Direct sulphate-TOR signalling controls transcriptional reprogramming for shoot apex activation in Arabidopsis

Abstract

AbstractPhotosynthetic plants play a primary role for the global sulphur cycle in the earth ecosystems by reduction of inorganic sulphate from the soil to organic sulphur-containing compounds. How plants sense and transduce the sulphate availability in soil to mediate their growth remains largely unclear. The target of rapamycin (TOR) kinase is an evolutionarily conserved master regulator of nutrient sensing and metabolic signalling to control cell proliferation and growth in all eukaryotes. Here, we discovered that inorganic sulphate exhibits higher potency than organic cysteine and glutathione for activation of TOR and cell proliferation in the leaf primordium to promote true leaf development in Arabidopsis. Chemical genetic analyses further revealed that this sulphate activation of TOR is independent of the sulphate-assimilation process and glucose-energy signalling. Significantly, tissue specific transcriptome analyses uncovered previously unknown sulphate-orchestrating genes involved in DNA replication, cell proliferation, autophagy and various secondary metabolism pathways, which are completely depending on TOR signalling. Systematic comparison between the sulphate- and glucose-TOR controlled transcriptome further revealed that, as the central growth integrator, TOR kinase can sense different upstream nutrient signals to control both shared and unique transcriptome networks, therefore, precisely modulate plant proliferation, growth and stress responses.