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Aster swarming by symmetry breaking of cortical dynein transport and coupling kinesins

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dc.contributor.author KHETAN, NEHA en_US
dc.contributor.author ATHALE, CHAITANYA A. en_US
dc.date.accessioned 2020-10-16T06:36:48Z
dc.date.available 2020-10-16T06:36:48Z
dc.date.issued 2020-10 en_US
dc.identifier.citation Soft Matter, 16(37), 8554-8564. en_US
dc.identifier.issn 1744-683X en_US
dc.identifier.issn 1744-6848 en_US
dc.identifier.uri http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/5133
dc.identifier.uri https://doi.org/10.1039/D0SM01086C en_US
dc.description.abstract Microtubule (MT) radial arrays or asters establish the internal topology of a cell by interacting with organelles and molecular motors. We proceed to understand the general pattern forming potential of aster–motor systems using a computational model of multiple MT asters interacting with motors in cellular confinement. In this model dynein motors are attached to the cell cortex and plus-ended motors resembling kinesin-5 diffuse in the cell interior. The introduction of ‘noise’ in the form of MT length fluctuations spontaneously results in the emergence of coordinated, achiral vortex-like rotation of asters. The coherence and persistence of rotation require a threshold density of both cortical dyneins and coupling kinesins, while the onset is diffusion-limited with relation to the cortical dynein mobility. The coordinated rotational motion emerges due to the resolution of a ‘tug-of-war’ of multiple cortical dynein motors bound to MTs of the same aster by ‘noise’ in the form of MT dynamic instability. This transient symmetry breaking is amplified by local coupling by kinesin-5 complexes. The lack of widespread aster rotation across cell types suggests that biophysical mechanisms that suppress such intrinsic dynamics may have evolved. This model is analogous to more general models of locally coupled self-propelled particles (SPP) that spontaneously undergo collective transport in the presence of ‘noise’ that have been invoked to explain swarming in birds and fish. However, the aster–motor system is distinct from SPP models with regard to the particle density and ‘noise’ dependence, providing a set of experimentally testable predictions for a novel sub-cellular pattern forming system. en_US
dc.language.iso en en_US
dc.publisher Royal Society of Chemistry en_US
dc.subject Microtubule Dynamics en_US
dc.subject Cytoplasmic Dynein en_US
dc.subject Self-Organization en_US
dc.subject Actin-Filaments en_US
dc.subject Cell-Division en_US
dc.subject Spindle en_US
dc.subject Driven en_US
dc.subject Model en_US
dc.subject Motion en_US
dc.subject Motors en_US
dc.subject 2020 en_US
dc.subject 2020-OCT-WEEK2 en_US
dc.subject TOC-OCT-2020 en_US
dc.title Aster swarming by symmetry breaking of cortical dynein transport and coupling kinesins en_US
dc.type Article en_US
dc.contributor.department Dept. of Biology en_US
dc.identifier.sourcetitle Soft Matter en_US
dc.publication.originofpublisher Foreign en_US


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