The Incredible Shrinking Spindle

As cell size decreases during the reductive divisions of early development, intracellular structures must shrink to fit. In this issue of Developmental Cell, Lacroix et al. (2018) identify a conserved mechanism of spindle scaling in nematode and sea urchin embryos whereby spindle microtubule polymer...

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Veröffentlicht in:Developmental cell 2018-05, Vol.45 (4), p.421-423
Hauptverfasser: Brownlee, Christopher, Heald, Rebecca
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Heald, Rebecca
description As cell size decreases during the reductive divisions of early development, intracellular structures must shrink to fit. In this issue of Developmental Cell, Lacroix et al. (2018) identify a conserved mechanism of spindle scaling in nematode and sea urchin embryos whereby spindle microtubule polymerization rates decrease as development proceeds. As cell size decreases during the reductive divisions of early development, intracellular structures must shrink to fit. In this issue of Developmental Cell, Lacroix et al. (2018) identify a conserved mechanism of spindle scaling in nematode and sea urchin embryos whereby spindle microtubule polymerization rates decrease as development proceeds.
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subjects Animals
Cell Size
Microtubules
Sea Urchins
Spindle Apparatus
title The Incredible Shrinking Spindle
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