The present disclosure relates to methodology for fast and cost-effective identification of the source of DNA samples. DNA samples obtained from unknown or unrecognized tissues or cell types are analyzed according to the methodology described herein, yielding an identification of the tissue and/or cell type source. Identification is based on sequential biochemical procedures including methylation sensitive/dependent restriction and polymerase chain reaction, followed by analysis of the data. All biochemical steps are performed in a single test tube. The disclosure has immediate applications in forensic science for identification of the tissue source of DNA obtained from biological stains. The disclosure also has immediate applications in cancer diagnosis for identification.

Methods are provided for determining the methylation status of GC-rich templates. The methods include use of GC reference standards that allow simultaneous characterization of methylation status and CGG repeat length. The methods are useful for detecting genotypes associated with GC-rich repeats, including Fragile X Syndrome.

Methods are provided for determining the methylation status of GC-rich templates. The methods include use of GC reference standards that allow simultaneous characterization of methylation status and CGG repeat length. The methods are useful for detecting genotypes associated with GC-rich repeats, including Fragile X Syndrome.

The presently disclosed subject matter provides high-throughput methods for performing genomic DNA methylation assessments. The presently disclosed subject matter further provides methods for diagnosing a subject with a disease and/or disorder, and for determining the prognosis of a subject that has a disease and/or disorder. In certain embodiments, the present disclosure provides a diagnostic method that includes obtaining a biological sample from the subject; determining the methylation status of one or more genomic DNA loci in one or more cells of the biological sample; and diagnosing a disease and/or disorder in the subject, wherein the methylation status of the one or more genomic DNA loci indicates the presence of the disease and/or disorder in the subject.

Provided herein are methods for identifying sites and regions within a gene or genome that are amenable to analysis of methylation. The methods disclosed herein allow the efficient identification on a genome-wide scale of target restriction sites and fragments that provide targets for subsequent analysis.

Provided herein are methods for identifying sites and regions within a gene or genome that are amenable to analysis of methylation. The methods disclosed herein allow the efficient identification on a genome-wide scale of target restriction sites and fragments that provide targets for subsequent analysis.

Described herein are methods, compositions and kits for the generation of bisulfite-converted libraries useful for conducting reduced representation bisulfite sequencing (RRBS). The methods described herein can be employed to generate RRBS libraries in a manner that is easier and more cost-efficient than conventional RRBS methods, and can be efficiently sequenced with next generation sequencing (NGS) techniques without the need for genomic, higher diversity sequencing controls such as PhiX spike-ins.

Described herein are methods, compositions and kits for the generation of bisulfite-converted libraries useful for conducting reduced representation bisulfite sequencing (RRBS). The methods described herein can be employed to generate RRBS libraries in a manner that is easier and more cost-efficient than conventional RRBS methods, and can be efficiently sequenced with next generation sequencing (NGS) techniques without the need for genomic, higher diversity sequencing controls such as PhiX spike-ins.

Methods and kits for detecting the presence of at least one target DNA sequence with or without a modification in a DNA molecule are provided.

Methods and kits for detecting the presence of at least one target DNA sequence with or without a modification in a DNA molecule are provided.