Gβγ dimers mediate low K+ stress‐inhibited root growth via modulating auxin redistribution in Arabidopsis.

In the investigation of heterotrimeric G protein‐mediated signal transduction in planta, their roles in the transmittance of low K+ stimuli remain to be elucidated. Here, we found that the primary root growth of wild‐type Arabidopsis was gradually inhibited with the decrease of external K+ concentrations, while the primary root of the mutants for G protein β subunit AGB1 and γ subunits AGG1, AGG2 and AGG3 could still grow under low K+ conditions (LK). Exogenous NAA application attenuated primary root elongation in agb1 and agg1/2/3 but promoted the growth in wild‐type seedlings under LK stress. Using ProDR5:GFP, ProPIN1:PIN1‐GFP and ProPIN2:PIN2‐GFP reporter lines, a diminishment in auxin concentration at the radicle apex and a reduction in PIN1and PIN2 efflux carrier abundance were observed in wild‐type roots under LK, a phenomenon not recorded in the agb1 and agg1/2/3. Further proteolytic and transcriptional assessments revealed an enhanced degradation of PIN1 and a suppressed expression of PIN2 in the wild‐type background under LK, contrasting with the stability observed in the agb1 and agg1/2/3 mutants. Our results indicate that the G protein β and γ subunits play pivotal roles in suppressing of Arabidopsis root growth under LK by modulating auxin redistribution via alterations in PIN1 degradation and PIN2 biosynthesis. Summary statement: We demonstrate that Gβγ dimers modulate auxin distribution at the root tip via the auxin efflux transporters PIN1/PIN2, consequently enhancing the adaptive response of plant roots to low K+ conditions. This underscores the critical role of G protein β and γ subunits in the morphogenetic processes of root architecture under low K+ stress. [ABSTRACT FROM AUTHOR]