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Rotation tracking of genome-processing enzymes using DNA origami rotors

Author

Listed:
  • Pallav Kosuri

    (Harvard University
    Harvard University
    Harvard University)

  • Benjamin D. Altheimer

    (Harvard University
    Harvard University
    Harvard University
    Harvard University)

  • Mingjie Dai

    (Harvard University
    Harvard Medical School
    Harvard Medical School)

  • Peng Yin

    (Harvard Medical School
    Harvard Medical School)

  • Xiaowei Zhuang

    (Harvard University
    Harvard University
    Harvard University)

Abstract

Many genome-processing reactions, including transcription, replication and repair, generate DNA rotation. Methods that directly measure DNA rotation, such as rotor bead tracking1–3, angular optical trapping4 and magnetic tweezers5, have helped to unravel the action mechanisms of a range of genome-processing enzymes that includes RNA polymerase (RNAP)6, gyrase2, a viral DNA packaging motor7 and DNA recombination enzymes8. Despite the potential of rotation measurements to transform our understanding of genome-processing reactions, measuring DNA rotation remains a difficult task. The time resolution of existing methods is insufficient for tracking the rotation induced by many enzymes under physiological conditions, and the measurement throughput is typically low. Here we introduce origami-rotor-based imaging and tracking (ORBIT), a method that uses fluorescently labelled DNA origami rotors to track DNA rotation at the single-molecule level with a time resolution of milliseconds. We used ORBIT to track the DNA rotations that result from unwinding by the RecBCD complex, a helicase that is involved in DNA repair9, as well as from transcription by RNAP. We characterized a series of events that occur during RecBCD-induced DNA unwinding—including initiation, processive translocation, pausing and backtracking—and revealed an initiation mechanism that involves reversible ATP-independent DNA unwinding and engagement of the RecB motor. During transcription by RNAP, we directly observed rotational steps that correspond to the unwinding of single base pairs. We envisage that ORBIT will enable studies of a wide range of interactions between proteins and DNA.

Suggested Citation

  • Pallav Kosuri & Benjamin D. Altheimer & Mingjie Dai & Peng Yin & Xiaowei Zhuang, 2019. "Rotation tracking of genome-processing enzymes using DNA origami rotors," Nature, Nature, vol. 572(7767), pages 136-140, August.
  • Handle: RePEc:nat:nature:v:572:y:2019:i:7767:d:10.1038_s41586-019-1397-7
    DOI: 10.1038/s41586-019-1397-7
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    Cited by:

    1. Xiaoming Liu & Fengyu Liu & Hemani Chhabra & Christopher Maffeo & Zhuo Chen & Qiang Huang & Aleksei Aksimentiev & Tatsuo Arai, 2024. "A lumen-tunable triangular DNA nanopore for molecular sensing and cross-membrane transport," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    2. Vishal Maingi & Zhao Zhang & Chris Thachuk & Namita Sarraf & Edwin R. Chapman & Paul W. K. Rothemund, 2023. "Digital nanoreactors to control absolute stoichiometry and spatiotemporal behavior of DNA receptors within lipid bilayers," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    3. Jae Young Lee & Heeyuen Koh & Do-Nyun Kim, 2023. "A computational model for structural dynamics and reconfiguration of DNA assemblies," Nature Communications, Nature, vol. 14(1), pages 1-12, December.

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