Waves of DNA: Propagating excitations in extended nanoconfined polymers

Author(s)

de Haan, Hendrick W.; Reisner, Walter W.; Klotz, Alexander

Abstract

We use a nanofluidic system to investigate the emergence of thermally driven collective phenomena along a single polymer chain. In our approach, a single DNA molecule is confined in a nanofluidic slit etched with arrays of embedded nanocavities; the cavity lattice is designed so that a single chain occupies multiple cavities. Fluorescent video-microscopy data shows fluctuations in intensity between cavities, including waves of excess fluorescence that propagate across the cavity-straddling molecule, corresponding to propagating fluctuations of contour overdensity in the cavities. The transfer of DNA between neighboring pits is quantified by examining the correlation in intensity fluctuations between neighboring cavities. Correlations grow from an anticorrelated minimum to a correlated maximum before decaying, corresponding to a transfer of contour between neighboring cavities at a fixed transfer time scale. The observed dynamics can be modeled using Langevin dynamics simulations and a minimal lattice model of coupled diffusion. This study shows how confinement-based sculpting of the polymer equilibrium configuration, by renormalizing the physical system into a series of discrete cavity states, can lead to new types of dynamic collective phenomena.

Date issued

2016-10

URI

http://hdl.handle.net/1721.1/105191

Department

Massachusetts Institute of Technology. Department of Chemical Engineering

Journal

Physical Review E

Publisher

American Physical Society

Citation

Klotz, Alexander R., Hendrick W. de Haan, and Walter W. Reisner. “Waves of DNA: Propagating Excitations in Extended Nanoconfined Polymers.” Physical Review E 94.4 (2016): n. pag. © 2016 American Physical Society

Version: Final published version

ISSN

2470-0045

2470-0053