Integrated analysis of the gonadal methylome and transcriptome provides new insights into the expression regulation of sex determination and differentiation genes in spotted scat (Scatophagus argus)

Abstract

The spotted scat (Scatophagus argus) is an economically important mariculture fish. There have been no studies of gonadal DNA methylation at the genomic level in S. argus. Here, the gonadal methylome profiles of male and female S. argus were constructed and a link between DNA methylation and transcriptional regulation was identified. The gonads at stage IV of three male and female S. argus individuals were subjected to whole-genome bisulfite sequencing (WGBS), generating an average of 17.76 Gb of clean data for each sample. Analysis of methylation levels in different genomic regions revealed that both male and female S. argus gonads exhibited low methylation levels in the promoters and first exons, but high levels in the inner exons and introns. In general, DNA methylation levels were higher in the testes than in the ovaries. A total of 234,482 differentially methylated regions (DMRs) were identified between testes and ovaries, including 234,245, 26 and 211 DMRs in the CpG, CHG, and CHH backgrounds, respectively. Combined methylation and transcriptome analysis revealed that the relationship between methylation patterns and gene expression was generally negatively correlated. The male-specific Dmrt1Y, which is the candidate sex-determining gene of S. argus, was lowly modified by DNA methylation at its promoter region in the testis. While its allele on the X chromosome, Dmrt1ΔX, was highly modified by DNA methylation in both the testis and ovary. The expression levels of some other genes involved in sex differentiation and sex steroid synthesis were also regulated by DNA methylation. This study sheds light on the divergent methylation patterns in the gonadal genomes of male and female S. argus. These findings laid the foundation for subsequent analysis of differentially expressed sex determination and differentiation genes between male and female S. argus, providing a crucial theoretical basis for sex-control breeding efforts in S. argus.