Biosensors (Jun 2016)

Single Molecule Bioelectronics and Their Application to Amplification-Free Measurement of DNA Lengths

  • O. Tolga Gül,
  • Kaitlin M. Pugliese,
  • Yongki Choi,
  • Patrick C. Sims,
  • Deng Pan,
  • Arith J. Rajapakse,
  • Gregory A. Weiss,
  • Philip G. Collins

DOI
https://doi.org/10.3390/bios6030029
Journal volume & issue
Vol. 6, no. 3
p. 29

Abstract

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As biosensing devices shrink smaller and smaller, they approach a scale in which single molecule electronic sensing becomes possible. Here, we review the operation of single-enzyme transistors made using single-walled carbon nanotubes. These novel hybrid devices transduce the motions and catalytic activity of a single protein into an electronic signal for real-time monitoring of the protein’s activity. Analysis of these electronic signals reveals new insights into enzyme function and proves the electronic technique to be complementary to other single-molecule methods based on fluorescence. As one example of the nanocircuit technique, we have studied the Klenow Fragment (KF) of DNA polymerase I as it catalytically processes single-stranded DNA templates. The fidelity of DNA polymerases makes them a key component in many DNA sequencing techniques, and here we demonstrate that KF nanocircuits readily resolve DNA polymerization with single-base sensitivity. Consequently, template lengths can be directly counted from electronic recordings of KF’s base-by-base activity. After measuring as few as 20 copies, the template length can be determined with <1 base pair resolution, and different template lengths can be identified and enumerated in solutions containing template mixtures.

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