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Gold rotor bead tracking for high-speed measurements of DNA twist, torque and extension
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Journal Article
Gold rotor bead tracking for high-speed measurements of DNA twist, torque and extension
2014
Overview
Single-molecule structural transitions involving DNA twisting can be measured with substantially greater spatiotemporal resolution than previously possible with a gold rotor bead tracking (AuRBT) method. This approach uses magnetic tweezers and evanescent darkfield microscopy to track a gold nanoparticle probe attached to a DNA molecule.
Single-molecule measurements of DNA twist and extension have been used to reveal physical properties of the double helix and to characterize structural dynamics and mechanochemistry in nucleoprotein complexes. However, the spatiotemporal resolution of twist measurements has been limited by the use of angular probes with high rotational drag, which prevents detection of short-lived intermediates or small angular steps. We introduce gold rotor bead tracking (AuRBT), which yields >100× improvement in time resolution over previous techniques. AuRBT employs gold nanoparticles as bright low-drag rotational and extensional probes, which are monitored by instrumentation that combines magnetic tweezers with objective-side evanescent darkfield microscopy. Our analysis of high-speed structural dynamics of DNA gyrase using AuRBT revealed an unanticipated transient intermediate. AuRBT also enables direct measurements of DNA torque with >50× shorter integration times than previous techniques; we demonstrated high-resolution torque spectroscopy by mapping the conformational landscape of a Z-forming DNA sequence.
Publisher
Nature Publishing Group US,Nature Publishing Group
Subject
