Pericentric chromatin loops function as a nonlinear spring in mitotic force balance |
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| Authors: | Andrew D. Stephens Rachel A. Haggerty Paula A. Vasquez Leandra Vicci Chloe E. Snider Fu Shi Cory Quammen Christopher Mullins Julian Haase Russell M. Taylor II Jolien S. Verdaasdonk Michael R. Falvo Yuan Jin M. Gregory Forest Kerry Bloom |
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| Affiliation: | 1.Department of Biology, 2.Department of Computer Science, 3.Department of Physics and Astronomy, and 4.Department of Mathematics and Biomedical Engineering, The University of North Carolina at Chapel Hill, Chapel Hill, NC 27599 |
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| Abstract: | ![]()
The mechanisms by which sister chromatids maintain biorientation on the metaphase spindle are critical to the fidelity of chromosome segregation. Active force interplay exists between predominantly extensional microtubule-based spindle forces and restoring forces from chromatin. These forces regulate tension at the kinetochore that silences the spindle assembly checkpoint to ensure faithful chromosome segregation. Depletion of pericentric cohesin or condensin has been shown to increase the mean and variance of spindle length, which have been attributed to a softening of the linear chromatin spring. Models of the spindle apparatus with linear chromatin springs that match spindle dynamics fail to predict the behavior of pericentromeric chromatin in wild-type and mutant spindles. We demonstrate that a nonlinear spring with a threshold extension to switch between spring states predicts asymmetric chromatin stretching observed in vivo. The addition of cross-links between adjacent springs recapitulates coordination between pericentromeres of neighboring chromosomes. |
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