The expression pattern of a mouse doublesex-related gene is consistent with a role in gonadal differentiation

The signal for somatic sex determination in mammals, Caenorhabditis elegans and Drosophila melanogaster is chromosomal, but the overall mechanisms do not appear to be conserved between the phyla. However it has been found quite recently that the C. elegans sex-determining gene Mab-3 contains a domain highly homologous to the Drosophila sex-determining gene doublesex (dsx) and shares a similar role. These data suggest that at least some aspects of the regulation of sex determination might be conserved. In humans, a doublesex-related gene (DMRT1) was identified at less than 30 kb from the critical region for sex reversal on chromosome 9p24 (TD9). In order to get insights into the role of DMRT1 in sex determination/differentiation, we have isolated DMRT1 mouse homologue (Dmrt1) and analysed its expression pattern. The gene is expressed in the genital ridges of both sexes during the sex-determining switch and it shows male/female dimorphism at late stages of sex differentiation.     

The <Emphasis Type="Italic">transformer2</Emphasis> gene in <Emphasis Type="Italic">Musca domestica</Emphasis> is required for selecting and maintaining the female pathway of development

We present the isolation and functional analysis of a transformer2 homologue Mdtra2 in the housefly Musca domestica. Compromising the activity of this gene by injecting dsRNA into embryos causes complete sex reversal of genotypically female individuals into fertile males, revealing an essential function of Mdtra2 in female development of the housefly. Mdtra2 is required for female-specific splicing of Musca doublesex (Mddsx) which structurally and functionally corresponds to Drosophila dsx, the bottom-most regulator in the sex-determining pathway. Since Mdtra2 is expressed in males and females, we propose that Mdtra2 serves as an essential co-factor of F, the key sex-determining switch upstream of Mddsx. We also provide evidence that Mdtra2 acts upstream as a positive regulator of F supporting genetic data which suggest that F relies on an autocatalytic activity to select and maintain the female path of development. We further show that repression of male courtship behavior by F requires Mdtra2. This function of F and Mdtra2 appears not to be mediated by Mddsx, suggesting that bifurcation of the pathway at this level is a conserved feature in the genetic architecture of Musca and Drosophila.Edited by D. Tautz     

The C. elegans sex determination gene laf-1 encodes a putative DEAD-box RNA helicase

The Caenorhabditis elegans gene laf-1 is critical for both embryonic development and sex determination. Laf-1 is thought to promote male cell fates by negatively regulating expression of tra-2 in both hermaphrodites and males. We cloned laf-1 and established that it encodes a putative DEAD-box RNA helicase related to Saccharomyces cerevisiae Ded1p and Drosophila Vasa. Three sequenced laf-1 mutations are missense alleles affecting a small region of the protein in or near helicase motif III. We demonstrate that the phenotypes resulting from laf-1 mutations are due to loss or reduction of laf-1 function, and that both laf-1 and a related helicase vbh-1 function in germline sex determination. Laf-1 mRNA is expressed in both males and hermaphrodites and in both the germline and soma of hermaphrodites. It is expressed at all developmental stages and is most abundant in embryos. LAF-1 is predominantly, if not exclusively, cytoplasmic and colocalizes with PGL-1 in P granules of germline precursor cells. Previous results suggest that laf-1 functions to negatively regulate expression of the sex determination protein TRA-2, and we find that the abundance of TRA-2 is modestly elevated in laf-1/+ females. We discuss potential functions of LAF-1 as a helicase and its roles in sex determination.     

Sex determination in<Emphasis Type="Italic"> Drosophila melanogaster</Emphasis> and<Emphasis Type="Italic"> Musca domestica</Emphasis> converges at the level of the terminal regulator<Emphasis Type="Italic"> doublesex</Emphasis>

