TY - JOUR A1 - Tomaszkiewicz, Marta A1 - Chalopin, Domitille A1 - Schartl, Manfred A1 - Galiana, Delphine A1 - Volff, Jean-Nicolas T1 - A multicopy Y-chromosomal SGNH hydrolase gene expressed in the testis of the platyfish has been captured and mobilized by a Helitron transposon JF - BMC Genetics N2 - Background: Teleost fish present a high diversity of sex determination systems, with possible frequent evolutionary turnover of sex chromosomes and sex-determining genes. In order to identify genes involved in male sex determination and differentiation in the platyfish Xiphophorus maculatus, bacterial artificial chromosome contigs from the sex-determining region differentiating the Y from the X chromosome have been assembled and analyzed. Results: A novel three-copy gene called teximY (for testis-expressed in Xiphophorus maculatus on the Y) was identified on the Y but not on the X chromosome. A highly related sequence called texim1, probably at the origin of the Y-linked genes, as well as three more divergent texim genes were detected in (pseudo) autosomal regions of the platyfish genome. Texim genes, for which no functional data are available so far in any organism, encode predicted esterases/lipases with a SGNH hydrolase domain. Texim proteins are related to proteins from very different origins, including proteins encoded by animal CR1 retrotransposons, animal platelet-activating factor acetylhydrolases (PAFah) and bacterial hydrolases. Texim gene distribution is patchy in animals. Texim sequences were detected in several fish species including killifish, medaka, pufferfish, sea bass, cod and gar, but not in zebrafish. Texim-like genes are also present in Oikopleura (urochordate), Amphioxus (cephalochordate) and sea urchin (echinoderm) but absent from mammals and other tetrapods. Interestingly, texim genes are associated with a Helitron transposon in different fish species but not in urochordates, cephalochordates and echinoderms, suggesting capture and mobilization of an ancestral texim gene in the bony fish lineage. RT-qPCR analyses showed that Y-linked teximY genes are preferentially expressed in testis, with expression at late stages of spermatogenesis (late spermatids and spermatozeugmata). Conclusions: These observations suggest either that TeximY proteins play a role in Helitron transposition in the male germ line in fish, or that texim genes are spermatogenesis genes mobilized and spread by transposable elements in fish genomes. KW - sex determination KW - testis KW - Y chromosome KW - rolling-circle transposons KW - factor acetylhydrolase activity KW - platelet activation factor KW - xiphophorus maculatus KW - oryzias-latipes KW - sequence alignment KW - DM-domain gene KW - sex-determining region KW - evolution KW - fish KW - SGNH hydrolase KW - helitron KW - transposition KW - platyfish KW - sex chromosomes Y1 - 2014 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-116746 VL - 15 IS - 44 ER - TY - JOUR A1 - Adolfi, Mateus C. A1 - Herpin, Amaury A1 - Martinez-Bengochea, Anabel A1 - Kneitz, Susanne A1 - Regensburger, Martina A1 - Grunwald, David J. A1 - Schartl, Manfred T1 - Crosstalk Between Retinoic Acid and Sex-Related Genes Controls Germ Cell Fate and Gametogenesis in Medaka JF - Frontiers in Cell and Developmental Biology N2 - Sex determination (SD) is a highly diverse and complex mechanism. In vertebrates, one of the first morphological differences between the sexes is the timing of initiation of the first meiosis, where its initiation occurs first in female and later in male. Thus, SD is intimately related to the responsiveness of the germ cells to undergo meiosis in a sex-specific manner. In some vertebrates, it has been reported that the timing for meiosis entry would be under control of retinoic acid (RA), through activation of Stra8. In this study, we used a fish model species for sex determination and lacking the stra8 gene, the Japanese medaka (Oryzias latipes), to investigate the connection between RA and the sex determination pathway. Exogenous RA treatments act as a stress factor inhibiting germ cell differentiation probably by activation of dmrt1a and amh. Disruption of the RA degrading enzyme