Modified DNA bases are widespread in biology. 5-Methylcytosine (mC) is a predominant epigenetic marker in higher eukaryotes involved in gene regulation, development, aging, cancer, and disease. Recently, 5-hydroxymethylcytosine (hmC) was identified in mammalian brain tissue and stem cells. However, most of the currently available assays cannot distinguish mC from hmC in DNA fragments. We investigate here the physical properties of DNA with modified cytosines, in efforts to develop a physical tool that distinguishes mC from hmC in DNA fragments. Molecular dynamics simulations reveal that polar cytosine modifications affect internal base pair dynamics, while experimental evidence suggest a correlation between the modified cytosine’s polarity, DNA flexibility, and duplex stability. Based on these physical differences, solid-state nanopores can rapidly discriminate among DNA fragments with mC or hmC modification by sampling a few hundred molecules in the solution. Further, the relative proportion of hmC in the sample can be determined from the electronic signature of the intact DNA fragment.
MspJI is a novel modification-dependent restriction endonuclease that cleaves at a fixed distance away from the modification site. Here, we present the biochemical characterization of several MspJI homologs, including FspEI, LpnPI, AspBHI, RlaI, and SgrTI. All of the enzymes specifically recognize cytosine C5 modification (methylation or hydroxymethylation) in DNA and cleave at a constant distance (N 12 ∕N 16 ) away from the modified cytosine. Each displays its own sequence context preference, favoring different nucleotides flanking the modified cytosine. By cleaving on both sides of fully modified CpG sites, they allow the extraction of 32-base long fragments around the modified sites from the genomic DNA. These enzymes provide powerful tools for direct interrogation of the epigenome. For example, we show that RlaI, an enzyme that prefers m CWG but not m CpG sites, generates digestion patterns that differ between plant and mammalian genomic DNA, highlighting the difference between their epigenomic patterns. In addition, we demonstrate that deep sequencing of the digested DNA fragments generated from these enzymes provides a feasible method to map the modified sites in the genome. Altogether, the MspJI family of enzymes represent appealing tools of choice for method development in DNA epigenetic studies. 5-methylcytosine | methylomeM odified DNA bases appear in genomic DNAs in all domains of life, spanning the evolutionary distance from viruses to eukaryotic species. DNA base modifications vary in form and genomic location enriching the information content encoded by genomes. The biological role of base modifications varies, ranging from protection against restriction endonucleases in bacteria and bacteriophages to transcriptional regulation in mammals. In prokaryotes, DNA methyltransferases in restriction-modification systems modify the host genomic DNA, so that restriction endonucleases can target foreign DNA and protect the host cell from invaders (1). However, a few bacteriophages respond by incorporating modified bases into their genomes as a way to block restriction endonuclease cleavage (2). For example, in Xanthomonas oryzae phage XP12, all cytosines exist in the form of 5-methylcytosine (5mC) (3). Another example is the well-studied T4 phage, in which 5-hydroxymethylcytosine (5hmC) is incorporated into the DNA during replication and additional glucosyltransferases further modify all 5hmC to glucosylated-hydroxymethylcytosine (5ghmC). T4 genomic DNA containing 5ghmC is resistant to cleavage by most restriction endonucleases, with the exception of Type IV modification-dependent endonucleases (4, 5).Several different types of modification-dependent endonucleases are found in prokaryotes. For example, N6-adenosine methylation is recognized by a few known enzymes, e.g., DpnI (G m ATC). A group of sequence-specific cytosine methylationdependent restriction endonucleases including GlaI (G m CG m C), BisI (G m CNGC), etc., have been reported recently, which cleave within the recognition site in a Type IIP-like ...
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