Sex-determining cascades are supposed to have evolved in a retrograde manner from bottom to top. Wilkins 1995 hypothesis finds support from our comparative studies in Drosophila melanogaster and Musca domestica, two dipteran species that separated some 120 million years ago. The sex-determining cascades in these flies differ at the level of the primary sex-determining signal and their targets, Sxl in Drosophila and F in Musca. Here we present evidence that they converge at the level of the terminal regulator, doublesex (dsx), which conveys the selected sexual fate to the differentiation genes. The dsx homologue in Musca, Md-dsx, encodes male-specific (MdDSX^M) and female-specific (MdDSX^F) protein variants which correspond in structure to those in Drosophila. Sex-specific regulation of Md-dsx is controlled by the switch gene F via a splicing mechanism that is similar but in some relevant aspects different from that in Drosophila. MdDSX^F expression can activate the vitellogenin genes in Drosophila and Musca males, and MdDSX^M expression in Drosophila females can cause male-like pigmentation of posterior tergites, suggesting that these Musca dsx variants are conserved not only in structure but also in function. Furthermore, downregulation of Md-dsx activity in Musca by injecting dsRNA into embryos leads to intersexual differentiation of the gonads. These results strongly support a role of Md-dsx as the final regulatory gene in the sex-determining hierarchy of the housefly.Edited by D. Tautz     

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。     

DMRT1 in a ratite bird: evidence for a role in sex determination and discovery of a putative regulatory element

Unlike mammals, birds have a ZZ male/ZW female sex-determining system. In most birds, the Z is large and gene rich, whereas the W is small and heterochromatic, but the ancient group of ratite birds are characterized by sex chromosomes that are virtually homomorphic. Any gene differentially present on the ratite Z and W is therefore a strong candidate for a sex-determining role. We have cloned part of the candidate bird sex-determining gene DMRT1 from the emu, a ratite bird, and have shown that it is expressed during the stages of development corresponding to gonadal differentiation in the chicken. The gene maps to the distal region of the Z short arm and is absent from the large W chromosome. Because most sequences on the emu W chromosome are shared with the Z, the Z-specific location constitutes strong evidence that differential dosage of DMRT1 is involved in sex determination in all birds. The sequence of emu DMRT1 has 88% homology with chicken DMRT1 and 65% with human DMRT1. Unexpectedly, an unexpressed 270-bp region in intron 3 of emu DMRT1 showed 90% homology with a sequence in the corresponding intron of human DMRT1. This extraordinarily high conservation across 300 million years of evolution suggests an important function, perhaps involved in control of DMRT1 expression and vertebrate sex determination.     

Sex-specific repression of dachshund is required for Drosophila sex comb development

The origin of new morphological structures requires the establishment of new genetic regulatory circuits to control their development, from initial specification to terminal differentiation. The upstream regulatory genes are usually the first to be identified, while the mechanisms that translate novel regulatory information into phenotypic diversity often remain obscure. In particular, elaborate sex-specific structures that have evolved in many animal lineages are inevitably controlled by sex-determining genes, but the genetic basis of sexually dimorphic cell differentiation is rarely understood. In this report, we examine the role of dachshund (dac), a gene with a deeply conserved function in sensory organ and appendage development, in the sex comb, a recently evolved male-specific structure found in some Drosophila species. We show that dac acts during metamorphosis to restrict sex comb development to the appropriate leg region. Localized repression of dac by the sex determination pathway is necessary for male-specific morphogenesis of sex comb bristles. This pupal function of dac is separate from its earlier role in leg patterning, and Dac at this stage is not dependent on the pupal expression of Distalless (Dll), the main regulator of dac during the larval period. Dll acts in the epithelial cells surrounding the sex comb during pupal development to promote sex comb rotation, a complex cellular process driven by coordinated cell rearrangement. Our results show that genes with well-conserved developmental functions can be re-used at later stages in development to regulate more recently evolved traits. This mode of gene co-option may be an important driver of evolutionary innovations.     

Disruption of mitotic arrest precedes precocious differentiation and transdifferentiation of pregranulosa cells in the perinatal Wnt4 mutant ovary

Mammalian sex determination is controlled by antagonistic pathways that are initially co-expressed in the bipotential gonad and subsequently become male- or female-specific. In XY gonads, testis development is initiated by upregulation of Sox9 by SRY in pre-Sertoli cells. Disruption of either gene leads to complete male-to-female sex reversal. Ovarian development is dependent on canonical Wnt signaling through Wnt4, Rspo1 and β-catenin. However, only a partial female-to-male sex reversal results from disruption of these ovary-promoting genes. In Wnt4 and Rspo1 mutants, there is evidence of pregranulosa cell-to-Sertoli cell transdifferentiation near birth, following a severe decline in germ cells. It is currently unclear why primary sex reversal does not occur at the sex-determining stage, but instead occurs near birth in these mutants. Here we show that Wnt4-null and Rspo1-null pregranulosa cells transition through a differentiated granulosa cell state prior to transdifferentiating towards a Sertoli cell fate. This transition is preceded by a wave of germ cell death that is closely associated with the disruption of pregranulosa cell quiescence. Our results suggest that maintenance of mitotic arrest in pregranulosa cells may preclude upregulation of Sox9 in cases where female sex-determining genes are disrupted. This may explain the lack of complete sex reversal in such mutants at the sex-determining stage.     

