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Related Concept Videos

Cytoskeletal Coordination in Cell Migration01:32

Cytoskeletal Coordination in Cell Migration

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 proteins that...
Cell Migration01:09

Cell Migration

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.
Cell Migration01:19

Cell Migration

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.
Role of Myosin in Cell Migration01:18

Role of Myosin in Cell Migration

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. It is...
The Movement of Organelles and Vesicles01:43

The Movement of Organelles and Vesicles

In eukaryotic cells,  cytoskeletal filaments such as actin, microtubules, and intermediate filaments form a mesh-like cytoskeletal network. These filaments serve as tracks for transporting cellular cargo. Specialized motor proteins use the chemical energy stored in adenosine triphosphate (ATP) for this transport. During interphase, microtubules are polarized, with the plus-end towards the cell periphery and the minus-end towards the cell center. Two microtubule-associated motor proteins,...
Anaphase A and B01:39

Anaphase A and B

Microtubules form through the end-to-end polymerization of tubulin heterodimers. Kinetochore microtubules originate from the spindle poles, and their plus-ends connect with the kinetochores on sister-chromatids. Ndc80 protein complexes, present on the kinetochore, form low-affinity links with the plus end of these kinetochore microtubules.
Plus-end depolymerization releases tubulin heterodimers from the terminal region of the microtubule. As tubulin subunits are lost, the Ndc80 complexes detach...

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Related Experiment Video

Updated: May 19, 2026

Nuclear Migration in the Drosophila Oocyte
04:17

Nuclear Migration in the Drosophila Oocyte

Published on: May 13, 2021

Apical movement during interkinetic nuclear migration is a two-step process.

Philip C Spear1, Carol A Erickson

  • 1Department of Molecular and Cellular Biology, One Shields Ave., UC Davis, Davis, CA 95616, United States. pcspear@ucdavis.edu

Developmental Biology
|August 14, 2012
PubMed
Summary
This summary is machine-generated.

Neural progenitor cells migrate their nuclei apically during G2 phase using microtubules. Mitosis then occurs at the apical surface through an actin-dependent rounding process, revealing a new model for interkinetic nuclear migration.

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Capturing Cytoskeleton-Based Agitation of the Mouse Oocyte Nucleus Across Spatial Scales

Published on: January 12, 2024

Area of Science:

  • Developmental Biology
  • Cell Biology
  • Neuroscience

Background:

  • Neural progenitor cells in vertebrate neuroepithelium exhibit interkinetic nuclear migration (INM).
  • Mitotic cells are typically found at the apical surface, while interphase nuclei are distributed basally.
  • The precise mechanisms of nuclear apical migration and mitosis coordination remain unclear.

Purpose of the Study:

  • To elucidate the mechanisms underlying nuclear migration during interkinetic nuclear migration.
  • To understand how mitosis is coordinated with nuclear positioning in neural progenitor cells.
  • To propose a revised model for interkinetic nuclear migration.

Main Methods:

  • Time-lapse confocal microscopy was employed to observe nuclear and centrosome dynamics.
  • Experiments were conducted using chicken neural tube and mouse cortical slice preparations.

Main Results:

  • Nuclei migrate apically in G2 phase, facilitated by microtubules.
  • Centrosomes detach from the apical surface late in G2, initiating mitosis away from the apex.
  • The mitotic cell rounds up to the apical surface via an actin-dependent mechanism.

Conclusions:

  • Interkinetic nuclear migration involves a complex interplay between microtubules and actin.
  • A novel model is proposed where microtubules guide nuclear migration and actin facilitates apical rounding for mitosis.
  • This mechanism is conserved across different vertebrate species.