Manipulating Biopolymer Dynamics by Anisotropic Nanoconfinement

Alexander P.; Barchi J. J.; Baumketner A.; Bernier V.; Betancourt M. R.; Bolis D.; Brinker A.; Brunet E.; Bryngelson J. D.; Campanini B.; Chen N. Y.; Cheung M. S.; Cheung M. S.; Cheung M. S.; Cohen F. E.; Eggers D. K.; Ellis R. J.; Galas D. J.; Gronenborn A. M.; Gu L.; Guo Z.; Gō N.; Hubner I. A.; Humphrey W.; Idiyatullin D.; Jewett A. I.; Karanicolas J.; Klimov D. K.; Klimov D. K.; Klimov D. K.; Leopold P. E.; Lucent D.; Mathe J.; McCallister E. L.; Minton A. P.; Movileanu L.; Nissen P.; Onuchic J. N.; Park S.-H.; Park S.-H.; Peterson R. W.; Ping G.; Pioselli B.; Quiocho F. A.; Rathore N.; Seewald M. J.; Selenko P.; Sheinerman F. B.; Shimada J.; Simpson A. A.; Sorenson J. M.; Sotiropoulou S.; Takagi F.; Tang Y.-C.; Uetz P.; Wei Y.; Zhou H.-X.; Zhou H.-X.

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Manipulating Biopolymer Dynamics by Anisotropic Nanoconfinement

Abstract

How the geometry of nano-sized confinement affects dynamics of biomaterials is interesting yet poorly understood. An elucidation of structural details upon nano-sized confinement may benefit manufacturing pharmaceuticals in biomaterial sciences and medicine. The behavior of biopolymers in nano-sized confinement is investigated using coarse-grained models and molecular simulations. Particularly, we address the effects of shapes of a confinement on protein folding dynamics by measuring folding rates and dissecting structural properties of the transition states in nano-sized spheres and ellipsoids. We find that when the form of a confinement resembles the geometrical properties of the transition states, the rates of folding kinetics are most enhanced. This knowledge of shape selectivity in identifying optimal conditions for reactions will have a broad impact in nanotechnology and pharmaceutical sciences.Comment: to appear in Nano Letter

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Last time updated on 26/02/2019