Abstract
Optimizing the photoprotection of different leaves as a whole is important for plants to adapt to fluctuations in ambient light conditions. However, the molecular basis of this leaf-to-leaf communication is poorly understood. Here, we used a range of techniques, including grafting, chlorophyll fluorescence, revers transcription quantitative PCR, immunoblotting, chromatin immunoprecipitation, and electrophoretic mobility shift assays, to explore the complexities of leaf-to-leaf light signal transmission and activation of the photoprotective response to light fluctuation in tomato (Solanum lycopersicum). We established that light perception in the top leaves attenuated the photoinhibition of both PSII and PSI by triggering photoprotection pathways in the bottom leaves. Local light promoted the accumulation and movement of LONG HYPOCOTYL5 from the sunlit local leaves to the systemic leaves, priming the photoprotective response of the latter to light fluctuation. By directly activating the transcription of PROTON GRADIENT REGULATION5 and VIOLAXANTHIN DE-EPOXIDASE, LONG HYPOCOTYL5 induced cyclic electron flow, the xanthophyll cycle, and energy-dependent quenching. Our findings reveal a systemic signaling pathway and provide insight into an elaborate regulatory network, demonstrating a pre-emptive advantage in terms of the activation of photoprotection and, hence, the ability to survive in a fluctuating light environment.