Reliability of sex determination in ovine embryos using amelogenin gene (AMEL)

Sex specific sequence variability of the amelogenin gene has been used for sex determination in the family of Bovidae. In our study, suitability and reliability of the amelogenin gene for ovine sex determination in embryos was studied. The specificity of the method was previously demonstrated by testing 579 blood samples from several Spanish sheep breeds (161 males and 198 females). No amplification failures and very high agreement between genotypic and phenotypic sex was found (578/579), in contrast to humans, where errors in sex determination has been reported because of mutations in AMELX or AMELY genes. However, one female animal showed a male genotypic sex, being the most plausible explanation that a recombination event has happened during the meiosis. In our study only 0.17% (1/579) of the samples tested has been misdiagnosed using the amelogenin gene. Finally, 1-10 cells from each of 67 compact morulae were aspirated through the zona pellucida, and genotyped for sex determination. The efficiency in sex determination was 95 and 98% when more than two and more than three cells were sampled, respectively. The total time required for the genetic test, was less than 4h. These results confirm that the amelogenin gene can be used for rapid sex determination in ovine embryos, with a high efficiency and accuracy (100%) when three or more cells are sampled, allowing transferring sexed fresh embryos in MOET programmes. To our knowledge, this was the first time that sex determination using the amelogenin gene was performed in ovine embryos.     

哺乳动物的性别决定相关基因的作用机理

哺乳动物的性别决定是以Sry基因为主导,其它多个基因参与的级联调控的机制。近年来的研究表明,Sry、Sox9、Wt1、Sf1、Amh、Dax1、Dmrt1、Wnt4等基因都参与性别决定的级联过程。哺育动物性别决定相关基因的研究,对性分化与生殖发育过程的了解具有十分重要的意义。主要论述了参与哺乳动物性别决定与调控的相关基因、可能作用机制及其研究进展等。     

R-spondin1—discovery of the long-missing,mammalian female-determining gene?

Until recently, sex determination in mammals has often been described as a male determination process, with male differentiation being the active and dominant pathway, and only in its absence is the passive female pathway followed. This picture has been challenged recently with the discovery that the gene encoding R-spondin1 is mutated in human patients with female-to-male sex reversal. These findings might place R-spondin1 in the exceptional position of being the female-determining gene in mammals. In this review, possible roles of R-spondin1 during sex determination as well as questions arising from this study will be discussed.     

Preimplantation embryo sexing by polymerase chain reaction amplification of the sry gene on single mouse blastomeres

Accurate and rapid sex determination of preimplantation embryos has great potential both in animal breeding and in human pathology. In the past, sex determination has been accomplished by cytogenetic or immunologic means and by polymerase chain reaction amplification of Y-chromosome-specific repetitive sequences. More recently, amplification of the Y-specific single-copy ZFY gene has been used in humans for sex determination of preimplantation embryos. The experiments reported here indicate that another Y-chromosome-specific single-copy gene, the sex-determining region gene (sry) can be successfully amplified from single mouse blastomeres. Blastocysts positive for sry amplification were reimplanted to foster mothers, and six of six newborns were male. We conclude that sry gene amplification can represent a good marker for embryo sex determination.     

SOX、DMRT性别决定基因家族及其应用研究进展

SOX基因家族是在动物中发现的一类新的编码转录因子的基因家族,其产物具有一个HMG基序保守区,参与诸如性别决定等多种早期胚胎发育过程。到目前为止,在XXXY染色体性别决定系统中,只发现了两个性别决定基因:一个是SRY,它主要在哺乳动物性别决定中起作用;一个是DMY,它是在青鳉(Oryziaslatipes)中发现的。SRY属于SOX基因家族,而DMY则属于另一个普遍参与脊椎动物性别决定过程的DMTR基因家族。本文综述了这两大性别决定基因的研究进展,并探讨了它们在水产养殖动物性别决定基因研究中的意义和价值。     

