Chemoenzymatic labeling of DNA methylation patterns for single-molecule epigenetic mapping.

DNA methylation, specifically, methylation of cytosine (C) nucleotides at the 5-carbon position (5-mC), is the most studied and significant epigenetic modification. Here we developed a chemoenzymatic procedure to fluorescently label non-methylated cytosines in CpG context, allowing epigenetic profiling of single DNA molecules spanning hundreds of thousands of base pairs. We used a CpG methyltransferase with a synthetic S-adenosyl-l-methionine cofactor analog to transfer an azide to cytosines instead of the natural methyl group.

Long-read single-molecule maps of the functional methylome.

We report on the development of a methylation analysis workflow for optical detection of fluorescent methylation profiles along chromosomal DNA molecules. In combination with Bionano Genomics genome mapping technology, these profiles provide a hybrid genetic/epigenetic genome-wide map composed of DNA molecules spanning hundreds of kilobase pairs. The method provides kilobase pair-scale genomic methylation patterns comparable to whole-genome bisulfite sequencing (WGBS) along genes and regulatory elements.

Ionic Current-Based Mapping of Short Sequence Motifs in Single DNA Molecules Using Solid-State Nanopores.

Nanopore sensors show great potential for rapid, single-molecule determination of DNA sequence information. Here, we develop an ionic current-based method for determining the positions of short sequence motifs in double-stranded DNA molecules with solid-state nanopores. Using the DNA-methyltransferase M.

The N6-Position of Adenine Is a Blind Spot for TAL-Effectors That Enables Effective Binding of Methylated and Fluorophore-Labeled DNA.

Transcription-activator-like effectors (TALEs) are programmable DNA binding proteins widely used for genome targeting. TALEs consist of multiple concatenated repeats, each selectively recognizing one nucleobase via a defined repeat variable diresidue (RVD). Effective use of TALEs requires knowledge about their binding ability to epigenetic and other modified nucleobases occurring in target DNA.

Light-Enhancing Plasmonic-Nanopore Biosensor for Superior Single-Molecule Detection.

A stacked plasmonic nanowell-nanopore biosensor strongly suppresses the background fluorescence from the bulk and yields net more than tenfold enhancement of the fluorescence intensity. The device offers extremely high signal-to-background (S/B) ratio for single-molecule detection at ultralow excitation laser intensities, while maintaining extremely high temporal bandwidth for single-DNA sensing.

Single-Molecule DNA Methylation Quantification Using Electro-optical Sensing in Solid-State Nanopores.

Detection of epigenetic markers, including 5-methylcytosine, is crucial due to their role in gene expression regulation and due to the mounting evidence of aberrant DNA methylation patterns in cancer biogenesis. Single-molecule methods to date have primarily been focused on hypermethylation detection; however, many oncogenes are hypomethylated during cancer development, presenting an important unmet biosensing challenge. To this end, we have developed a labeling and single-molecule quantification method for multiple unmethylated cytosine-guanine dinucleotides (CpGs).

Sequence-specific labeling of nucleic acids and proteins with methyltransferases and cofactor analogues.

S-Adenosyl-l-methionine (AdoMet or SAM)-dependent methyltransferases (MTase) catalyze the transfer of the activated methyl group from AdoMet to specific positions in DNA, RNA, proteins and small biomolecules. This natural methylation reaction can be expanded to a wide variety of alkylation reactions using synthetic cofactor analogues. Replacement of the reactive sulfonium center of AdoMet with an aziridine ring leads to cofactors which can be coupled with DNA by various DNA MTases.