The abscission checkpoint regulates the ESCRT membrane fission machinery and thereby delays cytokinetic abscission to protect genomic integrity in response to residual mitotic errors. The checkpoint is maintained by Aurora B kinase, which phosphorylates multiple targets, including CHMP4C, a regulatory ESCRT-III subunit necessary for this checkpoint. We now report the discovery that cytoplasmic abscission checkpoint bodies (ACBs) containing phospho-Aurora B and tri-phospho-CHMP4C develop during an active checkpoint. ACBs are derived from mitotic interchromatin granules, transient mitotic structures whose components are housed in splicing-related nuclear speckles during interphase. ACB formation requires CHMP4C, and the ESCRT factor ALIX also contributes. ACB formation is conserved across cell types and under multiple circumstances that activate the checkpoint. Finally, ACBs retain a population of ALIX, and their presence correlates with delayed abscission and delayed recruitment of ALIX to the midbody where it would normally promote abscission. Thus, a cytoplasmic mechanism helps regulate midbody machinery to delay abscission.
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| http://dx.doi.org/10.7554/eLife.63743 | DOI Listing |
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Article Synopsis
- The study explores how chromatin bridges are detected during cell division, focusing on the role of the DNA topoisomerase IIα (Top2α) enzyme in forming cleavage complexes on catenated DNA.
- These Top2-DNA complexes are processed by the proteasome, allowing the DNA damage sensor protein Rad17 to bind to the double-strand DNA ends created by Top2.
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