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Sex chromosome and sex locus characterization in goldfish, Carassius auratus (Linnaeus, 1758).

TitleSex chromosome and sex locus characterization in goldfish, Carassius auratus (Linnaeus, 1758).
Publication TypeJournal Article
Year of Publication2020
AuthorsWen, M, Feron, R, Pan, Q, Guguin, J, Jouanno, E, Herpin, A, Klopp, C, Cabau, C, Zahm, M, Parrinello, H, Journot, L, Burgess, SM, Omori, Y, Postlethwait, JH, Schartl, M, Guiguen, Y
JournalBMC Genomics
Date Published2020 Aug 11

BACKGROUND: Goldfish is an important model for various areas of research, including neural development and behavior and a species of significant importance in aquaculture, especially as an ornamental species. It has a male heterogametic (XX/XY) sex determination system that relies on both genetic and environmental factors, with high temperatures being able to produce female-to-male sex reversal. Little, however, is currently known on the molecular basis of genetic sex determination in this important cyprinid model. Here we used sequencing approaches to better characterize sex determination and sex-chromosomes in an experimental strain of goldfish.

RESULTS: Our results confirmed that sex determination in goldfish is a mix of environmental and genetic factors and that its sex determination system is male heterogametic (XX/XY). Using reduced representation (RAD-seq) and whole genome (pool-seq) approaches, we characterized sex-linked polymorphisms and developed male specific genetic markers. These male specific markers were used to distinguish sex-reversed XX neomales from XY males and to demonstrate that XX female-to-male sex reversal could even occur at a relatively low rearing temperature (18 °C), for which sex reversal has been previously shown to be close to zero. We also characterized a relatively large non-recombining region (~ 11.7 Mb) on goldfish linkage group 22 (LG22) that contained a high-density of male-biased genetic polymorphisms. This large LG22 region harbors 373 genes, including a single candidate as a potential master sex gene, i.e., the anti-Mullerian hormone gene (amh). However, no sex-linked polymorphisms were detected in the coding DNA sequence of the goldfish amh gene.

CONCLUSIONS: These results show that our goldfish strain has a relatively large sex locus on LG22, which is likely the Y chromosome of this experimental population. The presence of a few XX males even at low temperature also suggests that other environmental factors in addition to temperature could trigger female-to-male sex reversal. Finally, we also developed sex-linked genetic markers, which will be important tools for future research on sex determination in our experimental goldfish population. However, additional work would be needed to explore whether this sex locus is conserved in other populations of goldfish.

Alternate JournalBMC Genomics
PubMed ID32781981
PubMed Central IDPMC7430817
Grant ListANR-13-ISV7-0005 / / Agence Nationale de la Recherche /
DFG-13-ISV7-0005 / / Deutsche Forschungsgemeinschaft /
ANR-10-INBS-09 / / Agence Nationale de la Recherche /
19K22426 / / Grant-in-Aid for Scientific Research /
R01OD011116 / NH / NIH HHS / United States
5R01GM085318 / NH / NIH HHS / United States