gene cyp26a1 induced precocious meiosis and oogenesis in embryos/hatchlings of female and even some males. Transcriptome analyzes of cyp26a1–/–adult gonads revealed upregulation of genes related to germ cell differentiation and meiosis, in both ovaries and testes. Our findings show that germ cells respond to RA in a stra8 independent model species. The responsiveness to RA is conferred by sex-related genes, restricting its action to the sex differentiation period in both sexes. KW - sex determination KW - retinoic acid KW - meiosis KW - gametogenesis KW - medaka Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-222669 SN - 2296-634X VL - 8 ER - TY - THES A1 - Klüver, Nils T1 - Molecular analysis of gonad development in medaka (Oryzias latipes) and Oryzias celebensis T1 - Molekulare Analyse der Gonadenentwicklung im Medaka (Oryzias latipes) und Oryzias celebensis N2 - The process of sex-determination can be better understood through examinations of developing organs and cells, which are involved in the formation of undifferentiated gonad. This mechanisms show in fish a broad variety, ranging from hermaphroditism to gonochorism and environmental to genetic sex determination. Hormones and abiotic factors such as temperature and pH can influence teleost development and reproductive traits. These factors are vulnerable to pollutants and climate changes. Therefore, it is important to examine gonad development and sex-determination/differentiation in teleost fish. Teleost fish are the largest known group of vertebrates with approximately 25,000 species and are used for such kind of examinations as model organisms. Recently, in Oryzias latipes (medaka), dmrt1bY (or dmy), a member of the Dmrt gene family, has been described as testis-determining gene. However, this gene is not the universal master sex-determining gene in teleost fish. Although dmrt1bY is present in the most closely related species of the genus, namely Oryzias curvinotous, it is absent from other Oryzias species, like Oryzias celebensis, and other fish. During my thesis, I studied gonad development in medaka and in the closely related species Oryzias celebensis. Germ cell specification in medaka seems to be dependent on maternally provided cytoplasmatic determinants, so called germ plasm. Nanos and vasa are such germ cell specific genes. In zebrafish they are asymmetrically localized in the early embryo. I have shown that nanos mRNA is evenly distributed in the early embryo of medaka. A similar pattern has been already described for the medaka vasa homolog, olvas. This suggests differences in PGC specification in zebrafish and medaka. Further, the vasa homolog was isolated and the expression pattern examined in O. celebensis. The results show that it can be used as a germ cell specific marker. Additionally, the primordial germ cell migration in O. celebensis was followed, which is similar to medaka PGC migration. Primordial germ cell migration in vertebrates is dependent on the chemokine stromal cell-derived factor 1 (Sdf-1). Medaka has two different sdf-1 genes, sdf-1a and sdf-1b. Both genes are expressed in the lateral plate mesoderm (LPM). During late embryonic development, I could show that sdf-1a is expressed in newly formed somites and not longer in the LPM. Sdf-1b expression persisted in the posterior part of the lateral plate mesoderm in the developing gonad. In terms of early and late functions, this suggests subfunctionalization of sdf-1a and sdf-1b. In “higher” vertebrates, genes that are involved in the process of gonad development have been studied in detail, e.g. Wt1, Sox9, and Amh. I have analyzed the expression pattern of wt1 and sox9 co-orthologs and amh. In both, the medaka and O. celebensis, wt1a transcripts were localized in the LPM and its expression was similar to sdf-1a gene expression in medaka. Wt1b expression was restricted to the developing pronephric region. During later embryonic development, wt1a is specifically expressed in the somatic cells of the gonad primordium in both sexes. This is the first time that in fish wt1 gene expression in developing gonads has been described. Therefore, this result suggests that wt1a is involved in the