Inventing a sex-specific gene: a conserved role of DMRT1 in teleost fishes plus a recent duplication in the medaka Oryzias latipes resulted in DMY

DMY, the first sex-determining gene to be described in a nonmammal vertebrate was recently characterized in the medaka fish (Oryzias latipes). It is homologous to DMRT1, a conserved gene of the sex determination cascade in vertebrates. We have checked the near complete genomes of two other percomorph fishes, Tetraodon nigroviridis and Takifugu rubripes, for supplementary homologs of DMRT1 and DMY. We also compared the new gene, DMY, to its homolog DMRT1 from all available vertebrates. Finally, we found evidence for sex-specific expression and alternative splicing of the homolog from T. nigroviridis. Our results show that DMY is a recent duplicate of DMRT1 in the medaka. Its role in sex determination was not acquired through an acceleration of evolutionary rates, but by translocation to the Y chromosome and possibly changes at key positions.     

A ZZ/ZW-type sex determination in Xenopus laevis

Genetic sex-determining systems in vertebrates include two basic types of heterogamety, which are represented by the XX/XY and ZZ/ZW types. Both types occur among amphibian species. Little is known, however, about the molecular mechanisms underlying amphibian sex determination. Recently, a W-linked gene, DM-W, was isolated as a paralog of DMRT1 in the African clawed frog Xenopus laevis, which has a female heterogametic ZZ/ZW-type sex-determining system. The DNA-binding domain of DM-W shows high sequence identity with that of DMRT1, but DM-W does not contain a domain with homology to DMRT1's transactivation domain. Importantly, phenotypic analysis of transgenic individuals bearing a DM-W-expression or -knockdown vector strongly suggested that DM-W acts as a female sex-determining gene in this species. In this minireview, we briefly describe the sex-determining systems in amphibians, discuss recent findings from the discovery of the DM-W gene in terms of its molecular evolution and its function in sex determination and ovary formation, and introduce a new model for the ZZ/ZW-type sex determination elicited by DM-W and DMRT1 in X. laevis. Finally, we discuss sex-determining systems and germ-cell development during vertebrate evolution, especially in view of a conserved role of DMRT1 in gonadal masculinization.     

New Y chromosomes and early stages of sex chromosome differentiation: sex determination in <Emphasis Type="Italic">Megaselia</Emphasis>

The phorid fly Megaselia scalaris is a laboratory model for the turnover and early differentiation of sex chromosomes. Isolates from the field have an XY sex-determining mechanism with chromosome pair 2 acting as X and Y chromosomes. The sex chromosomes are homomorphic but display early signs of sex chromosome differentiation: a low level of molecular differences between X and Y. The male-determining function (M), maps to the distal part of the Y chromosome’s short arm. In laboratory cultures, new Y chromosomes with no signs of a molecular differentiation arise at a low rate, probably by transposition of M to these chromosomes. Downstream of the primary signal, the homologue of the Drosophila doublesex (dsx) is part of the sex-determining pathway while Sex-lethal (Sxl), though structurally conserved, is not.     

Sex determination in the genus Oreochromis

Summary Sex ratios from 62 single-pair matings of normal broodstock O. aureus were highly heterogeneous with an overall deficit of males (41.4%). Peaks in the sex ratio frequency distribution occurred at 11, 35 and 13 (malefemale). Hybridisation of O. aureus with O. mossambicus, O. spilums and O. niloticus produced highly variable sex ratios, suggesting a complexity of hybrid sex determination. Few valid inferences could be made regarding intraspecific sex determination from these hybrid data. Sex ratios from progeny testing of sex-reversed males (13) and most sex-reversed females (10) provide evidence for female heterogamety in O. aureus. Several aberrant ratios observed suggest Mendelian inheritance of an autosomal recessive gene (F,f), epistatic to the major sex-determining gene (W,Z). Sex ratios of triploids and gynogens support the hypothesis of recombination between the centromere and the major sex-determining locus. Progeny testing of a female mitogyne demonstrated the viability of a novel WW superfemale, which gave only female offspring. Not all data could be explained by a two-factor model of sex determination. Further exceptional sex ratios may be accounted for by rare autosomal or environmental sex-modifying factors. It is concluded that O. aureus has a multifactorial mechanism of sex determination with the underlying primary mechanism of female heterogamety.     

