Cycling State that Can Lead to Glassy Dynamics in Intracellular Transport

M Scholz, S Burov, K. L Weirich, B. J Scholz, S. A Tabei, M. L Gardel, A. R Dinner

Research output: Contribution to conferencePaperpeer-review

Abstract

Power-law dwell times have been observed for molecular motors in living cells, but the origins of these trapped states are not known. We introduce a minimal model of motors moving on a two-dimensional network of filaments, and simulations of its dynamics exhibit statistics comparable to those observed experimentally. Analysis of the model trajectories, as well as experimental particle tracking data, reveals a state in which motors cycle unproductively at junctions of three or more filaments. We formulate a master equation for these junction dynamics and show that the time required to escape from this vortexlike state can account for the power-law dwell times. We identify trends in the dynamics with the motor valency for further experimental validation. We demonstrate that these trends exist in individual trajectories of myosin II on an actin network. We discuss how cells could regulate intracellular transport and, in turn, biological function by controlling their cytoskeletal network structures locally.
Original languageEnglish
StatePublished - 2015
EventStochastic Modeling of Anomalous Dynamics in Complex Physical and Biological Systems - Wroclaw University of Technology, Wroclaw, Poland
Duration: 14 May 201516 May 2015

Conference

ConferenceStochastic Modeling of Anomalous Dynamics in Complex Physical and Biological Systems
Country/TerritoryPoland
CityWroclaw
Period14/05/1516/05/15

Fingerprint

Dive into the research topics of 'Cycling State that Can Lead to Glassy Dynamics in Intracellular Transport'. Together they form a unique fingerprint.

Cite this