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Cytoplasmic stirring by active carpets.

Brato Chakrabarti1,2, Manas Rachh3, Stanislav Y Shvartsman1,4,5

  • 1Center for Computational Biology, Flatiron Institute, New York, NY 10010.

Proceedings of the National Academy of Sciences of the United States of America
|July 16, 2024
PubMed
Summary
This summary is machine-generated.

This study introduces an active carpet theory to explain self-organized cytoplasmic flows in large cells. The model reveals how fluid-structure interactions create a global vortical flow, essential for intracellular transport and cell function.

Keywords:
active matterbiophysicscytoplasmic streamingdevelopmenthydrodynamics

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Area of Science:

  • Cell Biology
  • Biophysics
  • Fluid Dynamics

Background:

  • Large cells utilize cytoplasmic flows for essential functions like transport and homeostasis.
  • Understanding these flows is crucial for cell biology, development, and evolution.
  • Cortex-based fluid-structure interactions drive self-organized cytoplasmic stirring.

Purpose of the Study:

  • To propose an analytically tractable active carpet theory for self-organized cytoplasmic flows.
  • To decipher the origins and 3D spatiotemporal organization of these flows.
  • To model fluid-structure interactions between cytoskeletal elements at the cell cortex.

Main Methods:

  • Developed an active carpet theory inspired by fruit fly oocyte streaming flows.
  • Employed computational simulations to analyze flow dynamics.
  • Utilized weakly nonlinear theory to understand flow organization.

Main Results:

  • Established the pathway of streaming flow to a global attractor: a cell-spanning vortical twister.
  • Revealed inherent symmetries and low-dimensional structure of the emergent flow.
  • Demonstrated alignment of complex fluid-structure interactions with classical Stokes flow solutions.

Conclusions:

  • The active carpet theory provides a framework for understanding cortex-driven intracellular flows.
  • The model elucidates the emergence of complex, self-organized flows from simple interactions.
  • This adaptable framework can be applied to diverse self-organized, cortex-driven intracellular flow systems.