Genetic screen to saturate guard cell signaling network reveals a role of GDP-L-fucose metabolism in stomatal closure

Abstract

ABSTRACTGuard cells regulate plant gas exchange by controlling the aperture of stomatal pores. The process of stomatal closure involves a multi-input signaling network that governs the activity of ion channels, which in turn regulate guard cell turgor pressure and volume. Here we describe a forward genetic screen to identify novel components involved in stomatal movements. Through an ozone-sensitivity approach combined with whole-rosette gas exchange analysis, 130 mutants of established stomatal regulators and 76 novel mutants impaired in stomatal closure were identified. One of the novel mutants was mapped to MURUS1 (MUR1), the first enzyme in de novo GDP-L-fucose biosynthesis. Defects in synthesis or import of GDP-L-Fuc into the Golgi apparatus resulted in impaired stomatal closure to multiple stimuli. Stomatal phenotypes observed in mur1 were independent from the canonical guard cell signaling and instead could be related to altered mechanical properties of guard cell walls. Impaired fucosylation of xyloglucan, N-linked glycans and arabinogalactan proteins did not explain the aberrant function of mur1 stomata, however our data suggest that the stomatal phenotypes observed in mur1 can at least partially be attributed to defective dimerization of rhamnogalactouronan-II. In addition to providing the genetic framework for future studies on guard cell signaling, our work emphasizes the impact of fucose metabolism on stomatal movement.