formation of the bipotential gonad. Furthermore, I have analyzed the gonad specific function of the wt1 co-orthologs in medaka. I could show that a conditional co-regulation mechanism between Wt1a and Wt1b ensures PGC maintenance and/or survival. The expression of sox9 genes in medaka and sox9b in O. celebensis were detected in the somatic cells of the gonad primordium of both sexes. Additionally, I have shown that amh and amhrII in medaka are expressed in somatic cells of the gonad primordium of both sexes. This suggests that sox9b, amh and amhrII are involved in gonad development and have specific functions in the adult gonad. In O. celebensis I could detect an expression of dmrt1 already six days after fertilization in half of the embryos, which is similar to the dmrt1bY expression in medaka. Whether the expression of dmrt1 is male specific in O. celebensis is currently under investigation. Altogether, the obtained results provide new insights into gene expression patterns during the processes of gonad development. Furthermore, no differences in the expression pattern of wt1a and sox9b during gonad development between the medaka and O. celebensis could be detected. This might indicate that the genetic mechanisms during gonad development are similar in both species. N2 - Die Untersuchung der Keimzellwanderung in O. celebensis zeigte hohe Ähnlichkeiten zu der bereits Beschriebenen im Medaka. Die Keimzellwanderung in Wirbeltieren ist abhängig von stromal cell-derived factor 1 (Sdf-1), einem chemotaktisch wirkendem Zytokinin. Im Medaka existieren zwei sdf-1 Gene, sdf-1a und sdf-1b, die während der embryonalen Entwicklung im Seitenplattenmesoderm (LPM) exprimiert werden. Die Expression der beiden Gene unterscheiden sich jedoch zeitlich und auch örtlich im LPM. Dies lässt vermuten, dass sich im Verlauf der Evolution eine frühe und eine späte keimzellspezifische Funktion zwischen sdf-1a und sdf-1b aufgeteilt hat. In „höheren“ Wirbeltieren wurden schon verschiedene Gene, z.B. Wt1, Sox9 und Amh, in dem Prozess der Gonadenentwicklung beschrieben. Die Expressionsmuster von wt1 und sox9 Co-Orthologen und amh habe ich während meiner Arbeit untersucht. Im Medaka und in O. celebensis wird wt1a im LPM transkribiert und ähnelt der von sdf-1a im Medaka. Die Expression von wt1b erfolgt hingegen nur in der Region der Vorläufer-Niere. Im weiteren Verlauf der Embryogenese ließen sich wt1a Transkripte erstmalig in somatischen Zellen des Gonaden-Vorläufers nachweisen. Wt1a spielt vermutlich eine Rolle in der Entwicklung der bipotentialen Gonade. Die funktionelle Analyse von wt1 Genen im Medaka zeigte, dass durch eine konditionale Co-Regulation zwischen wt1a und wt1b die Keimzellen überleben bzw. erhalten bleiben. Die Expression von sox9b im Medaka und in O. celebensis ließ sich in somatischen Zellen des Gonaden-Vorläufers nachweisen. Zusätzlich werden amh und amhrII ebenfalls in somatischen Zellen beider Geschlechter exprimiert, daher kann man eine wichtige Rolle dieser Gene während der Gonadenentwicklung und in der adulten Gonade annehmen. Die Expression von dmrt1 in O. celebensis konnte ich, in etwa der Hälfte der beobachteten Embryonen, bereits schon früh in der embryonalen Entwicklung (6 Tage nach der Befruchtung) nachweisen. Das Transkriptionsmuster von dmrt1 in O. celebensis ist ähnlich der Expression von dmrt1bY im Medaka. Inwieweit diese Expression in O. celebensis spezifisch für Männchen ist wird zurzeit noch untersucht. Die erhaltenen Ergebnisse zeigen neue Einblicke in die Genexpressionsmuster der Gonadenentwicklung von Medaka und O. celebensis und weisen neue Möglichkeiten für weitere Forschungen auf. Des Weiteren konnte ich im Verlauf der Gonadenentwicklung keine Unterschiede in der Genexpression von wt1a und sox9b zwischen Medaka und O. celebensis nachweisen. Dies deutet an, dass die genetischen Mechanismen der Gonadenentwicklung zwischen den beiden nahverwandten Arten sehr ähnlich sind. KW - Japankärpfling KW - Gonade KW - Geschlechtsbestimmung KW - Entwicklungsbiologie KW - medaka KW - sex determination KW - sox9 KW - amh KW - wt1 KW - gonad development Y1 - 2007 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-25105 ER -