Collective dynamics of microtubule-based 3D active fluids from single microtubules
Teagan E. Bate, Edward J. Jarvis, Megan E. Varney, Kun-Ta Wu

TL;DR
This study investigates how microscopic microtubule dynamics influence macroscopic active fluid flows, revealing the roles of motor processivity, temperature, and depletants in controlling fluid behavior and response times.
Contribution
It provides a detailed comparison between single microtubule motion and 3D active fluid flows, highlighting the impact of motor processivity and temperature on collective dynamics.
Findings
Motor processivity affects active fluid flows near motionless states.
Active fluid flow speed increases with temperature but can be reversed by depletants.
Active fluids respond rapidly (<10 sec) to temperature changes, enabling quick control.
Abstract
Self-organization of kinesin-driven, microtubule-based 3D active fluids relies on the collective dynamics of single microtubules. However, the connection between macroscopic fluid flows and microscopic motion of microtubules remains unclear. In this work, the motion of single microtubules was characterized by means of 2D gliding assays and compared with the flows of 3D active fluids. While the scales of the two systems differ by 1,000x, both were driven by processive, non-processive or an equal mixture of both molecular motor proteins. To search for the dynamic correlation between both systems, the motor activities were tuned by varying temperature and ATP concentration, and the changes in both systems were compared. Motor processivity played an important role in active fluid flows but only when the fluids were nearly motionless; otherwise, flows were dominated by hydrodynamic…
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Taxonomy
TopicsMicro and Nano Robotics · Microtubule and mitosis dynamics · Advanced Materials and Mechanics
