Abstract
Context-dependent gene expression in eukaryotes is controlled by several mechanisms including cytosine methylation that primarily occurs in the CG dinucleotides (CpGs). However, less frequent non-CpG asymmetric methylation has been found in various cell types, such as mammalian neurons, and recent results suggest that these sites can repress transcription independently of CpG contexts. In addition, an emerging view is that CpG hemimethylation may arise not only from deregulation of cellular processes but also be a standard feature of the methylome. Here, we have applied a novel approach to examine whether asymmetric CpG methylation is present in a sparsely methylated genome of the honeybee, a social insect with a high level of epigenetically driven phenotypic plasticity. By combining strand-specific ultra-deep amplicon sequencing of illustrator genes with whole-genome methylomics and bioinformatics, we show that rare asymmetrically methylated CpGs can be unambiguously detected in the honeybee genome. Additionally, we confirm differential methylation between two phenotypically and reproductively distinct castes, queens and workers, and offer new insight into the heterogeneity of brain methylation patterns. In particular, we challenge the assumption that symmetrical methylation levels reflect symmetry in the underlying methylation patterns and conclude that hemimethylation may occur more frequently than indicated by methylation levels. Finally, we question the validity of a prior study in which most of cytosine methylation in this species was reported to be asymmetric.
Highlights
IntroductionAs methylation levels average information from all reads, all or most of the fragments of DNA in the bisulfite sequencing experiment must be hemimethylated in the same direction for hemimethylation to be detected
The role of asymmetric cytosine methylation remains debatable, recent results support the idea that methylated CpH sites have an intrinsic capacity to repress transcription independently of CpG contexts [6]
By identifying asymmetry in methylation patterns in our amplicons and detecting consistently hemimethylated sites, our study provides new evidence that rare asymmetrically methylated CpGs are present in brain methylomes
Summary
As methylation levels average information from all reads, all or most of the fragments of DNA in the bisulfite sequencing experiment must be hemimethylated in the same direction for hemimethylation to be detected Tools such as Methpat and MPFE have been developed to study methylation patterns rather the levels [14]. A recent report by Niazi et al [23] claiming that in the honeybee, much of the methylation is asymmetric is highly surprising We reinvestigate this unanticipated result by applying a novel combination of in silico analysis and deep strand-specific amplicon bisulfite sequencing that allow exploring both methylation levels and methylation patterns to identify consistent cases of hemimethylation, and to assess symmetry of methylation patterns
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