Ken-ichi Inaishi

Publications (2)4.99 Total impact

• Article: Real-time direct observation of single-molecule DNA hydrolysis by exonuclease III.

  Hirofumi Kurita, Ken-ichi Inaishi, Ken Torii, Madoka Urisu, Michihiko Nakano, Shinji Katsura, Akira Mizuno
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  ABSTRACT: Single-molecule DNA digestion by exonuclease III, which has 3' to 5' exonuclease activity, was analyzed using a micro-channel with two-layer laminar flow. First, a DNA-bead complex was optically trapped in one layer in the absence of exonuclease III permitted the DNA to be stretched by the laminar flow. The exonuclease III reaction was initiated by moving the trapped DNA-bead complex to another layer of flow, which contained exonuclease III. As the reaction proceeded, the fluorescently-stained DNA was observed to shorten. The process was photographed; examination of the photographs showed that the DNA molecule shortened in a linear fashion with respect to the reaction time. The digestion rate obtained from the single-molecule experiment was compared to that measured from a bulk experiment and was found to be ca. 28 times higher than the bulk digestion rate.
  Journal of biomolecular structure & dynamics 05/2008; 25(5):473-80. · 4.99 Impact Factor
• Conference Proceeding: Real-time direct observation of single-molecule DNA hydrolysis by exonucleaseIII

  Hirofumi Kurita, Ken-ichi Inaishi, Ken Torii, Madoka Urisu, Michihiko Nakano, Shinji Katsura, Akira Mizuno
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  ABSTRACT: Real time direct observation of single molecule using fluorescent technique has elucidated various biological phenomena, because not only average but also distributions and fluctuations of molecules can be characterized directly by this method, on the other hand, conventional methods can observe only average behaviors of molecules. In recent years, single-molecule analyses of various DNA-protein interactions by using florescent techniques were performed. In this study, single-molecule DNA hydrolysis by exonucleaseIII was observed, which has 3' rarr 5' exonuclease activity. This single-molecule observation method was based on optical trap and two-layer laminar flow, in which mixing between the two layers was negligible. First of all, one DNA-bead complex was optically trapped in a layer without exonucleaseIII. This trapping permitted stretching of DNA by flow. ExonucleaseIII reaction was initiated by moving the trapped DNA-bead complex to another flow layer containing exonucleaseIII, then shortening of fluorescently stained DNA was observed in real time. The sequentially captured photographs demonstrate that the digested DNA molecule linearly shortened with reaction time. The digestion rate from single-molecule experiment was determined and compared to in vitro experiment. As a result, digestion rate of exonucleaseIII from single-molecule experiment was ~20 times higher than in vitro digestion rate
  Micro-NanoMechatronics and Human Science, 2006 International Symposium on; 12/2006