Reversible Actin modifications by Mical and SelR regulate dynamic actomyosin ring functions during cell wound repair

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Reversible Actin modifications by Mical and SelR regulate dynamic actomyosin ring functions during cell wound repair

Authors

Nakamura, M.; Hui, J.; Parkhurst, S. M.

Abstract

Cell wound repair requires rapid and coordinated remodeling of the actin cytoskeleton to restore cortex integrity. Here, we show that a Rab35-Mical-SelR pathway regulates actomyosin ring dynamics through reversible actin redox. We find that Rab35 is recruited to wounds and is essential for proper actin ring assembly and disassembly. Rab35 regulates the recruitment of Mical, an actin-oxidizing enzyme, and SelR, a reductase that reverses oxidation, to the cell wound. Mical and SelR knockdowns disrupt actin ring formation and wound closure, whereas double knockdown partially rescues these defects, indicating a balanced redox cycle is required. Super-resolution microscopy reveals that Mical and SelR differentially regulate F-actin architecture and orientation. Mutation of actin at Methionine 44 does not fully recapitulate Mical knockdown phenotypes, suggesting the presence of additional targets and enzymes. Taken together, our results indicate that reversible actin modifications dynamically regulate F-actin architecture and orientation for actin ring assembly and disassembly.

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