testes during embryonic life, a process that must be triggered by sex-determining genes. This process involves the Z-linked DMRT1 gene. If DMRT1 gene activity is experimentally reduced, the gonads of male embryos (ZZ) are feminized, with ovarian-type structure, downregulation of male markers and activation of female markers. DMRT1 is currently the best candidate gene thought to regulate gonadal sex differentiation. However, if sex is cell autonomous, DMRT1 cannot be the master regulator, as its expression is confined to the urogenital system. Female development in the avian model appears to be shared with mammals; both the FOXL2 and RSPO1/WNT4 pathways are implicated in ovarian differentiation.     

Sex determination in the dioecious Melandrium. The X/Y chromosome system allows complementary cloning strategies

Melandrium album (Silene alba) is a dioecious species showing a clear-cut correlation between the phenotypic sex and the presence of heteromorphic sex chromosomes. The paper reviews basic aspects on taxonomy and flowering, concentrating on classical and more recent experiments on sex conversion: hormonal balance in planta or in vitro, interactions with the fungus Ustilago violacea, haploid production from anthers, induction of sex chromosomal aberrations via crosses between polyploids and interspecific crosses, isolation of sexual mutants through pollen irradiation, etc. The experimental data is used to discuss the current understanding of sex determination in this species. The phenotypic and genetic characteristics of Melandrium are underlined and enable alternative and complementary cloning strategies for genes involved in sex determination and differentiation.     

Sex-lethal in neurons controls female body growth in Drosophila

Sexual size dimorphism (SSD), a sex difference in body size, is widespread throughout the animal kingdom, raising the question of how sex influences existing growth regulatory pathways to bring about SSD. In insects, somatic sexual differentiation has long been considered to be controlled strictly cell-autonomously. Here, we discuss our surprising finding that in Drosophila larvae, the sex determination gene Sex-lethal (Sxl) functions in neurons to non-autonomously specify SSD. We found that Sxl is required in specific neuronal subsets to upregulate female body growth, including in the neurosecretory insulin producing cells, even though insulin-like peptides themselves appear not to be involved. SSD regulation by neuronal Sxl is also independent of its known splicing targets, transformer and msl-2, suggesting that it involves a new molecular mechanism. Interestingly, SSD control by neuronal Sxl is selective for larval, not imaginal tissue types, and operates in addition to cell-autonomous effects of Sxl and Tra, which are present in both larval and imaginal tissues. Overall, our findings add to a small but growing number of studies reporting non-autonomous, likely hormonal, control of sex differences in Drosophila, and suggest that the principles of sexual differentiation in insects and mammals may be more similar than previously thought.     

Establishing sexual dimorphism in humans

Sexual dimorphism, i.e. the distinct recognition of only two sexes per species, is the phenotypic expression of a multi-stage procedure at chromosomal, gonadal, hormonal and behavioral level. Chromosomal--genetic sexual dimorphism refers to the presence of two identical (XX) or two different (XY) gonosomes in females and males, respectively. This is due to the distinct content of the X and Y-chromosomes in both genes and regulatory sequences, SRY being the key regulator Hormones (AMH, testosterone, Insl3) secreted by the foetal testis (gonadal sexual dimorphism), impede Müller duct development, masculinize Wolff duct derivatives and are involved in testicular descent (hormonal sexual dimorphism). Steroid hormone receptors detected in the nervous system, link androgens with behavioral sexual dimorphism. Furthermore, sex chromosome genes directly affect brain sexual dimorphism and this may precede gonadal differentiation.     

Sex-related differences in developmental rates of bovine embryos produced and cultured in vitro.

The classical concept of sex determination in mammals is that a Y chromosomal gene controls the development of the indifferent gonad into a testis. Subsequent divergence of sexual phenotypes is secondary to this gonadal determination. The most likely candidate gene is SRY (sex-determining region Y) in humans, and Sry in mouse. However, several lines of evidence indicate that sexual dimorphism occurs even before the indifferent gonad appears. Here we present evidence that bovine male embryos generally develop to more advanced stages than do females during the first 8 days after insemination in vitro. Corresponding relationships between both cell numbers and mitotic indices and sex were also seen. Although it is not clear whether this phenomenon involves factors originating before or after fertilization, these findings suggest that sex-related gene expression affects the development of embryos soon after activation of the embryonic genome and well before gonadal differentiation.