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Polarized growth drives the morphogenesis of elongated cellular structures. In plants, polarized growth depends on actin and a tip focused ionic calcium gradient. How the calcium gradient is maintained remains unclear. We discovered that autoinhibitory calcium ATPases (ACAs) redundantly contribute to the steepness of the calcium gradient. ACA1 and ACA2 localize to the subapical plasma membrane and ACA5 to the vacuole membrane, providing spatial regulation of calcium efflux. Tip-growing plant cells also exhibit apical calcium fluctuations. Even though Δaca1/2/5 cells have a diminished calcium gradient, they exhibit normal fluctuations and actin but have significantly reduced apical secretion. Furthermore, cells lacking apical actin retain a strong calcium gradient but have reduced apical secretion. Suppression of both the calcium gradient and apical actin dramatically impairs growth, supporting a model where two independent and parallel processes, the calcium gradient and apical actin, promote rapid polarized growth. 

In animals, PIEZOs are plasma membrane–localized cation channels involved in diverse mechanosensory processes. We investigated PIEZO function in tip-growing cells in the mossPhyscomitrium patensand the flowering plantArabidopsis thaliana.PpPIEZO1 andPpPIEZO2 redundantly contribute to the normal growth, size, and cytoplasmic calcium oscillations of caulonemal cells. BothPpPIEZO1 andPpPIEZO2 localized to vacuolar membranes. Loss-of-function, gain-of-function, and overexpression mutants revealed that moss PIEZO homologs promote increased complexity of vacuolar membranes through tubulation, internalization, and/or fission.ArabidopsisPIEZO1 also localized to the tonoplast and is required for vacuole tubulation in the tips of pollen tubes. We propose that in plant cells the tonoplast has more freedom of movement than the plasma membrane, making it a more effective location for mechanosensory proteins.