Cytokinin Targets Auxin Transport to Promote Shoot Branching

Overview

Journal Plant Physiol

Specialty Physiology

Date 2018 May 3

PMID 29717021

Citations 72

Authors

Tanya Waldie

Ottoline Leyser

Affiliations

Soon will be listed here.

Abstract

Cytokinin promotes shoot branching by activating axillary buds, but its mechanism of action in Arabidopsis () in this process is unclear. We have shown previously that a hextuple mutant lacking a clade of type-A Arabidopsis Response Regulators (ARRs) known to act in cytokinin signaling has reduced shoot branching compared with the wild type. Since these proteins typically act as negative regulators of cytokinin signaling, this is an unexpected result. To explore this paradox more deeply, we characterized the effects of loss of function of the type-B ARR, ARR1, which positively regulates cytokinin-induced gene expression. The mutant has increased branching, consistent with a role antagonistic to the type-A ARRs but in apparent conflict with the known positive role for cytokinin in bud activation. We show that the branching phenotypes correlate with increases in stem auxin transport and steady-state levels of the auxin export proteins PIN3 and PIN7 on the plasma membrane of xylem-associated cells in the main stem. Cytokinin treatment results in an increased accumulation of PIN3, PIN7, and the closely related PIN4 within several hours, and loss of , , and can partially rescue the branching phenotype. This suggests that there are multiple signaling pathways for cytokinin in bud outgrowth; one of these pathways regulates PIN proteins in shoots, independently of the canonical signaling function of the genes tested here. A hypothesis consistent with the shoot phenotypes is that feedback control of biosynthesis leads to altered cytokinin accumulation, driving cytokinin signaling via this pathway.

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