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Mini-Review |
Correspondence to Cécile Sykes: cecile.sykes{at}curie.fr
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Introduction |
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The cell membrane is supported by a thin cortical layer between 100 nm and 1 µm thick that consists of cross-linked actin filaments, myosin motors, and actin-binding proteins, the spatial organization and dynamics of which are only beginning to be resolved (Medalia et al., 2002; Bretschneider et al., 2004; Morone et al., 2006). The motors present in the cortex generate a contractile tension in the actin network (Dai et al., 1999) that can be relaxed if the cortex ruptures (Fig. 1 d). Local relaxation of the cortical tension can trigger polarization events such as global cortex flows (Bray and White, 1988; Munro et al., 2004) or the growth of membrane protrusions called blebs (Keller et al., 2002; Charras et al., 2005; Paluch et al., 2005). Similarly, during early neuronal differentiation, breaking of the neuronal sphere and sprouting of neurites seem to require local relaxations of the cortical actin meshwork, although, in this case, the role of myosin motors is unclear (Da Silva and Dotti, 2002). Polarization induced by a release of mechanical tension is also observed in simpler systems, such as in actin networks growing on beads that mimic Listeria monocytogenes motility. In this paper, we compare the biochemistry and the mechanics of polarization in cells and around beads, and we argue that the bead system can serve as a simple model system to study mechanically driven polarization in cells. Furthermore, we argue that both actin gels around beads and the actomyosin cortex in cells are close to an instability threshold. Instability can be triggered by an intracellular or extracellular signal or can occur spontaneously when a fluctuation exceeds the mechanical threshold. Finally, we discuss the likelihood that polarization, by locally overcoming a mechanical threshold, could apply more generally to a variety of biological systems.
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Symmetry breaking around beads: an example of mechanically driven polarization |
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 TopAbstractIntroduction Symmetry breaking around beads:... Cortex instability and cell...A closer look at...Symmetry can break from...Stress-induced polarization in...Concluding remarksReferences |
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Beads (radii of 1–10 µm) are first covered with an activator of actin polymerization and are placed in cell extracts or in a mixture of purified proteins that reconstitutes the dynamics of actin-based movement observed for the bacterium L. monocytogenes (Bernheim-Groswasser et al., 2002). Actin polymerization is activated at the surface of the bead, and an actin gel grows outward in spherical geometry. During gel growth, new monomers are incorporated at the bead surface underneath the preexisting gel, which is thus pushed outward and stretched as a result of the curved surface (Noireaux et al., 2000). As a consequence, stresses build up, and the actin shell is under tension (Fig. 1 a). When this tension exceeds the maximum tension that the actin network can bear, the actin shell breaks, and the actin gel develops into a comet tail (Fig. 1 b; Sekimoto et al., 2004; van der Gucht et al., 2005). The gel rupture is most likely to take place in a region where the actin network is locally weaker. Interestingly, symmetry breaking does not necessarily occur at a single point in the actin gel; for large beads, under conditions in which gel growth is slow (e.g., at low gelsolin concentration), the gel may rupture at multiple locations, giving rise to several comets (Fig. 1 c; and unpublished data).
In some cases, the gel stops growing before the rupture threshold is reached. The stress in the gel is then below the critical value, and symmetry breaking is delayed. However, symmetry breaking may still occur if a local perturbation is induced in the gel or, for example, if a spontaneous fluctuation in the cross-linker density is large enough to bring the system over the threshold (van der Gucht et al., 2005).
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Cortex instability and cell polarization |
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For example, flows of the actomyosin cortex have been observed in various cell lines at the onset of cytokinesis, where they presumably contribute to cleavage furrow formation (Cao and Wang, 1990; DeBiasio et al., 1996). One mechanism that has been proposed to cause these cortical flows is a local relaxation of the cortex at the cell poles by astral microtubules (Fig. 2 a; Bray and White, 1988). However, this hypothesis remains controversial, as several experiments have shown that myosin can be recruited and activated in the equatorial zone even in the absence of cortex flows (Straight et al., 2003; Bement et al., 2005; Dean et al., 2005). It is well possible that the cell uses several redundant mechanisms and that direct myosin recruitment mediated by the spindle midzone and aster-triggered cortex flows both contribute to furrow positioning (Wang et al., 1993; Bringmann and Hyman, 2005). Another process that is thought to depend on local cortex relaxation is the polarization of the one-cell Caenorhabditis elegans embryo. Here, the sperm provides the external cue: after fertilization, the sperm centrosome moves toward the point of sperm entry, where it locally relaxes cortical contractility (Cowan and Hyman, 2004). As during cytokinesis, the cortex flows away from the relaxed region, transporting polarity proteins and shaping the pseudocleavage furrow (Fig. 2 b; Munro et al., 2004). Polarization by cortex relaxation may also precede cell migration in some cells (Paluch et al., 2006; Yoshida and Soldati, 2006).
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A closer look at conditions under which symmetry breaks in cells or around beads |
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In both systems, the instability threshold can be lowered by lowering the density of cross-linkers in the actin gel, like filamin or 
-actinin, which leads to a softer and weaker network. Indeed, the depletion of filamin or degradation of -actinin in cells enhances blebbing, probably as a result of cortical breakage, or at least a local release in the cortical tension (Cunningham, 1995; Miyoshi et al., 1996). Conversely, shell breakage in the bead system is slowed down by the presence of filamin or -actinin (van der Gucht et al., 2005). In both systems, actin gel rupture is thus facilitated by the depletion of cross-linkers.
