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Related Concept Videos

Actin Filament Depolymerization01:19

Actin Filament Depolymerization

Actin filaments (F-actin) are composed of actin subunits. The dissociation of actin monomers can occur from either end of F-actin. The rate of dissociation is faster from the minus-end or the pointed end, where the actin subunits exist with a bound ADP, together known as ADP-actin. The depolymerization of F-actin is aided by proteins, including the actin-depolymerizing factor (ADF) and cofilin family of proteins, gelsolin, and glia maturation factor (GMF).
In F-actin, the ADF/cofilin proteins...
Actin Polymerization01:42

Actin Polymerization

Actin polymerization occurs through the head-to-tail association of binding sites on monomeric actin or G-actin to form filamentous or F-actin. The polymerization can be divided into three phases ̶  nucleation, elongation, and steady-state phase.
The nucleation phase involves forming a stable nucleus consisting of three actin monomers to form a new actin filament. Actin-binding proteins such as formins and Arp2/3 complex help filament growth post-nucleation. The Formins form straight actin...
The Role of Actin and Myosin in Non-muscle Cells01:10

The Role of Actin and Myosin in Non-muscle Cells

Actin and myosin or actomyosin filaments also play a significant role in cells other than those involved in muscle contraction (which occurs within the sarcomere of muscle cells). The mechanism of non-muscle cell contractile bundles was first observed in Dictyostelium and Acanthamoeba. In non-muscle cells, two bundles are commonly found: stress fibers and actomyosin adherence belts. These contractile bundles are smaller and less organized than the ones found in muscle cells. They  are held...
Introduction to Actin01:26

Introduction to Actin

Actin is a highly conserved cytoskeletal protein found abundantly in eukaryotic cells. It constitutes 10% weight of the total cellular protein in muscle cells, while in non-muscle cells, it is lower and makes up around 1–5 percent of the total cell protein. Actin found in the unicellular amoebae and complex multicellular animals is around 80% similar, demonstrating their conservation over a billion years of evolution.  Actin coding genes are conserved within species and across different species.
Formation of Higher-order Actin Filaments01:11

Formation of Higher-order Actin Filaments

The polymerization of G-actin monomers into filamentous F-actin is a multi-step process. Once the F-actins are formed, they can bundle together in different arrangements to form higher-order networks and regulate cellular functions. Common examples include the formation of lamellipodia and filopodia at the cell's leading edge by actin reorganization in a migrating cell. The microvilli on the brush border epithelial cells are also formed through the F-actin network.
The high-order actin networks...
Generation of Straight or Branched Actin Filaments01:14

Generation of Straight or Branched Actin Filaments

The straight or branched structure formation of actin filaments is controlled by nucleating proteins such as the formins and Arp2/3 complex. Formin-mediated assembly results in straight filaments, whereas Arp2/3 protein complex-mediated assembly results in branched actin filaments.
Arp2/3 Complex
Arp2/3 complex is a seven-subunit complex consisting of two proteins similar to actin- Arp2 and Arp3, and five other subunits that help keep Arp2 and Arp3 inactive. When required, the complex is...

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Related Experiment Video

Updated: Jun 23, 2026

Actin Co-Sedimentation Assay; for the Analysis of Protein Binding to F-Actin
07:53

Actin Co-Sedimentation Assay; for the Analysis of Protein Binding to F-Actin

Published on: March 28, 2008

Busy doing nothing: evidence for nonaction--effect binding.

Simone Kühn1, Birgit Elsner, Wolfgang Prinz

  • 1Max Planck Institute for Human Cognitive and Brain Sciences, Leipzig, Germany. skuehn@cbs.mpg.de

Psychonomic Bulletin & Review
|May 20, 2009
PubMed
Summary
This summary is machine-generated.

This study shows that intentionally not acting, or voluntary nonaction, can be mentally linked to its outcome, similar to how actions are linked to their effects. This nonaction-effect binding requires the nonaction to be voluntary.

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Measuring Protein Binding to F-actin by Co-sedimentation
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Related Experiment Videos

Last Updated: Jun 23, 2026

Actin Co-Sedimentation Assay; for the Analysis of Protein Binding to F-Actin
07:53

Actin Co-Sedimentation Assay; for the Analysis of Protein Binding to F-Actin

Published on: March 28, 2008

A Time-Efficient Fluorescence Spectroscopy-Based Assay for Evaluating Actin Polymerization Status in Rodent and Human Brain Tissues
06:54

A Time-Efficient Fluorescence Spectroscopy-Based Assay for Evaluating Actin Polymerization Status in Rodent and Human Brain Tissues

Published on: June 3, 2021

Measuring Protein Binding to F-actin by Co-sedimentation
06:17

Measuring Protein Binding to F-actin by Co-sedimentation

Published on: May 18, 2017

Area of Science:

  • Cognitive Neuroscience
  • Psychology of Action

Background:

  • Voluntary action research primarily focuses on motor and cognitive representations of acting.
  • The representation of voluntary nonaction has been largely overlooked in scientific literature.

Purpose of the Study:

  • To investigate the cognitive and motor representations of intentionally not acting.
  • To explore whether nonactions can be represented similarly to actions in the brain.

Main Methods:

  • Utilized an action-effect binding paradigm.
  • Compared the binding of voluntary actions to effects with the binding of voluntary nonactions to effects.

Main Results:

  • Demonstrated that voluntary nonactions can be bound to an effect tone, establishing nonaction-effect binding.
  • Showed that this binding only occurs when the nonaction is initiated voluntarily.

Conclusions:

  • Effect binding is not limited to actions but also applies to intended nonactions.
  • Voluntary nonaction has distinct cognitive and motor representations that can be studied using effect-binding paradigms.