Cytoplasmic Flows As Signatures for the Mechanics of Mitotic Positioning

Overview

Journal Mol Biol Cell

Specialties Cell Biology
Molecular Biology

Date 2017 Mar 24

PMID 28331070

Citations 17

Authors

Ehssan Nazockdast

Abtin Rahimian

Daniel Needleman

Michael Shelley

Affiliations

Soon will be listed here.

Abstract

The proper positioning of mitotic spindle in the single-cell embryo is achieved initially by the migration and rotation of the pronuclear complex (PNC) and its two associated astral microtubules (MTs). Pronuclear migration produces global cytoplasmic flows that couple the mechanics of all MTs, the PNC, and the cell periphery with each other through their hydrodynamic interactions (HIs). We present the first computational study that explicitly accounts for detailed HIs between the cytoskeletal components and demonstrate the key consequences of HIs for the mechanics of pronuclear migration. First, we show that, because of HIs between the MTs, the cytoplasm-filled astral MTs behave like a porous medium, with its permeability decreasing with increasing the number of MTs. We then directly study the dynamics of PNC migration under various force-transduction models, including the pushing or pulling of MTs at the cortex and the pulling of MTs by cytoplasmically bound force generators. Although achieving proper position and orientation on reasonable time scales does not uniquely choose a model, we find that each model produces a different signature in its induced cytoplasmic flow. We suggest that cytoplasmic flows can be used to differentiate between mechanisms.

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Two-fluid dynamics and micron-thin boundary layers shape cytoplasmic flows in early embryos.

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Two-fluid dynamics and micron-thin boundary layers shape cytoplasmic flows in early embryos.

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