Tension modulates actin filament polymerization mediated by formin and profilin

Courtemanche, Naomi; Lee, Ja Yil; Pollard, Thomas D.; Greene, Eric C.

doi:10.1073/pnas.1308257110

Cited by 119 publications

(129 citation statements)

References 31 publications

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“…5B), this would imply a ∼0.15 pN −1 sensitivity of the synthase, which is considerably higher than that of another molecular polymerization complex -RNA polymerase II of S. cerevisiae -for which we estimate μ*∼0.01 pN −1 at saturating NTP conditions (Larson et al, 2012). By contrast, the sensitivities estimated from constructs of the actin polymerization regulators formin Bni1p and mDia1, which contain the catalytic FH1-FH2 domains, are somewhat greater, μ*∼1 pN −1 and μ*∼0.4−0.5 pN −1 , respectively (Courtemanche et al, 2013;Jégou et al, 2013).…”

Section: Mechanosensitivity Of Septum Synthesis Machinery Enables Shacontrasting

confidence: 54%

The fission yeast cytokinetic contractile ring regulates septum shape and closure

Thiyagarajan

Munteanu

Arasada

et al. 2015

Journal of Cell Science

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During cytokinesis, fission yeast and other fungi and bacteria grow a septum that divides the cell in two. In fission yeast closure of the circular septum hole by the β-glucan synthases (Bgs) and other glucan synthases in the plasma membrane is tightly coupled to constriction of an actomyosin contractile ring attached to the membrane. It is unknown how septum growth is coordinated over scales of several microns to maintain septum circularity. Here, we documented the shapes of ingrowing septum edges by measuring the roughness of the edges, a measure of the deviation from circularity. The roughness was small, with spatial correlations indicative of spatially coordinated growth. We hypothesized that Bgs-mediated septum growth is mechanosensitive and coupled to contractile ring tension. A mathematical model showed that ring tension then generates almost circular septum edges by adjusting growth rates in a curvature-dependent fashion. The model reproduced experimental roughness statistics and showed that septum synthesis sets the mean closure rate. Our results suggest that the fission yeast cytokinetic ring tension does not set the constriction rate but regulates septum closure by suppressing roughness produced by inherently stochastic molecular growth processes.

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Section: Mechanosensitivity Of Septum Synthesis Machinery Enables Shacontrasting

confidence: 54%

The fission yeast cytokinetic contractile ring regulates septum shape and closure

Thiyagarajan

Munteanu

Arasada

et al. 2015

Journal of Cell Science

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“…We find that dynamic motor activity is crucial for the stabilization of myosin at the cortex, consistent with recent work showing that myosin phosphorylation regulates contractility in epithelial morphogenesis (Kasza et al, 2014;Vasquez et al, 2014;Vasquez et al, 2016). Several actin regulators are sensitive to load, including formins (Courtemanche et al, 2013;Higashida et al, 2013;Jégou et al, 2013), and the filament-severing protein cofilin (Hayakawa et al, 2011;Tojkander et al, 2015). The mechanical dependence of myosin dynamics could thus be a result of direct effects on the motor, indirect effects on the actin filaments bound by the motor, or a combination of both.…”

Section: Results and Discussion Myosin Turnover Is Reduced Around Embsupporting

confidence: 90%

Tension regulates myosin dynamics during Drosophila embryonic wound repair

Kobb¹,

Zulueta-Coarasa²,

Fernández-González³

2017

Development

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Embryos repair epithelial wounds rapidly in a process driven by collective cell movements. Upon wounding, actin and the molecular motor non-muscle myosin II are redistributed in the cells adjacent to the wound, forming a supracellular purse string around the lesion. Purse string contraction coordinates cell movements and drives rapid wound closure. By using fluorescence recovery after photobleaching in Drosophila embryos, we found that myosin turns over as the purse string contracts. Myosin turnover at the purse string was slower than in other actomyosin networks that had a lower level of contractility. Mathematical modelling suggested that myosin assembly and disassembly rates were both reduced by tension at the wound edge. We used laser ablation to show that tension at the purse string increased as wound closure progressed, and that the increase in tension was associated with reduced myosin turnover. Reducing purse string tension by laser-mediated severing resulted in increased turnover and loss of myosin. Finally, myosin motor activity was necessary for its stabilization around the wound and for rapid wound closure. Our results indicate that mechanical forces regulate myosin dynamics during embryonic wound repair.

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“…The mechanosensitivity of the contractome establishes a positive-feedback loop for increased local contractility, which is used in various cell processes, such as cytokinesis, cell adhesion, intercalation and membrane fusion (Luo et al, 2013;Schiller and Fassler, 2013;West-Foyle and Robinson, 2012;Fernandez-Gonzalez et al, 2009;Kim et al, 2015). Actin polymerization is enhanced under mechanical tension in a mechanism involving zyxin (Hirata et al, 2008) or by directly augmenting formin activity (Courtemanche et al, 2013;Jegou et al, 2013), and actin severing by cofilin is inhibited by tension in the actin filament (Hayakawa et al, 2011). Strikingly, the affinity of myosin II motor domain towards actin is enhanced when the actin filament is under tension, suggesting that this is the basis for cooperative assembly of actomyosin structures.…”

Section: Contractome Subnetworkmentioning

confidence: 99%

The contractome – a systems view of actomyosin contractility in non-muscle cells

Zaidel-Bar

Guo

Luxenburg

2015

Journal of Cell Science

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Actomyosin contractility is a highly regulated process that affects many fundamental biological processes in each and every cell in our body. In this Cell Science at a Glance article and the accompanying poster, we mined the literature and databases to map the contractome of non-muscle cells. Actomyosin contractility is involved in at least 49 distinct cellular functions that range from providing cell architecture to signal transduction and nuclear activity. Containing over 100 scaffolding and regulatory proteins, the contractome forms a highly complex network with more than 230 direct interactions between its components, 86 of them involving phosphorylation. Mapping these interactions, we identify the key regulatory pathways involved in the assembly of actomyosin structures and in activating myosin to produce contractile forces within non-muscle cells at the exact time and place necessary for cellular function.

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Tension modulates actin filament polymerization mediated by formin and profilin

Cited by 119 publications

References 31 publications

The fission yeast cytokinetic contractile ring regulates septum shape and closure

The fission yeast cytokinetic contractile ring regulates septum shape and closure

Tension regulates myosin dynamics during Drosophila embryonic wound repair

The contractome – a systems view of actomyosin contractility in non-muscle cells

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