A circadian rheostat drives proton electrochemical gradients to optimize cell-type-specific growth in Arabidopsis
Summary
Plant growth relies on the activity of key transcription factors. Here, we uncover a mechanism for organ-specific growth driven by opposing electrochemical signals that propagate in a cell-type-specific manner. Using a genetically encoded pH sensor and a pH-sensitive dye, we show that apoplastic pH in epidermal cells oscillates antiphasically relative to phloem pH. The clock component CCA1 lowers apoplastic pH in hypocotyl epidermal cells while increasing it in companion cells. This opposi
Content
# A circadian rheostat drives proton electrochemical gradients to optimize cell-type-specific growth in Arabidopsis
*Published: 2026 Mar 19*
Plant growth relies on the activity of key transcription factors. Here, we
uncover a mechanism for organ-specific growth driven by opposing electrochemical
signals that propagate in a cell-type-specific manner. Using a genetically
encoded pH sensor and a pH-sensitive dye, we show that apoplastic pH in
epidermal cells oscillates antiphasically relative to phloem pH. The clock
component CCA1 lowers apoplastic pH in hypocotyl epidermal cells while
increasing it in companion cells. This opposing regulation promotes hypocotyl
growth but inhibits root elongation. Mechanistically, CCA1 activates auxin
signaling in shoots while repressing sucrose transporter 2 and the electrogenic
(H+)-pump ATPase AHA3 by directly binding their promoters. The repression
decreases sucrose loading into the phloem and slows transport velocity.
Expressing CCA1 in the phloem is sufficient to inhibit root elongation, whereas
AHA3 overexpression in CCA1 overexpressing seedlings rescues root growth. Thus,
a circadian rheostat orchestrates electrochemical signals to optimize source
capacity with sink demand.
DOI: 10.1016/j.cell.2025.12.056