A DNA methylation fingerprint of 1,628 human samples.
Fernandez AF, Assenov Y, Martin-Subero J, Balint B, Siebert R, Taniguchi H, Yamamoto H, Hidalgo M, Tan AC, Galm O, Ferrer I, Sanchez-Cespedes M, Villanueva A, Carmona J, Sanchez-Mut JV, Berdasco M, Moreno V, Capella G, Monk D, Ballestar E, Ropero S, Martinez R, Sanchez-Carbayo M, Prosper F, Agirre X, Fraga MF, Graña O, Perez-Jurado L, Mora J, Puig S, Prat J, Badimon L, Puca AA, Meltzer SJ, Lengauer T, Bridgewater J, Bock C, Esteller M.
Source
Cancer Epigenetics and Biology Program (PEBC);
Abstract
DNA methylation is the best characterized of the different layers that make up the epigenetic setting. Most of the studies characterizing DNA methylation patterns have been restricted to particular genomic loci in a limited number of human samples and pathological conditions. The recently arrived single-base-resolution technologies for DNA methylation are extremely helpful tools, but are not yet applicable and affordable for studying large groups of subjects. Herein, we present a compromise between an extremely comprehensive study of a human sample population with an intermediate level of resolution of CpGs at the genomic level. We obtained a DNA methylation fingerprint of 1,628 human samples where we interrogated 1,505 CpG sites. The DNA methylation patterns revealed show this epigenetic mark to be critical in tissue-type definition and stemness, particularly around transcription start sites that are not within a CpG island. For disease, the generated DNA methylation fingerprints show that, during tumorigenesis, human cancer cells underwent a progressive gain of promoter CpG island hypermethylation and a loss of CpG methylation in non-CpG island promoters. Although transformed cells are those where DNA methylation disruption is more obvious, we observed that other common human diseases, such as neurological and autoimmune disorders, had their own distinct DNA methylation profiles. Most importantly, we provide proof of principle that the obtained DNA methylation fingerprints might be useful for translational purposes by showing that are able to identify the tumor type origin of Cancers of Unknown Primary (CUPs). Thus, the DNA methylation patterns identified across the largest spectrum of samples, tissues and diseases reported to date constitute a baseline for developing higher-resolution DNA methylation maps, and provide important clues concerning the contribution of CpG methylation to tissue identity and its changes in the most prevalent human diseases.
PMID:21613409[PubMed - as supplied by publisher]
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A DNA methylation fingerprint of 1,628 human sampl... [Genome Res. 2011] - PubMed result
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