Division of Epigenetics, DKFZ-ZMBH Alliance, German Cancer Research Center, Heidelberg, Germany.
PLoS Biol. 2010 Nov 2;8(11):e1000506. doi: 10.1371/journal.pbio.1000506.
In honey bees (Apis mellifera) the behaviorally and reproductively distinct queen and worker female castes derive from the same genome as a result of differential intake of royal jelly and are implemented in concert with DNA methylation. To determine if these very different diet-controlled phenotypes correlate with unique brain methylomes, we conducted a study to determine the methyl cytosine (mC) distribution in the brains of queens and workers at single-base-pair resolution using shotgun bisulfite sequencing technology. The whole-genome sequencing was validated by deep 454 sequencing of selected amplicons representing eight methylated genes. We found that nearly all mCs are located in CpG dinucleotides in the exons of 5,854 genes showing greater sequence conservation than non-methylated genes. Over 550 genes show significant methylation differences between queens and workers, revealing the intricate dynamics of methylation patterns. The distinctiveness of the differentially methylated genes is underscored by their intermediate CpG densities relative to drastically CpG-depleted methylated genes and to CpG-richer non-methylated genes. We find a strong correlation between methylation patterns and splicing sites including those that have the potential to generate alternative exons. We validate our genome-wide analyses by a detailed examination of two transcript variants encoded by one of the differentially methylated genes. The link between methylation and splicing is further supported by the differential methylation of genes belonging to the histone gene family. We propose that modulation of alternative splicing is one mechanism by which DNA methylation could be linked to gene regulation in the honey bee. Our study describes a level of molecular diversity previously unknown in honey bees that might be important for generating phenotypic flexibility not only during development but also in the adult post-mitotic brain.
在蜜蜂(Apis mellifera)中,行为和生殖上有区别的蜂王和工蜂后两种性别是由同一基因组产生的,这是由于蜂王浆的不同摄入,并与 DNA 甲基化协同实施的。为了确定这些非常不同的饮食控制表型是否与独特的大脑甲基组相关,我们进行了一项研究,以确定使用鸟枪法亚硫酸氢盐测序技术在单碱基分辨率下蜂王和工蜂大脑中的甲基胞嘧啶(mC)分布。通过对代表八个甲基化基因的选定扩增子进行深度 454 测序,对全基因组测序进行了验证。我们发现,在 5854 个具有更高序列保守性的外显子中的 CpG 二核苷酸中几乎所有的 mC 都位于 CpG 二核苷酸中。在蜂王和工蜂之间,有超过 550 个基因表现出显著的甲基化差异,揭示了甲基化模式的复杂动态。差异甲基化基因的独特性突出表现在它们与甲基化基因的中间 CpG 密度以及 CpG 更丰富的非甲基化基因之间的相对关系上。我们发现,甲基化模式与剪接位点之间存在很强的相关性,包括那些有可能产生替代外显子的剪接位点。我们通过对一个差异甲基化基因编码的两个转录变体进行详细检查,验证了我们的全基因组分析。DNA 甲基化与剪接之间的联系进一步得到了组蛋白基因家族中基因的差异甲基化的支持。我们提出,可变剪接的调节是 DNA 甲基化与蜜蜂基因调控相关的一种机制。我们的研究描述了蜜蜂中以前未知的分子多样性水平,这可能对发育过程中和成年后有丝分裂后大脑中的表型灵活性的产生很重要。
