At mitosis onset, cortical tension increases and cells round up, ensuring correct spindle morphogenesis and orientation. Thus, cortical tension sets up the geometric requirements of cell division. On the contrary, cortical tension decreases during meiotic divisions in mouse oocytes, a puzzling observation because oocytes are round cells, stable in shape, that actively position their spindles. We investigated the pathway leading to reduction in cortical tension and its significance for spindle positioning. We document a previously uncharacterized Arp2/3-dependent thickening of the cortical F-actin essential for first meiotic spindle migration to the cortex. Using micropipette aspiration, we show that cortical tension decreases during meiosis I, resulting from myosin-II exclusion from the cortex, and that cortical F-actin thickening promotes cortical plasticity. These events soften and relax the cortex. They are triggered by the Mos-MAPK pathway and coordinated temporally. Artificial cortex stiffening and theoretical modelling demonstrate that a soft cortex is essential for meiotic spindle positioning.
Many cell movements proceed via a crawling mechanism, where polymerization of the cytoskeletal protein actin pushes out the leading edge membrane. In this model, membrane tension has been seen as an impediment to filament growth and cell motility. Here we use a simple model of cell motility, the Caenorhabditis elegans sperm cell, to test how membrane tension affects movement and cytoskeleton dynamics. To enable these analyses, we create transgenic worm strains carrying sperm with a fluorescently labeled cytoskeleton. Via osmotic shock and deoxycholate treatments, we relax or tense the cell membrane and quantify apparent membrane tension changes by the membrane tether technique. Surprisingly, we find that membrane tension reduction is correlated with a decrease in cell displacement speed, whereas an increase in membrane tension enhances motility. We further demonstrate that apparent polymerization rates follow the same trends. We observe that membrane tension reduction leads to an unorganized, rough lamellipodium, composed of short filaments angled away from the direction of movement. On the other hand, an increase in tension reduces lateral membrane protrusions in the lamellipodium, and filaments are longer and more oriented toward the direction of movement. Overall we propose that membrane tension optimizes motility by streamlining polymerization in the direction of movement, thus adding a layer of complexity to our current understanding of how membrane tension enters into the motility equation. I n crawling cells, motility is mainly driven by actin polymerization, which forms filaments beneath the leading edge cell membrane to make protrusions (1). In this scenario, polymerization is inhibited by the presence of the cell membrane, and membrane tension is thus commonly seen as an impediment to cell motility (2). Experiments show that lamellipodial extension rate is indeed inversely correlated with membrane tension (3), but steady-state, whole cell translocation has not been studied. Here we use a simplified system of crawling cell motility, the Caenorhabditis elegans sperm cell, in order to address the question of how membrane tension affects whole cell translocation. The sperm cell contains only cytoskeleton, mitochondria, and nuclear material and is incapable of de novo protein synthesis or classical exo-and endocytosis, thus representing a useful model for exploring the interplay between membrane tension and cell motility. The sperm cell translocates by adhering to the substrate and emitting a dynamic lamellipodia, in a manner that is morphologically similar to actomyosin containing motile cells, despite the fact that the movement of sperm cells is powered by the dynamics of the major sperm protein (MSP) cytoskeleton in the absence of actin and known molecular motors (4, 5).The production of fluorescently labeled actin in living cells was a watershed in the understanding of how actin structures assemble, flow, and disassemble to produce cell motility. However, due to efficient gene silencing mechanisms in th...
Cell mechanics control the outcome of cell division. In mitosis, external forces applied on a stiff cortex direct spindle orientation and morphogenesis. During oocyte meiosis on the contrary, spindle positioning depends on cortex softening. How changes in cortical organization induce cortex softening has not yet been addressed. Furthermore, the range of tension that allows spindle migration remains unknown. Here, using artificial manipulation of mouse oocyte cortex as well as theoretical modelling, we show that cortical tension has to be tightly regulated to allow off-center spindle positioning: a too low or too high cortical tension both lead to unsuccessful spindle migration. We demonstrate that the decrease in cortical tension required for spindle positioning is fine-tuned by a branched F-actin network that triggers the delocalization of myosin-II from the cortex, which sheds new light on the interplay between actin network architecture and cortex tension.
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