The present invention relates to the field of pharmacogenomics and in particular to detecting the presence or absence of hypermethylated DNA. The detection of CpG methylation in marker DNA is useful for the diagnosis of cancers and the invention provides improved methods for this purpose. These improved methods allow in particular for a more sensitive detection of methylated marker DNA with high backgrounds of unmethylated marker DNA.

Methods of determining methylation of DNA are provided. In one illustrative, but non-limiting embodiment the method comprises i) contacting a biological sample comprising a nucleic acid to a first matrix material comprising a first column or filter where said matrix material binds and/or filters nucleic acids in said sample and thereby purifies the DNA; ii) eluting the bound DNA from the first matrix material and denaturing the DNA to produce eluted denatured DNA; iii) heating the eluted DNA in the presence of bisulfite ions to produce a deaminated nucleic acid; iv) contacting said deaminated nucleic acid to a second matrix material comprising a second column to bind said deaminated nucleic acid to said second matrix material; v) desulphonating the bound deaminated nucleic acid and/or simultaneously eluting and desulphonating the nucleic acid by contacting the deaminated nucleic acid with an alkaline solution to produce a bisulfite converted nucleic acid; vi) eluting said bisulfite converted nucleic acid from said second matrix material; and vii) performing methylation specific PCR and/or nucleic acid sequencing, and/or high resolution melting analysis (HRM) on said bisulfite-converted nucleic acid to determine the methylation of said nucleic acid, wherein at least steps iv) through vi) are performed in a single reaction cartridge.

The present invention provides for novel methods for regulating and detecting the cytosine methylation status of DNA. The invention is based upon identification of a novel and surprising catalytic activity for the family of TET proteins, namely TET1, TET2, TET3, and CXXC4. The novel activity is related to the enzymes being capable of converting the cytosine nucleotide 5-methylcytosine into 5-hydroxymethylcytosine by hydroxylation.

The present invention provides for novel methods for regulating and detecting the cytosine methylation status of DNA. The invention is based upon identification of a novel and surprising catalytic activity for the family of TET proteins, namely TET1, TET2, TET3, and CXXC4. The novel activity is related to the enzymes being capable of converting the cytosine nucleotide 5-methylcytosine into 5-hydroxymethylcytosine by hydroxylation.

Provided are compositions and processes that utilize genomic regions that are differentially methylated between a mother and her fetus to separate, isolate or enrich fetal nucleic acid from a maternal sample. The compositions and processes described herein are particularly useful for non-invasive prenatal diagnostics, including the detection of chromosomal aneuploidies.

Provided are compositions and processes that utilize genomic regions that are differentially methylated between a mother and her fetus to separate, isolate or enrich fetal nucleic acid from a maternal sample. The compositions and processes described herein are particularly useful for non-invasive prenatal diagnostics, including the detection of chromosomal aneuploidies.

The RNA molecule of the present invention, which is based on a helix 73-derived RNA substrate and Erm interaction sites, may be used for screening candidate substances that inhibit methylation by Erm, developing variants thereof, and identifying the action mechanism, and may be used for suppressing the expression of antibiotic resistance.

The RNA molecule of the present invention, which is based on a helix 73-derived RNA substrate and Erm interaction sites, may be used for screening candidate substances that inhibit methylation by Erm, developing variants thereof, and identifying the action mechanism, and may be used for suppressing the expression of antibiotic resistance.

Provided herein is a method for analyzing genomic DNA. In some embodiments, the method may comprise labeling a genomic sample by adding a capture tag to the ends of the DNA molecules in the sample and labeling molecules that comprise hydroxymethylcytosine with a first fluorophore, immobilizing the labeled DNA molecules on a support, and imaging individual molecules of hydroxymethylated genomic DNA on the support.

Provided herein is a method for analyzing genomic DNA. In some embodiments, the method may comprise labeling a genomic sample by adding a capture tag to the ends of the DNA molecules in the sample and labeling molecules that comprise hydroxymethylcytosine with a first fluorophore, immobilizing the labeled DNA molecules on a support, and imaging individual molecules of hydroxymethylated genomic DNA on the support.