The driving force for cortex breakage in cells can be enhanced by increasing the activity of myosin II, leading to an increased contractility of the cortex and a larger cortical tension. Indeed, blebbing in cells is enhanced when the global contractility of the cortex is increased (Sahai and Marshall, 2003), and, conversely, blebbing is reduced when contractility is decreased (Mills et al., 1998). In the bead system, the tension is related to the thickness of the gel layer. Thus, the analogous effect of decreased contractility (leading to a lower tension) in the bead system is a decrease in gel thickness. For example, this can be achieved by adding actin-depolymerizing factor/cofilin, which enhances the depolymerization of filaments in the outer regions of the actin gel. Indeed, at high actin-depolymerizing factor/ cofilin concentrations, the gel thickness remains small, and no symmetry breaking is observed, indicating that the threshold tension for gel rupture can never be reached (van der Gucht et al., 2005).
A growing actin shell in spherical geometry can break spontaneously and form a propelling comet at the opposite side of the breakage point, although the original breakage and, thus, direction of the comet is random. If gel growth stops before the instability threshold is reached, symmetry breaking can still be triggered by an external perturbation (for example, by a local disruption of the actin network by photodamage; van der Gucht et al., 2005). Likewise, a local alteration of the actin cortex in cells, either by locally applying drugs that affect actin or by increasing the local stress mechanically, induces cortex rupture and bleb formation (Paluch et al., 2005).
We can compare the forces necessary for shell breakage around beads and for cortex breakage in cells. The stresses in the gel around beads can be estimated from the elastic modulus of the actin gel and the thickness of the gel (Noireaux et al., 2000). This produces a value of 103–104 Pa for the critical tensile stress for gel rupture (van der Gucht et al., 2005). The cell cortical tension has been estimated in different cell types and is on the order of 10–3 N/m for Dictyostelium discoideum (Pasternak et al., 1989; Dai et al., 1999), lymphocytes (Pasternak and Elson, 1985), or fibroblasts (Matzke et al., 2001), whereas it is 
20–30 times smaller for neutrophils (Evans and Yeung, 1989). With a cortical thickness of a few hundred nm, this provides a value of 103–104 Pa for the tensile stress in the cortex, which is very similar to the stress in the bead system. Interestingly, in D. discoideum, the deletion of either myosin II or of two myosins I leads to a decrease of the tension by 50%, suggesting that most of the cortex tension is caused by myosin motors (Dai et al., 1999). Note that the cortical tension is very close to the threshold for cortex breakage, as breakage can be induced by applying pressures as small as 100 Pa, which is only 10% of the cortical stress (Paluch et al., 2005).
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Symmetry can break from one point or from multiple points |
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Stress-induced polarization in other systems |
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TopAbstractIntroductionSymmetry breaking around beads:...Cortex instability and cell...A closer look at...Symmetry can break from...Stress-induced polarization in...Concluding remarksReferences |
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On a larger scale, a mechanical instability has been proposed to explain the shape and size of oscillations observed during the regeneration of fresh water polyp Hydra vulgaris. At the initial stages, H. vulgaris cells form a hollow sphere consisting of a cell bilayer. This sphere inflates by the uptake of fluid and builds up pressure as a result of stretching of the cells, which is analogous to the accumulation of stress in the actin gel growing around a bead. It has been proposed that this stress is released by rupture of the cell layer followed by rapid shrinkage of the cell ball (Fütterer et al., 2003). Repeated cycles of growth followed by rupture and rapid shrinkage might be important for the first polarization step in H. vulgaris morphogenesis.
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Concluding remarks |
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Highly reactive systems operating close to instability thresholds may be frequently found in biology. A similar, although not mechanical, threshold mechanism is observed in budding yeast, for example, where Cdc42, a small GTPase, is required for bud formation. The expression of a constitutively active Cdc42 results in spontaneous polarization with random orientation (Lechler et al., 2001; Wedlich-Soldner et al., 2003). It is possible that the enhanced activity of Cdc42 brings the system closer to a chemical threshold, where it becomes sensitive to random fluctuations (Wedlich-Soldner and Li, 2003).
Comparing the forces necessary for rupture and the effects of various proteins on symmetry breaking suggests that the mechanisms of polarization of the cell cortex and of the rupture of gels growing around beads are very similar. As a consequence, understanding symmetry breaking in biomimetic systems may provide essential insight into spontaneous cortex rupture in cells. There are many open questions as to how exactly polarizing signals trigger the mechanical instability leading to cortex rupture. The centrosome–microtubule system plays an essential role here, but, to a large extent, the pathways by which it controls the cortex mechanics are still unknown.
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Acknowledgments |
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Research in the Sykes' laboratory is supported by a Curie Programme Incitatif Coopératif grant, a Human Frontiers Science Program grant, and an Action Concertée Nanosciences grant from the French Ministry of Research. J. van der Gucht acknowledges a Human Frontier Science Program fellowship. The research project of E. Paluch is funded by the Polish Ministry of Science and Higher Education from science funds for the years 2006–2009.
Submitted: 28 July 2006
Accepted: 24 October 2006
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