黑腹果蝇的性别控制

性别的形成包括两个过程,即性别决定和性别分化。果蝇的性别控制研究包括性别决定、性别分化、性别鉴定、性别诱导和性别控制5个方面。性别决定是在两种不同发育途径之间的选择,它提供了一个研究基因调控的模式系统。果蝇的性别决定问题已经研究得相当详细［1］。性别分化是使胚胎向着雌性或雄性发育的过程,决定了性别表型。果蝇的性别分化也取得了不少研究成果。近年来,许多重要的性别调控基因已被克隆和鉴定。随着果蝇基因组全序列测定的完成,果蝇的性别控制研究将会更为深入而完善。本文对与黑腹果蝇性别决定和性别分化相关的一些问题进行综述。     

Sex determination in fish: Lessons from the sex-determining gene of the teleost medaka, Oryzias latipes

Although sex determination systems in animals are diverse, sex-determining genes have been identified only in mammals and some invertebrates. Recently, DMY (DM domain gene on the Y chromosome) has been found in the sex-determining region on the Y chromosome of the teleost medaka fish, Oryzias latipes. Functional and expression analyses of DMY show it to be the leading candidate for the male-determining master gene of the medaka. Although some work is required to define DMY as the master sex-determining gene, medaka is expected to be a good experimental animal for investigating the precise mechanisms involved in primary sex determination in non-mammalian vertebrates. In this article, the process of identification of DMY and is summarized and the origins of DMY and sexual development of the medaka's gonads are reviewed. In addition, putative functions of DMY are discussed.     

Sex Determination in Reptiles: An Update

Sex determination and sex differentiation are two separate butrelated phenomena. Sex differentiation is a programmed cascadeof events in which the indifferent gonad develops as a testisor an ovary with the appropriate urogenital and secondary sexcharacters. Sex determination is the event that sets this cascadein motion. In placental mammals, there is good evidence thatsex is determined by a gene on the Y chromosome (SRY) that initiatestestis formation. In the absence of SRY an ovary develops. Thereare, however, examples of placental mammal that develop as normalmales with no detectable SRY. In reptiles, sex differentiationappears to be similar to mammals (i.e., the same genes and hormonesact ina similar manner), but sex determination is clearly verydifferent. Ovarian differentiation in placental mammals canoccur in the absence of estrogen or an estrogen receptor. Ovariandifferentiation in reptiles requires the presence of estrogen.In the absence of estrogen a testis develops. In TSD reptiles,embryos will develop as females when treated with estrogen evenif eggs are incubated at male-inducing temperatures, and conversely,will develop as males when estrogen synthesis is blocked ineggs incubated at female-inducing temperatures. A number ofother genes have also been shown to be important in mammaliansex determination. One of these genes, Sox9, which is expressedin differentiating mouse testis, has recently been found tobe expressed in embryonic reptile testis. Other genes that appearto be common to both mammals and reptiles in the sex determiningcascade are SF- 1, MIH, and possibly DAX-1. Current researchis now focused on how the gene that produces the enzyme necessaryfor estrogen synthesis (aromatase) is regulated in the embryosof reptiles with genetic or environmental sex determination.Controversial issues in reptilian sex determination are 1) therole of the brain in gonadal sex determination, and 2) the roleof steroid hormones in the yolk prior to sex determination     

棕色田鼠不同性别中R-spondin1基因的特殊表达

哺乳动物睾丸决定的诱导一般依赖于Sry基因,然而棕色田鼠指名亚种的Sry基因已经丢失,而棕色田鼠指名亚种雌雄个体依然有繁殖能力。我们在研究涉及性别决定的一些基因时,发现R-spondin1与性别决定有关。为了探讨R-spondin1在棕色田鼠中的性别决定中的作用,我们用RT-PCR检测R-spondin1在棕色田鼠性腺中的表达。研究结果表明R-spondin1仅在出生后不久的棕色田鼠指名亚种雌性个体的卵巢中表达,在出生后的棕色田鼠指名亚种雄性个体睾丸中未见其表达,这说明R-spondin1可能在棕色田鼠指名亚种卵巢发育中具有某种角色。     

Regain of sex determination system and sexual reproduction ability in a synthetic octoploid male fish

