Abstract
DNA methylation is a conserved chemical modification, by which methyl groups are added to the cytosine of DNA molecules. Methylation can influence gene expression without changing the sequence of a particular gene. This epigenetic effect is an intriguing phenomenon that has puzzled biologists for years. By probing the temporal and spatial patterns of DNA methylation in genomes, it is possible to learn about the biological role of cytosine methylation, as well as its involvement in gene regulation and transposon silencing. Advances in whole-genome sequencing have led to the widespread adoption of methods that examine genome-wide patterns of DNA methylation. Achieving sufficient sequencing depth in these types of experiments is costly, particularly for pilot studies in organisms with large genome sizes, or incomplete reference genomes. To overcome this issue, assays to determine site-specific DNA methylation can be used. Although often used, these assays are rarely described in detail. Here, we describe a pipeline that applies traditional TA cloning, Sanger sequencing, and online tools to examine DNA methylation. We provide an example of how to use this protocol to examine the pattern of DNA methylation at a specific transposable element in maize.