The integrity of the cell wall depends on the synthesis and correct assembly of its individual components. Several environmental factors, such as temperature up-shift, treatments with mating factors or with specific cell wall-perturbing drugs, or genetic factors, such as inactivation of cell wall-related genes (for example FKS1 or GAS1) can impair construction of the cell wall. As the cell wall is essential for preserving the osmotic integrity of the cell, several responses are triggered in response to cell-wall damage. This review focuses on the activation of salvage pathways that guarantee cell survival through remodeling of the extracellular matrix. These researches have useful implication for the study of similar pathways in human fungal pathogens, and for the evaluation of the efficacy of new antifungal drugs.
The cell wall is essential to preserve osmotic integrity of yeast cells. Some phenotypic traits of cell wall mutants suggest that, as a result of a weakening of the cell wall, hypo-osmotic stress-like conditions are created. Consequent expansion of the cell wall and stretching of the plasma membrane trigger a complex response to prevent cell lysis. In this work we examined two conditions that generate a cell wall and membrane stress: one is represented by the cell wall mutant gas1 and the other by a hypo-osmotic shock. We examined the actin cytoskeleton and the role of the cell wall sensors Wsc1p and Mid2p in these stress conditions. In the gas1 null mutant cells, which lack a β(1,3)-glucanosyltransferase activity required for cell wall assembly, a constitutive marked depolarization of actin cytoskeleton was found. In a hypo-osmotic shock wild-type cells showed a transient depolarization of actin cytoskeleton. The percentage of depolarized cells was maximal at 30 min after the shift and then progressively decreased until cells reached a new steadystate condition. The maximal response was proportional to the magnitude of the difference in the external osmolarity before and after the shift within a given range of osmolarities. Loss of Wsc1p specifically delayed the repolarization of the actin cytoskeleton, whereas Wsc1p and Mid2p were essential for the maintenance of cell integrity in gas1 cells. The control of actin cytoskeleton is an important element in the context of the compensatory response to cell wall weakening. Wsc1p appears to be an important regulator of the actin network rearrangements in conditions of cell wall expansion and membrane stretching.
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