Open AccessEnergetically Biased DNA Motor Containing a Thermodynamically Stable Partial Strand Displacement State
Author(s) -
Preston B. Landon,
Joon Lee,
Michael Taeyoung Hwang,
Alexander H. Mo,
Chen Zhang,
Anthony Neuberger,
Brian Meckes,
Jose J. Gutierrez,
Gennadi V. Glinsky,
Ratnesh Lal
Publication year - 2014
Publication title -
langmuir
Language(s) - Uncategorized
Resource type - Journals
SCImago Journal Rank - 1.042
H-Index - 333
eISSN - 1520-5827
pISSN - 0743-7463
DOI - 10.1021/la503711g
Subject(s) - kinetics , dna , displacement (psychology) , work (physics) , inosine , a dna , nucleotide , chemistry , chemical physics , biophysics , biological system , materials science , nanotechnology , thermodynamics , physics , biology , biochemistry , classical mechanics , psychology , enzyme , gene , psychotherapist
Current work in tuning DNA kinetics has focused on changing toehold lengths and DNA concentrations. However, kinetics can also be improved by enhancing the completion probability of the strand displacement process. Here, we execute this strategy by creating a toehold DNA motor device with the inclusion of a synthetic nucleotide, inosine, at selected sites. Furthermore, we found that the energetic bias can be tuned such that the device can stay in a stable partially displaced state. This work demonstrates the utility of energetic biases to change DNA strand displacement kinetics and introduces a complementary strategy to the existing designs.
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