Mitosis-Specific Mechanosensing and Contractile-Protein Redistribution Control Cell Shape

Effler, Janet C.; Kee, Yee Seir; Berk, Jason M.; Tran, Minhchau N.; Iglesias, Pablo A.; Robinson, Douglas N.

doi:10.1016/j.cub.2006.08.027

Cited by 123 publications

(168 citation statements)

References 32 publications

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“…To explain these, we proposed that Dictyostelium cells [5][6][7]: cytokinesis A, which is dependent on active contraction of a contractile ring and is independent of substrate adhesion, and cytokinesis B [4,5], or attachment-assisted mitotic cleavage [3], which does not depend on active contraction of a contractile ring but requires substrate adhesion. We have proposed that cytokinesis B is driven by oppositely oriented traction forces generated by two daughter cells, which separate the two cells by moving away from one another [5,6], although a similar but somewhat different hypothesis has also been proposed [32,33]. The aim of this study was to reveal the crosstalk among cell adhesion, cell migration and cytokinesis, cytokinesis B in particular, in Dictyostelium through examination of the functions of PAXB and VINA.…”

Section: Discussionmentioning

confidence: 99%

Cell adhesion molecules regulate contractile ring-independent cytokinesis in Dictyostelium discoideum

2008

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To investigate the roles of substrate adhesion in cytokinesis, we established cell lines lacking paxillin (PAXB) or vinculin (VINA), and those expressing the respective GFP fusion proteins in Dictyostelium discoideum. As in mammalian cells, GFP-PAXB and GFP-VINA formed focal adhesion-like complexes on the cell bottom. paxB − cells in suspension grew normally, but on substrates, often failed to divide after regression of the furrow. The efficient cytokinesis of paxB − cells in suspension is not because of shear forces to assist abscission, as they divided normally in static suspension culture as well. Double knockout strains lacking mhcA, which codes for myosin II, and paxB or vinA displayed more severe cytokinetic defects than each single knockout strain. In mitotic wild-type cells, GFP-PAXB was diffusely distributed on the basal membrane, but was strikingly condensed along the polar edges in mitotic mhcA − cells. These results are consistent with our idea that Dictyostelium displays two forms of cytokinesis, one that is contractile ringdependent and adhesion-independent, and the other that is contractile ring-independent and adhesion-dependent, and that the latter requires PAXB and VINA. Furthermore, that paxB − cells fail to divide normally in the presence of substrate adhesion suggests that this adhesion molecule may play additional signaling roles.

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Section: Discussionmentioning

confidence: 99%

Cell adhesion molecules regulate contractile ring-independent cytokinesis in Dictyostelium discoideum

2008

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“…The major module responsible for cellular mechanosensing is the force-dependent accumulation of myosin II involving the assembly -disassembly of myosin II BTFs [10,12]. In our model, we coupled this to the viscoelastic properties of a cell to explain the biphasic mechanosensitive myosin accumulation and ensuing cellular deformation observed in WT and actin cross-linker-depleted mutant Dictyostelium cells.…”

Section: Discussionmentioning

confidence: 99%

“…For this reason, the signs in front of s ten ðr R Þ, Ds cross ðI cross Þ and Ds myo ðI myo Þ in the above equation are all negative. In practice, the accumulation of cross-linkers and myosin II differs, though there is a strong correlation between the two [10,14]. To keep the model simple, we assumed that the increase in accumulation of the cross-linkers is the same as that of myosin II; i.e.…”

Section: Description Of Forces Acting In An Aspirated Cellmentioning

confidence: 99%

“…When WT or genetically modified Dictyostelium cells are subjected to constant mechanical perturbation through a micropipette aspirator, myosin II is recruited to the site of deformation [10,[12][13][14] (figure 1a). The kinetics of myosin II accumulation in each of the cell types can be characterized as three distinct temporal phases: an initial accelerating accumulation, followed by a plateau, and subsequent decay (figure 2, left panels; [13,14]).…”

Section: Mechanosensitive Myosin II Accumulation During Micropipette mentioning

confidence: 99%

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Cell shape regulation through mechanosensory feedback control

Mohan

Luo

Robinson

et al. 2015

J. R. Soc. Interface.

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Cells undergo controlled changes in morphology in response to intracellular and extracellular signals. These changes require a means for sensing and interpreting the signalling cues, for generating the forces that act on the cell's physical material, and a control system to regulate this process. Experiments on Dictyostelium amoebae have shown that force-generating proteins can localize in response to external mechanical perturbations. This mechanosensing, and the ensuing mechanical feedback, plays an important role in minimizing the effect of mechanical disturbances in the course of changes in cell shape, especially during cell division, and likely in other contexts, such as during three-dimensional migration. Owing to the complexity of the feedback system, which couples mechanical and biochemical signals involved in shape regulation, theoretical approaches can guide further investigation by providing insights that are difficult to decipher experimentally. Here, we present a computational model that explains the different mechanosensory and mechanoresponsive behaviours observed in Dictyostelium cells. The model features a multiscale description of myosin II bipolar thick filament assembly that includes cooperative and force-dependent myosinactin binding, and identifies the feedback mechanisms hidden in the observed mechanoresponsive behaviours of Dictyostelium cells during micropipette aspiration experiments. These feedbacks provide a mechanistic explanation of cellular retraction and hence cell shape regulation.

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“…In complex living tissues and organisms, cells have to adapt to compressive forces exerted by multiple surrounding cells. These mechanical interactions, which are intricately involved in cellular processes both mechanically and biochemically, thus have a strong impact on cellular functions (1)(2)(3)(4). Mechanical forces play an especially important role in chromosome segregation machinery, which is controlled by mechanochemical regulation (5)(6)(7).…”

mentioning

confidence: 99%

Mechanical impulses can control metaphase progression in a mammalian cell

Itabashi¹,

Terada

Kuwana

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Chromosome segregation machinery is controlled by mechanochemical regulation. Tension in a mitotic spindle, which is balanced by molecular motors and polymerization-depolymerization dynamics of microtubules, is thought to be essential for determining the timing of chromosome segregation after the establishment of the kinetochore-microtubule attachments. It is not known, however, whether and how applied mechanical forces modulate the tension balance and chemically affect the molecular processes involved in chromosome segregation. Here we found that a mechanical impulse externally applied to mitotic HeLa cells alters the balance of forces within the mitotic spindle. We identified two distinct mitotic responses to the applied mechanical force that either facilitate or delay anaphase onset, depending on the direction of force and the extent of cell compression. An external mechanical impulse that physically increases tension within the mitotic spindle accelerates anaphase onset, and this is attributed to the facilitation of physical cleavage of sister chromatid cohesion. On the other hand, a decrease in tension activates the spindle assembly checkpoint, which impedes the degradation of mitotic proteins and delays the timing of chromosome segregation. Thus, the external mechanical force acts as a crucial regulator for metaphase progression, modulating the internal force balance and thereby triggering specific mechanochemical cellular reactions.chromosome segregation | mechanobiology | mitotic force | mitotic spindle | spindle assembly checkpoint

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Mitosis-Specific Mechanosensing and Contractile-Protein Redistribution Control Cell Shape

Cited by 123 publications

References 32 publications

Cell adhesion molecules regulate contractile ring-independent cytokinesis in Dictyostelium discoideum

Cell adhesion molecules regulate contractile ring-independent cytokinesis in Dictyostelium discoideum

Cell shape regulation through mechanosensory feedback control

Mechanical impulses can control metaphase progression in a mammalian cell

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