Male-biased expression of X-chromosomal DM domain-less Dmrt8 genes in the mouse.

The vertebrate DMRT gene family encodes putative transcription factors related to the sexual regulators Doublesex (Drosophila melanogaster) and MAB-3 (Caenorhabditis elegans). They share a highly conserved DNA binding motif, the DM domain. In human and mouse seven DMRT genes (DMRT1-DMRT7) have been analyzed. DMRT8, a gene related to DMRT7, is located on the X chromosome in placental mammals. While DMRT8 is single copy in most mammals, three copies are present in mouse, rat, and rabbit. Despite the loss of the DM domain, DMRT8 genes have been maintained in the mammalian lineage, suggesting a DM domain-independent function. In adult mouse, two Dmrt8 genes are expressed exclusively in testis. Dmrt8.1 mRNA was detected in Sertoli cells by in situ hybridization. In embryos, Dmrt8.2 shows a dynamic expression restricted to male and female gonads and might therefore be involved in sexual development in the mouse.

Molecular analysis of the sex-determining region of the platyfish Xiphophorus maculatus.

Due to the presence of genetically well-defined sex chromosomes, with a relatively restricted sex-determination region containing markers identified at the molecular level, the platyfish Xiphophorus maculatus is one of the best models for the positional cloning of a master sex-determining gene in fish. Both male and female heterogametes and three different types of sex chromosomes have been described in the platyfish, with several loci involved in pigmentation, melanoma formation, and sexual maturity closely linked to the master sex-determining locus. Using the melanoma-inducing oncogene Xmrk, its protooncogenic counterpart egfrb, as well as other X- and Y-linked molecular markers, bacterial artificial chromosome (BAC) contigs have been assembled for the sex-determining region of X. maculatus, which was mapped by fluorescent in situ hybridization to the subtelomeric region of the sex chromosomes. Initial sequence analysis of these contigs revealed several gene candidates and uncovered syntenies with different mammalian and chicken autosomes, supporting an independent origin of sex chromosomes in platyfish and tetrapods. Strikingly, the sex determination region of the platyfish is very instable and frequently undergoes duplications, deletions, and transpositions. This instability might be linked to the high genetic variability affecting sex determination and other sex-linked traits in Xiphophorus.

Tissue-specific expression of dmrt genes in embryos and adults of the platyfish Xiphophorus maculatus.

The vertebrate dmrt gene family encodes transcription factors with a characteristic DNA-binding motif called the DM domain. The best studied member is dmrt1, which is involved in sexual development in fish and tetrapods. The cloning of dmrt5 from the platyfish Xiphophorus maculatus and the expression pattern of dmrt1, dmrt2a, dmrt4, and dmrt5 in adults and embryos are reported. Consistent with a role in sexual development, platyfish dmrt1 is expressed exclusively in adult testis. Interestingly, dmrt1 expression was detected in both spermatogonia and Sertoli cells. This contrasts with the situation in other fish, where dmrt1 is not expressed in both types of cells, and is reminiscent of the expression observed in other vertebrates. Certain expression patterns in platyfish embryos were similar to those found in other vertebrates, suggesting conserved functions of dmrt genes in vertebrate development. This was the case for dmrt2a/terra and dmrt4, presenting expression patterns compatible with roles in somitogenesis and olfactory system development, respectively. However, differences in expression during embryogenesis and in adult tissues were observed not only between fish and tetrapods, but also between fish species, illustrating the possible functional divergence of this gene family in fish and other vertebrates.

Transposable elements as a source of genetic innovation: expression and evolution of a family of retrotransposon-derived neogenes in mammals.

A family of functional neogenes called Mart, related to the gag gene of Sushi-like long terminal repeat retrotransposons from fish and amphibians, is present in the genome of human (11 genes) and other primates, as well as in mouse (11 genes), rat, dog (12 genes), cat, and cow. Mart genes have lost their capacity of retrotransposition through non-functionalizing rearrangements having principally affected long terminal repeats and pol open reading frame. Most Mart genes are located on the X chromosome in different mammals. Sequence database analysis suggested that Mart genes are present in opossum (marsupial), but absent from the genome of chicken. Hence, the Mart gene family might have been formed from Sushi-like retrotransposon(s) after the split of birds and mammals (310 myr ago), but before the divergence between placental mammals and marsupials (170 myr ago). RT-PCR analysis showed that at least six Mart genes are expressed during mouse embryonic development, with in situ hybridization analysis revealing rather ubiquitous expression patterns. Mart expression was also detected in adult mice, with some genes being expressed in all tissues tested, while others showed a much more restricted expression pattern. Although additional analysis will be required to establish the function of the retrotransposon-derived Mart neogenes, these observations support the evolutionary importance of retrotransposable elements as a source of genetic novelty.

Cloning of the dmrt1 gene of Xiphophorus maculatus: dmY/dmrt1Y is not the master sex-determining gene in the platyfish.

In contrast to the situation observed in mammals and birds, a switching between different sex determination systems frequently occurred during the evolution of the teleost fish lineage. This might be due to a frequent turnover of sex-determining signals at the top of the sex determination cascade (master sex-determining genes in the case of genetic sex determination). Alternatively, different variations of a same master gene might decide the sex of individuals in different sex determination systems. In the medaka Oryzias latipes, a Y-specific copy of the putative transcription factor gene dmrt1 very likely corresponds to the master sex-determining gene inducing male formation [Nature 417 (2002) 559; Proc. Natl. Acad. Sci. U. S. A. 99 (2002) 11778]. This gene, alternately called dmY and dmrt1Y, has been formed by duplication of the autosomal dmrt1. In order to determine if an orthologue of dmrt1Y was also located in the sex determination region of the related platyfish Xiphophorus maculatus, Southern blot analysis was performed on genomic DNA from XY and YY males and WY and XX females using both medaka and human dmrt1 cDNA as probes. Using different restriction enzymes, no evidence for sex-specific dmrt-containing genomic fragments could be found in the platyfish. No dmrt gene could be detected by low-stringency Southern blot analysis of genomic inserts from 60 bacterial artificial chromosome (BAC) clones linked to the sex-determining locus on the X and Y chromosomes. Six different groups of BAC clones containing dmrt genes were isolated from a platyfish genomic library. X. maculatus dmrt1 gene and cDNA were characterised. In adult, expression of dmrt1 was detected only in testis. Phylogenetic analysis indicated that the duplication of dmrt1 that led to the formation of dmY/dmrt1Y within the medaka lineage clearly occurred after its divergence from the platyfish lineage. Hence, a dmY/dmrt1Y orthologue generated by this particular event of duplication does not correspond to the master sex-determining gene in the platyfish.