Self-regulation of PIN1-driven auxin transport by cell surface-based auxin signaling inArabidopsis

Abstract

AbstractPIN-FORMED (PIN)-driven auxin transport contributes to establishing and maintaining a dynamic auxin concentration gradient alongside plant tissues, which drives the majority of developmental processes in plants. To maintain developmental plasticity in ever-changing environments, plants have evolved self-organizing feedback machinery between auxin signaling and its transport, which has been shown to play essential roles in many fundamental plant processes. However, the molecular mechanism behind this mutual regulation has not yet been clarified. Here, we identified a cell surface-triggered auxin signaling that regulates the PIN1-mediated auxin efflux and further developmental patterning inArabidopsis. Auxin was able to stimulate PIN1 phosphorylation in plants through transmembrane kinases (TMKs), key components in auxin signaling, at the plasma membrane. TMK1 and TMK4 directly interacted with and phosphorylated PIN1 and functioned redundantly in the regulation of PIN1 polarity in plant cells. The phosphorylation sites in PIN1 proteins, targeted by both auxin and TMKs, were required for PIN1 trafficking and polarity, which further controlled auxin responses and downstream developmental patterning inArabidopsis. Therefore, our findings provide a direct mechanism for the self-regulation between auxin signaling and transport that drives the auxin flows and proper development in plants.