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Actin Polymerization and Cell Motility01:13

Actin Polymerization and Cell Motility

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Actin is a family of globular proteins that are highly abundant in eukaryotic cells. It makes up approximately 1-5% of total cell protein concentration. Actin monomers polymerize to form a complex network of polarized filaments, the actin cytoskeleton, that plays a crucial role in many cellular processes, including cell motility, division, endocytosis, and metastasis of cancer cells.
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Cells migrating in response to external stimuli form lamellipodia, which are thin membrane protrusions supported by a mesh of linked, branched, or unbranched actin filaments. These actin filaments interact with myosin motor proteins, creating the dynamic actomyosin complex within the cytoskeleton. Contractility, or the ability to generate contractile stress, is inherent to the actomyosin complex. It helps cells detect the stiffness of the surrounding ECM and exert contractile force for...
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Mechanisms of Membrane-bending01:15

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The living membranes are flexible due to their fluid mosaic nature; however, their bending into different shapes is an active process regulated by specific lipids and proteins. The membrane bending can be transient as seen in vesicles or stable for a long time as in microvilli. Cells regulate the size, location, and duration of the membrane curvature.
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Membrane Domains01:18

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The membrane domains concentrate specific lipids and proteins at one place within the membrane, which helps in cell signaling, adhesion, and other critical cellular processes. These domains can differ in size, composition, function, and lifespan.
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Mechanisms of Membrane Domain Formation00:59

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Different physical properties of lipids and proteins allow them to localize and form distinct islands or domains in the membrane. Some membrane domains are formed due to protein-protein interactions, whereas others are formed due to the presence of specific lipids such as sphingolipids and sterols—for example, large proteins, such as bacteriorhodopsin, aggregate and create distinct domains.
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Filopodia are thin, actin-rich cellular protrusions that play an important role in many fundamental cellular functions. They vary in their occurrence, length, and positioning in different cell types, suggesting their diverse roles.
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Related Experiment Video

Updated: Jun 5, 2025

In Vitro Reconstitution of the Actin Cytoskeleton Inside Giant Unilamellar Vesicles
10:19

In Vitro Reconstitution of the Actin Cytoskeleton Inside Giant Unilamellar Vesicles

Published on: August 25, 2022

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Lipid Membrane Domains Control Actin Network Viscoelasticity.

Daniel P Arnold1, Sho C Takatori1

  • 1Department of Chemical Engineering, University of California, Santa Barbara, Santa Barbara, California 93106, United States.

Langmuir : the ACS Journal of Surfaces and Colloids
|December 4, 2024
PubMed
Summary

Researchers engineered 2D lipid membranes within actin networks, observing unique triangular shapes and accelerated relaxation. This work offers insights into cell membrane mechanics and potential applications for advanced materials.

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Reconstitution of Membrane-Tethered Minimal Actin Cortices on Supported Lipid Bilayers
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The Mechanics of Poro-Elastic Contractile Actomyosin Networks As a Model System of the Cell Cytoskeleton
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Related Experiment Videos

Last Updated: Jun 5, 2025

In Vitro Reconstitution of the Actin Cytoskeleton Inside Giant Unilamellar Vesicles
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Reconstitution of Membrane-Tethered Minimal Actin Cortices on Supported Lipid Bilayers
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The Mechanics of Poro-Elastic Contractile Actomyosin Networks As a Model System of the Cell Cytoskeleton
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Area of Science:

  • Biophysics
  • Materials Science
  • Cell Biology

Background:

  • Cell membranes feature protein and lipid condensates interacting with cytoskeleton networks.
  • The interplay between viscoelastic networks and 2D lipid phase separation is not well understood.

Purpose of the Study:

  • To engineer composite materials of 2D lipid condensates in viscoelastic actin networks.
  • To investigate the mechanical and thermodynamic interactions between these components.

Main Methods:

  • Engineered 2D lipid membrane condensates within a thin viscoelastic actin network.
  • Applied localized anisotropic stresses to deform lipid condensates.
  • Manipulated membrane composition to control viscoelastic properties.

Main Results:

  • Observed lipid condensates deforming into unique triangular shapes with sharp edges.
  • Found that lipid condensate coarsening accelerates network viscoelastic relaxation.
  • Demonstrated control over the elastic-to-viscous crossover of the composite membrane.

Conclusions:

  • Viscoelastic networks induce novel morphologies in 2D lipid condensates.
  • Lipid phase separation dynamics influence composite material viscoelasticity.
  • Engineered membranes offer potential for tunable coatings and interfaces.