Genome-wide DNA methylomes from discrete developmental stages reveal the predominance of non-CpG methylation in Tribolium castaneum.

Cytosine DNA methylation is a vital epigenetic regulator of eukaryotic development. Whether this epigenetic modification occurs in Tribolium castaneum has been controversial, its distribution pattern and functions have not been established. Here, using bisulphite sequencing (BS-Seq), we confirmed the existence of DNA methylation and described the methylation profiles of the four life stages of T. castaneum. In the T. castaneum genome, both symmetrical CpG and non-CpG methylcytosines were observed. Symmetrical CpG methylation, which was catalysed by DNMT1 and occupied a small part in T. castaneum methylome, was primarily enriched in gene bodies and was positively correlated with gene expression levels. Asymmetrical non-CpG methylation, which was predominant in the methylome, was strongly concentrated in intergenic regions and introns but absent from exons. Gene body methylation was negatively correlated with gene expression levels. The distribution pattern and functions of this type of methylation were similar only to the methylome of Drosophila melanogaster, which further supports the existence of a novel methyltransferase in the two species responsible for this type of methylation. This first life-cycle methylome of T. castaneum reveals a novel and unique methylation pattern, which will contribute to the further understanding of the variety and functions of DNA methylation in eukaryotes.