Polyploids in vertebrates are generally associated with unisexual reproduction, but the direct consequences of polyploidy on sex determination system and reproduction mode remain unknown. Here, we synthesized a group of artificial octoploids between unisexual gynogenetic hexaploid Carassius gibelio and sexual tetraploid Carassius auratus. The synthetic octoploids were revealed to have more than 200 chromosomes, in which 50 chromosomes including the X/Y sex determination system were identified to transfer from sexual tetraploid C. auratus into the unisexual gynogenetic hexaploid C. gibelio. Significantly, a few synthetic octoploid males were found to be fertile, and one octoploid male was confirmed to regain sexual reproduction ability,which exhibits characteristics that are the same to sexual reproduction tetraploid males, such as 1:1 sex ratio occurrence, meiosis completion and euploid sperm formation in spermatogenesis, as well as normal embryo development and gene expression pattern during embryogenesis. Therefore, the current finding provides a unique case to explore the effect of sex determination system incorporation on reproduction mode transition from unisexual gynogenesis to sexual reproduction along with genome synthesis of recurrent polyploidy in vertebrates.     

The dice of fate: the csd gene and how its allelic composition regulates sexual development in the honey bee, Apis mellifera

Perhaps 20% of known animal species are haplodiploid: unfertilized haploid eggs develop into males and fertilized diploid eggs into females. Sex determination in such haplodiploid species does not rely on a difference in heteromorphic sex chromosome composition but the genetic basis has been elucidated in some hymenopteran insects (wasps, sawflies, ants, bees). In these species, the development into one sex or the others depends on an initial signal whether there is only one allele or two different alleles of a single gene, the complementary sex determiner (csd), in the zygotic genome. The gene has been most-recently identified in the honey bee and has been found to encode an arginine serine-rich (SR) type protein. Heterozygosity generates an active protein that initiates female development while hemizygosity/homozygosity results in a non-active CSD protein and default male development. I will discuss plausible models of how the molecular decision of male and female is made and implemented. Comparison to hierarchies of dipteran insects suggests that SR-type protein has facilitated the differentiation of sex-determining systems and hierarchies.     

Amelogenin cross-amplification in the family Bovidae and its application for sex determination

Sex-specific sequence variability of the amelogenin gene had been observed in a variety of mammalian species. In our study, the suitability of the amelogenin gene for sex determination in different species of the family Bovidae was examined. Based on a sequence insertion/deletion characteristic for X- and Y-specific amelogenin (AMELX and AMELY), PCR amplification on male and female genomic DNA from domestic and wild bovine species, sheep and goat, consistently displayed a sex-specific pattern. Thus, the amelogenin amplification by PCR proved to be a reliable method for sex determination not only in domestic and wild species of the tribe Bovini, but also in the related species sheep and goat. Sex determination using the amelogenin-based assay can be performed with at least 40 pg of genomic DNA. The assay enables the investigation of small amounts of DNA from meat, hair, bones, and embryo biopsies to identify species and sex for a number of applications in animal production, forensics, population research, and monitoring within the family Bovidae. Sequence comparison of the amplified amelogenin gene region specific for male and female animals from domestic and wild bovide species revealed further sequence variations within and between sexes as well as between species. Sequence variations in the AMELX gene can be applied to discriminate Bos and Bison individuals from other bovine species, and also from sheep and goat.     

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.     

HOMOLOGOUS SEX CHROMOSOMES IN THREE DEEPLY DIVERGENT ANURAN SPECIES

Comparative genomic studies are revealing that, in sharp contrast with the strong stability found in birds and mammals, sex determination mechanisms are surprisingly labile in cold‐blooded vertebrates, with frequent transitions between different pairs of sex chromosomes. It was recently suggested that, in context of this high turnover, some chromosome pairs might be more likely than others to be co‐opted as sex chromosomes. Empirical support, however, is still very limited. Here we show that sex‐linked markers from three highly divergent groups of anurans map to Xenopus tropicalis scaffold 1, a large part of which is homologous to the avian sex chromosome. Accordingly, the bird sex determination gene DMRT1, known to play a key role in sex differentiation across many animal lineages, is sex linked in all three groups. Our data provide strong support for the idea that some chromosome pairs are more likely than others to be co‐opted as sex chromosomes because they harbor key genes from the sex determination pathway.     

