AdiY Acts as a Cytoplasmic pH-Sensor via Histidine Protonation to Regulate Acid Stress Adaptation in Escherichia coli

The arginine-dependent acid resistance (Adi) system is a vital component that enables Escherichia coli and other enterobacteria to withstand the extreme acidity in the human gastrointestinal tract. It consists of the proton-consuming decarboxylation of arginine, catalyzed by AdiA, and the uptake of arginine, as well as the excretion of the more alkaline agmatine, catalyzed by the antiporter AdiC. The corresponding genes adiA and adiC are induced in E. coli under acidic conditions (pH < 5.5), a process that is tightly regulated by the AraC/XylS transcriptional activator AdiY. Here, we show that the pH-sensing mechanism of AdiY functions through the protonation of two histidines (His34 and His60) in the N-terminal domain. Replacing these histidine residues with alanine, glutamine or aspartate abolishes the pH-dependent activation of AdiY, both in vivo , as demonstrated by promoter-reporter assays, and in vitro , as indicated by the loss of DNA-binding activity detected by surface plasmon resonance spectroscopy. Biochemical analyses of purified wild-type AdiY using size-exclusion chromatography and intrinsic tryptophan fluorescence revealed a pronounced and reversible pH-dependent conformational change that does not occur in the pH-sensing–deficient AdiY variant. A model is proposed in which AdiY forms a monomer at physiological pH. At a lower intracellular pH, the protonation of histidine in AdiY causes a conformational change that leads to the binding of AdiY as a tetramer to the DNA. This work elucidates the molecular mechanism of a one-component signal transduction system that combines both sensory and responsive functions.