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DNA origami-based shape IDs for single-molecule nanomechanical genotyping.


ABSTRACT: Variations on DNA sequences profoundly affect how we develop diseases and respond to pathogens and drugs. Atomic force microscopy (AFM) provides a nanomechanical imaging approach for genetic analysis with nanometre resolution. However, unlike fluorescence imaging that has wavelength-specific fluorophores, the lack of shape-specific labels largely hampers widespread applications of AFM imaging. Here we report the development of a set of differentially shaped, highly hybridizable self-assembled DNA origami nanostructures serving as shape IDs for magnified nanomechanical imaging of single-nucleotide polymorphisms. Using these origami shape IDs, we directly genotype single molecules of human genomic DNA with an ultrahigh resolution of ?10?nm and the multiplexing ability. Further, we determine three types of disease-associated, long-range haplotypes in samples from the Han Chinese population. Single-molecule analysis allows robust haplotyping even for samples with low labelling efficiency. We expect this generic shape ID-based nanomechanical approach to hold great potential in genetic analysis at the single-molecule level.

SUBMITTER: Zhang H 

PROVIDER: S-EPMC5384221 | biostudies-literature | 2017 Apr

REPOSITORIES: biostudies-literature

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DNA origami-based shape IDs for single-molecule nanomechanical genotyping.

Zhang Honglu H   Chao Jie J   Pan Dun D   Liu Huajie H   Qiang Yu Y   Liu Ke K   Cui Chengjun C   Chen Jianhua J   Huang Qing Q   Hu Jun J   Wang Lianhui L   Huang Wei W   Shi Yongyong Y   Fan Chunhai C  

Nature communications 20170406


Variations on DNA sequences profoundly affect how we develop diseases and respond to pathogens and drugs. Atomic force microscopy (AFM) provides a nanomechanical imaging approach for genetic analysis with nanometre resolution. However, unlike fluorescence imaging that has wavelength-specific fluorophores, the lack of shape-specific labels largely hampers widespread applications of AFM imaging. Here we report the development of a set of differentially shaped, highly hybridizable self-assembled DN  ...[more]

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