ON THE INSTABILITY OF POLYGENIC SEX DETERMINATION: THE EFFECT OF SEX-SPECIFIC SELECTION

A combination of analytical and simulation models is used to explore the initial evolution of genic sex determination from polygenic sex determination. Prior studies have indicated that polygenic sex determination is rare or absent in extant species but that it has likely played an important intermediate role in the evolution of other genetic sex-determination systems. This study explores why polygenic sex determination does not persist. Two possibilities are considered. First it is assumed that a major sex-determining gene also pleiotropically increases fitness. Second it is assumed that the sex-determining gene is neutral but linked to another locus segregating for a rare selectively favored allele. The major conclusion from the models is that sex-specific natural selection will cause polygenic sex determination to be a transient state in most populations. Polygenic sex determination may be an important intermediate step in the evolution of genetically controlled sexual differentiation, but it is unlikely to persist unless there is some selective advantage compared to genic sex determination. This may in part explain the relatively small number of extant species that have polygenic sex determination.     

Mammalian sex--Origin and evolution of the Y chromosome and SRY

Sex determination in vertebrates is accomplished through a highly conserved genetic pathway. But surprisingly, the downstream events may be activated by a variety of triggers, including sex determining genes and environmental cues. Amongst species with genetic sex determination, the sex determining gene is anything but conserved, and the chromosomes that bear this master switch subscribe to special rules of evolution and function. In mammals, with a few notable exceptions, female are homogametic (XX) and males have a single X and a small, heterochromatic and gene poor Y that bears a male dominant sex determining gene SRY. The bird sex chromosome system is the converse in that females are the heterogametic sex (ZW) and males the homogametic sex (ZZ). There is no SRY in birds, and the dosage-sensitive Z-borne DMRT1 gene is a credible candidate sex determining gene. Different sex determining switches seem therefore to have evolved independently in different lineages, although the complex sex chromosomes of the platypus offer us tantalizing clues that the mammal XY system may have evolved directly from an ancient reptile ZW system. In this review we will discuss the organization and evolution of the sex chromosomes across a broad range of mammals, and speculate on how the Y chromosome, and SRY, evolved.     

人类性别决定和性别分化研究进展

SRY基因在人类性别分化中起着关键作用,目前研究认为SRY仅是涉及性别决定过程的基因之一,其他基因和SRY相关基因SOX9,抗副中肾激素基因AMH,编码缁类因子的基因SF1,X－连锁的DAX基因,wilm‘s肿瘤抑制基因WT1等基因都参与了人类性腺分化和发育,本文拟就人类性别决定基因的研究进展及其与人类性别分化的关系作一综述。     

Characterization of Pisrt1/Foxl2 in Ellobius lutescens and exclusion as sex-determining genes

The rodent Ellobius lutescens is an exceptional mammal which determines male sex constitutively without the SRY gene and, therefore, may serve as an animal model for human 46,XX female-to-male sex reversal. It was suggested that other factors of the network of sex-determining genes determine maleness in these animals. However, some sex-determining genes like SOX9 and SF1 have already been excluded by segregation analysis as primary sex-determining factors in E. lutescens. In this work, we have cloned and characterized two genes of the PIS (polled intersex syndrome) gene interval, which were reported as candidates in female-to-male sex reversal in hornless goats recently. The genes Foxl2 and Pisrt1 from that interval were identified in E. lutescens DNA and mapped to Chromosome 8. We have excluded linkage of Foxl2 and Pisrt1 loci with the sex of the animals. Hence, the involvement of this gene region in sex determination may be specific for goats and is not a general mechanism of XX sex reversal or XX male sex determination.The nucleotide sequence data reported in this article have been submitted to GenBank and have been assigned the accession number AY623815.     

Genetic mapping of the autosomal region involved in XX sex-reversal and horn development in goats

Contrary to other genetic disorders, the genetic study of sex determination anomalies in humans stumbles over the difficulty in observing large pedigrees. In goats, abnormalities in sex determination are intimately linked to a dominant Mendelian gene coding for the ``polled' (hornless) character, which could render this species an interesting animal model for the rare human cases of SRY-negative XX males. In this report, we describe genetic linkage between the polled/intersex synchome (PIS) and four microsatellite markers of the distal region of goat Chromosome 1 (CHI1), quite distinct from the bovine ``polled' region. According to comparative mapping data, no sex-determining gene has been described so far in homologous regions in the human. This genetic localization constitutes a first step towards identifying a new autosomal sex-determining gene in mammals. Received: 7 July 1995 / Accepted: 6 September 1995