The Kdm/Kmt gene families in the self-fertilizing mangrove rivulus fish, Kryptolebias marmoratus, suggest involvement of histone methylation machinery in development and reproduction

• Published in: Gene Vol. 687; pp. 173 - 187
• Main Authors: Fellous, Alexandre, Earley, Ryan L., Silvestre, Frederic
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.03.2019
• Subjects: Development; Gametogenesis; Histone methylation; Kdm; Kmt; Kryptolebias marmoratus; Suv39h1; PHF2; Setdb; RNA; Histone methylation; Ehmt; RRM; Prdm; LRR; AWS Domain; PHF8; ANK Domain; ARID; KDM; HXKXmeX; Dpy30; WDR5; Development; Ash2l; UTY; RT-qPCR; Nsd; JmjC; Rubis-Sub-Bind; Mllt; Gametogenesis; SETMAR; Ezh; KMT; Dot1l; PCR; BAH Domain; Aa; Kryptolebias marmoratus; ZnF_C2H2; SMYD; SET Domain; PWWP Domain; WW Domain; PHD; MBD; C1; ZnF_TTF; TPR; SANT Domain; HXKX; HMG; JmjN; FYRC; Jmj; Rbbp5; Bp; FYRN; CXC; CHROMO; DNA; Ash1l; N-SET Domain; Nap; Ezh2; Ezh1; Kmt; Kdm
• ISSN: 0378-1119; 1879-0038
• DOI: 10.1016/j.gene.2018.11.046

Histone modifications such as methylation of key lysine residues play an important role in embryonic development in a variety of organisms such as of Pacific oysters, zebrafish and mice. The action of demethylase (“erasers”) and methyltransferase (“writers”) enzymes regulates precisely the methylation status of each lysine residue. However, despite fishes being very useful model organisms in medicine, evolution and ecotoxicology, most studies have focused on mammalian and plant model organisms, and mechanisms underlying regulation of histones are unknown in fish development outside of zebrafish. Here, putative histone lysine demethylases (Kdm) and methyltransferases (Kmt) were identified in an isogenic lineage of the self-fertilizing hermaphroditic vertebrate, the mangrove rivulus fish, Kryptolebias marmoratus. Evolutionary relationships with other animal demethylases and methyltransferases were examined, and expression patterns during embryonic development and in adult tissues were characterized. Twenty-five Kdm orthologues (Jarid2, Jmjd1c, Jmjd4, Jmjd6, Jmjd7, Jmjd8, Kdm1a, Kdm1b, Kdm2a, Kdm2b, Kdm3b, Kdm4a, Kdm4b, Kdm4c, Kdm5a, Kdm5b, Kdm5c, Kdm6a, Kdm6b, Kdm7a, Kdm8, Kdm9, UTY, Phf2 and Phf8) and forty-eight Kmt orthologues (Ezh1, Ezh2, Setd2, Nsd1, Nsd2, Nsd3, Ash1l, Kmt2e, Setd5, Prdm1, Prdm2, Prdm4, Prdm5, Prdm6, Prdm8, Prdm9, Prdm10, Prdm11, Prdm12, Prdm13, Prdm14, Prdm15, Prdm16, Setd3, Setd4, Setd6, Setd1a, Setd1b, Kmt2a, Kmt2b, Kmt2c, Kmt2d, Kmt5a, Kmt5b, Ehmt1, Ehmt2, Suv39h1, Setmar, Setdb1, Setdb2, Smyd1, Smyd2, Smyd3, Smyd4, Smyd5, Setd7, Setd9, Dot1l) were discovered. Expression patterns of both Kdm and Kmt were variable during embryonic development with a peak in gastrula stage and a reduction in later embryogenesis. Expression of both Kdm and Kmt was higher in male brains compared to hermaphrodite brains whereas specific expression patterns of Kdm and Kmt were observed in the hermaphrodite ovotestes and male testes, respectively. Putative histone demethylases (Kdm) and methyltransferases (Kmt) were for the first time characterized in a teleost besides zebrafish, the mangrove rivulus. Their domain conservation and expression profiles suggest that they might play important roles during development, gametogenesis and neurogenesis, which raises questions about epigenetic regulation of these processes by histone lysine methylation in K. marmoratus. Due to its peculiar mode of reproduction and the natural occurrence of isogenic lineages, this new model species is of great interest for understanding epigenetic contributions to the regulation of development and reproduction. •25 genes coding for putative JmjC proteins and 48 genes coding for putative Kmts•Differences in number and duplicated genes among the teleost species•Dynamic expression during embryonnic development•Sex-specific pattern of the different transcripts in adult tissues•Conservation of the protein subunit necessary to the methyltransferase activity