DNA N6-methyldeoxyadenosine in mammals and human disease.

N6-methyladenine (6mA) is the most prevalent DNA modification in prokaryotes. However, its presence and significance in eukaryotes remain elusive. Recently, with methodology advances in detection and sequencing of 6mA in eukaryotes, 6mA is back in the spotlight. Although multiple studies have reported that 6mA is an important epigenetic mark in eukaryotes and plays a regulatory role in DNA transcription, transposon activation, stress response, and other bioprocesses, there are some discrepancies in the current literature. We review the recent advances in 6mA research in eukaryotes, especially in mammals. In particular, we describe the abundance/distribution of 6mA, its potential role in regulating gene expression, identified regulators, and pathological roles in human diseases, especially in cancer. The limitations faced by the field and future perspectives in 6mA research are also discussed.

N6-methyladenine: A Rare and Dynamic DNA Mark.

Chromatin, consisting of deoxyribonucleic acid (DNA) wrapped around histone proteins, facilitates DNA compaction and allows identical DNA code to confer many different cellular phenotypes. This biological versatility is accomplished in large part by post-translational modifications to histones and chemical modifications to DNA. These modifications direct the cellular machinery to expand or compact specific chromatin regions and mark certain regions of the DNA as important for cellular functions. While each of the four bases that make up DNA can be modified (Iyer et al., Prog Mol Biol Transl Sci. 101:25-104, 2011), this chapter will focus on methylation of the 6th position on adenines (6mA). 6mA is a prevalent modification in unicellular organisms and until recently was thought to be restricted to them. A flurry of conflicting studies have proposed that 6mA either does not exist, is present at low levels, or is present at relatively high levels and regulates complex processes in different multicellular eukaryotes. Here, we will briefly describe the history of 6mA, examine its evolutionary conservation, and evaluate the current methods for detecting 6mA. We will discuss the proteins that have been reported to bind and regulate 6mA and examine the known and potential functions of this modification in eukaryotes. Finally, we will close with a discussion of the ongoing debate about whether 6mA exists as a directed DNA modification in multicellular eukaryotes.

N6-methyldeoxyadenosine directs nucleosome positioning in Tetrahymena DNA.

BACKGROUND: N6-methyldeoxyadenosine (6mA or m6dA) was shown more than 40 years ago in simple eukaryotes. Recent studies revealed the presence of 6mA in more prevalent eukaryotes, even in vertebrates. However, functional characterizations have been limited. RESULTS: We use Tetrahymena thermophila as a model organism to examine the effects of 6mA on nucleosome positioning. Independent methods reveal the enrichment of 6mA near and after transcription start sites with a periodic pattern and anti-correlation relationship with the positions of nucleosomes. The distribution pattern can be recapitulated by in vitro nucleosome assembly on native Tetrahymena genomic DNA but not on DNA without 6mA. Model DNA containing artificially installed 6mA resists nucleosome assembling compared to unmodified DNA in vitro. Computational simulation indicates that 6mA increases dsDNA rigidity, which disfavors nucleosome wrapping. Knockout of a potential 6mA methyltransferase leads to a transcriptome-wide change of gene expression. CONCLUSIONS: These findings uncover a mechanism by which DNA 6mA assists to shape the nucleosome positioning and potentially affects gene expression.

N6-adenine DNA methylation demystified in eukaryotic genome: From biology to pathology.

N6-methyl-2'-deoxyadenosine (m6dA) is a well characterized DNA modification in prokaryotes. Its existence in eukaryotic DNA remained doubtful until recently. Evidence suggests that the m6dA levels decrease with the increasing complexity of eukaryotic genomes. Analysis of m6dA levels in genome of lower eukaryotes reveals its role in gene regulation, nucleosome positioning and early development. In higher eukaryotes m6dA is enriched in nongenic region compared to genic region, preferentially in chromosome X and 13 suggesting a chromosome bias. High levels of m6dA during embryogenesis as compared to adult tissues are indicative of its importance during development and possible association with regeneration capabilities. Further, decreased levels of m6dA in diabetic patients has been correlated with expression of Fat mass and obesity-associated (FTO) which acts as m6A demethylase. m6dA levels have also been reported to be decreased in different types of cancers. The present review highlights the role of m6dA modification in eukaryotic genomes and its functional importance in regulation of physiological and pathological processes.