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Nanomechanical recognition measurements of individual DNA molecules reveal epigenetic methylation patterns.

ABSTRACT: Atomic force microscopy (AFM) is a powerful tool for analysing the shapes of individual molecules and the forces acting on them. AFM-based force spectroscopy provides insights into the structural and energetic dynamics of biomolecules by probing the interactions within individual molecules, or between a surface-bound molecule and a cantilever that carries a complementary binding partner. Here, we show that an AFM cantilever with an antibody tether can measure the distances between 5-methylcytidine bases in individual DNA strands with a resolution of 4 Å, thereby revealing the DNA methylation pattern, which has an important role in the epigenetic control of gene expression. The antibody is able to bind two 5-methylcytidine bases of a surface-immobilized DNA strand, and retracting the cantilever results in a unique rupture signature reflecting the spacing between two tagged bases. This nanomechanical approach might also allow related chemical patterns to be retrieved from biopolymers at the single-molecule level.

SUBMITTER: Zhu R 

PROVIDER: S-EPMC3108878 | biostudies-literature | 2010 Nov

REPOSITORIES: biostudies-literature

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Nanomechanical recognition measurements of individual DNA molecules reveal epigenetic methylation patterns.

Zhu Rong R   Howorka Stefan S   Pröll Johannes J   Kienberger Ferry F   Preiner Johannes J   Hesse Jan J   Ebner Andreas A   Pastushenko Vassili Ph VP   Gruber Hermann J HJ   Hinterdorfer Peter P  

Nature nanotechnology 20101031 11

Atomic force microscopy (AFM) is a powerful tool for analysing the shapes of individual molecules and the forces acting on them. AFM-based force spectroscopy provides insights into the structural and energetic dynamics of biomolecules by probing the interactions within individual molecules, or between a surface-bound molecule and a cantilever that carries a complementary binding partner. Here, we show that an AFM cantilever with an antibody tether can measure the distances between 5-methylcytidi  ...[more]

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