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Related Concept Videos

Actin Treadmilling01:18

Actin Treadmilling

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Actin filaments undergo polymerization and depolymerization from either end. The polymerization and depolymerization rates depend on the cytosolic concentration of free G-actins. The polymerization rate is generally higher at the plus or barbed end, while the depolymerization rate is higher at the minus or pointed end. At a steady state, critical concentration describes the concentration of free G-actin monomers at which the polymerization rate at the plus end is equal to that of the...
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Actin Polymerization01:42

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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...
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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.
Actin cytoskeleton dynamics can produce pushing, pulling, and resistance forces that help the cell to migrate....
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Generation of Straight or Branched Actin Filaments01:14

Generation of Straight or Branched Actin Filaments

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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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Introduction to Actin01:26

Introduction to Actin

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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...
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Studying the Cytoskeleton01:17

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The cytoskeletal architecture can be studied using different microscopic and biochemical techniques. Electron microscopy was instrumental in discovering the cytoskeletal architecture around the 1960s, which allowed obtaining structural information at a high-resolution level. However, the sample preparation procedure often limits this ability in biological samples. Several protocols have been developed over the years to optimize sample preparation. In one of the protocols known as rotary...
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Related Experiment Video

Updated: May 24, 2025

Cortical Actin Flow in T Cells Quantified by Spatio-temporal Image Correlation Spectroscopy of Structured Illumination Microscopy Data
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Cortical Actin Flow in T Cells Quantified by Spatio-temporal Image Correlation Spectroscopy of Structured Illumination Microscopy Data

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Spatiotemporal feature learning for actin dynamics.

Siddhartha Saha1, Qixin Yang2, Wolfgang Losert2

  • 1Department of Physics and Astronomy, Rutgers University, Piscataway, New Jersey, United States of America.

Plos One
|March 5, 2025
PubMed
Summary
This summary is machine-generated.

Machine learning can predict Dictyostelium discoideum cell microenvironments from actin wave videos. Analyzing actin dynamics reveals nano-topography and electric field influences on cell migration.

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Area of Science:

  • Cellular and Molecular Biology
  • Biophysics
  • Computational Biology

Background:

  • Dictyostelium discoideum is a model organism for studying cell motility and pattern formation.
  • Cell migration relies on actin cytoskeleton dynamics, sensitive to microenvironmental cues like stiffness, topography, and electric fields.
  • Understanding how microenvironmental factors influence cell behavior is crucial for biological research.

Purpose of the Study:

  • To investigate if machine learning can infer microenvironmental conditions (electric fields, nano-topography) from actin wave videos in Dictyostelium discoideum.
  • To identify visual features of actin waves that correlate with specific microenvironmental characteristics.
  • To develop computational methods for analyzing cell dynamics in response to physical cues.

Main Methods:

  • Utilized three machine learning techniques: dictionary learning, scattering transforms, and optical flow.
  • Analyzed video microscopy data of Dictyostelium discoideum actin waves.
  • Developed frame-by-frame prediction models to classify microenvironment types based on actin wave patterns.

Main Results:

  • Dictionary learning and scattering transforms effectively classified cells based on nano-topography by analyzing static image features.
  • Optical flow, by tracking stable cellular features over time, proved effective in predicting the presence of external electric fields.
  • The study demonstrated that distinct actin wave patterns correlate with different microenvironmental conditions.

Conclusions:

  • Machine learning analysis of actin waves provides a robust method for inferring microenvironmental properties.
  • Specific machine learning approaches are better suited for identifying different types of physical cues.
  • This computational framework can be applied to study collective cell dynamics in various biological systems using video microscopy.