Genome assembly,sex-biased gene expression and dosage compensation in the damselfly Ischnura elegans

The evolution of sex chromosomes, and patterns of sex-biased gene expression and dosage compensation, are poorly known among early winged insects such as odonates. We assembled and annotated the genome of Ischnura elegans (blue-tailed damselfly), which, like other odonates, has a male-hemigametic sex-determining system (X0 males, XX females). By identifying X-linked genes in I. elegans and their orthologs in other insect genomes, we found homologies between the X chromosome in odonates and chromosomes of other orders, including the X chromosome in Coleoptera. Next, we showed balanced expression of X-linked genes between sexes in adult I. elegans, i.e. evidence of dosage compensation. Finally, among the genes in the sex-determining pathway only fruitless was found to be X-linked, while only doublesex showed sex-biased expression. This study reveals partly conserved sex chromosome synteny and independent evolution of dosage compensation among insect orders separated by several hundred million years of evolutionary history.     

Variability of genetic sex determination in poeciliid fishes

Poeciliids are one of the best-studied groups of fishes with respect to sex determination. They present an amazing variety of mechanisms, which span from simple XX-XY or ZZ-ZW systems to polyfactorial sex determination. The gonosomes of poeciliids generally are homomorphic, but very early stages of sex chromosome differentiation have been occasionally detected in some species. In the platyfish Xiphophorus maculatus, gene loci involved in melanoma formation, in different pigmentation patterns and in sexual maturity are closely linked to the sex-determining locus in the subtelomeric region of the X- and Y- chromosomes. The majority of traits encoded by these loci are highly polymorphic. This phenomenon might be explained by the high level of genomic plasticity apparently affecting the sex-determining region, where frequent rearrangements such as duplications, deletions, amplifications, and transpositions frequently occur. We propose that the high plasticity of the sex-determining region might explain the variability of sex determination in Xiphophorus and otherbreak poeciliids.     

Hens,cocks and avian sex determination: A quest for genes on Z or W?

The sex of an individual is generally determined genetically by genes on one of the two sex chromosomes. In mammals, for instance, the presence of the male-specific Y chromosome confers maleness, whereas in Drosophila melanogaster and Caenorhabditis elegans it is the number of X chromosomes that matters. For birds (males ZZ, females ZW), however, the situation remains unclear. The recent discovery that the Z-linked DMRT1 gene, which is conserved across phyla as a gene involved in sexual differentiation, is expressed early in male development suggests that it might be the number of Z chromosomes that regulate sex in birds. On the other hand, the recent identification of the first protein unique to female birds, encoded by the W-linked PKCIW gene, and the observation that it is expressed early in female gonads, suggests that the W chromosome plays a role in avian sexual differentiation. Clearly defining the roles of the DMRT1 and PKC1W genes in gonadal development, and ultimately determining whether avian sex is dependent on Z or W, will require transgenic experiments.     

The medaka sex-determining gene DMY acquired a novel temporal expression pattern after duplication of DMRT1

The male sex-determining gene, DMY, of the medaka is considered to have arisen via gene duplication of DMRT1. In the medaka, both genes are expressed in Sertoli cell lineage cells, but their temporal expression patterns are quite different. DMY expression starts just before the sex-determining period, whereas DMRT1 expression occurs during the testicular differentiation period. To evaluate the alterations to the expression patterns of the DMRT1 genes after duplication, we analyzed the morphological gonadal sex differentiation processes and expression patterns of DMRT1 in Oryzias luzonensis and Oryzias mekongensis, which are closely related to the medaka but do not have DMY. Male-specific upregulation of DMRT1 in these two species occurred during the testicular differentiation period, similar to the case for DMRT1 in the medaka. These findings suggest that DMY acquired a novel temporal expression pattern after duplication and that this event played a critical role in the evolutionary process of this gene.