High-throughput screening and structure-guided design of small molecules enable modulation of SAL-PAP stress signaling

Chloroplasts sense environmental stress and activate chloroplast-to-nucleus retrograde signalling, reprogramming nuclear gene expression to drive plant acclimation. One such pathway is regulated by the chloroplastic phosphatase, SAL, which hydrolyses the nucleotide signal 3'-phosphoadenosine 5'-phosphate (PAP). In Arabidopsis thaliana, genetic loss of AtSAL1 elevates PAP and enhances stress tolerance but causes pleiotropic growth defects, complicating the interpretation of the role of PAP in cellular signalling. To uncouple stress signalling from genetic pleiotropy, we conducted a high-throughput in vitro screen of 13,000 small molecules and identified V20, a competitive inhibitor of AtSAL1 with three-fold greater potency than the known Li ⁺ inhibitor. Structural analoguing of V20 and biochemical assays defined key pharmacophore features required for inhibition, including an ortho-halogenated aromatic ring, hydrogen-bond donor capacity at the triazole carboxamide, and electron-withdrawing substitutions that enhance π-π stacking with aromatic residues. Accelerated molecular dynamics simulations using a new high-resolution crystal structure revealed two previously uncharacterised V20 binding pockets adjacent to the catalytic site. V20 binding induces conformational changes that restrict substrate access to the catalytic site. Exogenous application of V20 to Arabidopsis led to increased PAP accumulation, activated PAP-responsive gene expression and enhanced oxidative tolerance, demonstrating cellular uptake and in vivo efficacy in the energy organelles, chloroplasts and mitochondria, where AtSAL1 is localised. Collectively, our findings reveal new insights into the regulatory domains of SAL enzymatic activity for control of PAP-mediated signalling and establish a proof-of-concept for targeted chemical modulation of SAL activity, which offers novel strategies to selectively manipulate chloroplast-to-nucleus retrograde signalling in plants.