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Cell Migration01:09

Cell Migration

18.1K
Cell migration, the process by which cells move from one location to another, is essential for the proper development and viability of organisms throughout their life. When cells are not able to migrate properly to their ordained locations, various disorders may occur. For example, disruption in cell migration causes chronic inflammatory diseases such as arthritis.
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Cell Migration01:19

Cell Migration

6.1K
Cell migration is a process by which the cells move from one location to another, playing an essential role in embryological development, repair and regeneration, immune response, and metastasis. Cells migrate in response to chemical or mechanical signals generated by specific organs or tissues. The overall mechanism includes three steps - polarization, protrusion, and release. Polarization involves the formation of a distinct cell front and rear, which determines the direction of movement.
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Cytoskeletal Coordination in Cell Migration01:32

Cytoskeletal Coordination in Cell Migration

5.2K
A migrating cell changes its shape during the cyclic events of attachment and detachment from the substratum and repositions the cell organelles correspondingly. These complex events are orchestrated by the dynamic cytoskeletal network comprising actin filaments, intermediate filaments, and microtubules. Cytoskeletal crosstalk — the direct and indirect communication between the different components — is crucial for this coordination. Direct communication involves various linker...
5.2K
Role of Myosin in Cell Migration01:18

Role of Myosin in Cell Migration

2.9K
Myosins are multimeric motor proteins involved in various cellular processes such as migration, adhesion, and proliferation. Myosin II is the most common type in animal cells, which binds and cross-links actin filaments.
Myosin II  is a hexamer comprising two heavy chains with globular heads and coiled-coil tails, two regulatory light chains, and two essential light chains. The ATPase sites on the myosin heads hydrolyze ATP, and the released phosphate generates the force for contraction....
2.9K
Mechanism of Lamellipodia Formation01:31

Mechanism of Lamellipodia Formation

3.3K
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...
3.3K
Chemotaxis and Direction of Cell Migration01:21

Chemotaxis and Direction of Cell Migration

4.2K
Cells can detect chemical cues in their environment and reorganize the cytoskeleton to migrate toward them or away from them. This directional migration, called chemotaxis, is essential during embryogenesis and development, immune response, tissue repair and regeneration, and reproduction. These chemical cues can either attract or repel the cell's movement. For example, axon development is determined by a combination of chemoattractants and chemorepellents that direct the growing axon...
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Related Experiment Video

Updated: Dec 7, 2025

Ex Utero Electroporation and Organotypic Slice Cultures of Embryonic Mouse Brains for Live-Imaging of Migrating GABAergic Interneurons
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Ex Utero Electroporation and Organotypic Slice Cultures of Embryonic Mouse Brains for Live-Imaging of Migrating GABAergic Interneurons

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Forces to Drive Neuronal Migration Steps.

Takunori Minegishi1, Naoyuki Inagaki1

  • 1Laboratory of Systems Neurobiology and Medicine, Division of Biological Science, Nara Institute of Science and Technology, Nara, Japan.

Frontiers in Cell and Developmental Biology
|September 28, 2020
PubMed
Summary
This summary is machine-generated.

Neurons migrate using a saltatory movement, involving distinct steps of leading process extension and cell body translocation. This process is driven by spatiotemporally organized forces and molecular mechanics, crucial for brain development.

Keywords:
actomyosinadhesion forcedyneinmechanical tensionmechanobiologyneuronal migrationshootin1traction force

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Area of Science:

  • Neuroscience
  • Cell Biology
  • Biophysics

Background:

  • Neuronal migration is essential for brain architecture and neural network formation.
  • Neurons migrate via a unique saltatory movement, characterized by leading process extension and cell body translocation.
  • This migration requires coordinated force generation for both extension and translocation.

Purpose of the Study:

  • To review the current understanding of forces driving neuronal migration steps.
  • To describe the molecular machineries responsible for generating these forces.
  • To elucidate the mechanobiology underlying neuronal saltatory movement.

Main Methods:

  • Mechanobiological analyses including traction force microscopy.
  • Cell detachment assays and live-cell imaging.
  • Loss-of-function analyses to investigate molecular contributions.

Main Results:

  • Neuronal migration involves distinct forces for leading process extension (traction forces) and cell body translocation (leading process tension, rear adhesion reduction, nucleokinesis forces).
  • Traction forces arise from the coupling of actin retrograde flow with the extracellular environment via clutch and adhesion molecules.
  • Actomyosin and dynein contribute to nucleokinesis, while external forces from neighboring cells coordinate collective migration.

Conclusions:

  • Spatiotemporally organized intracellular and extracellular forces are pivotal for neuronal migration.
  • Understanding the molecular mechanics of force generation is key to comprehending neuronal migration.
  • Coordination of intrinsic and extrinsic forces ensures proper neuronal positioning during development.