Effect of Substituting of Amino Acids Residues Ser-911 and Thr-912 in the Plasma Membrane H+-ATPase of Yeast <i>Saccharomyces cerevisiae</i> on Its Activity and Distribution of Polyphosphates

Abstract

The vital enzyme of yeast metabolism, plasma membrane H+-ATPase (PMA1), is phosphorylated during folding and functioning. The main phosphorylation sites are Ser911 and Thr-912 in the C-terminal regulatory domain. The work used wild and mutant forms of the enzyme with substitutions of these amino acid residues with Ala or Asp to determine their role in the functioning of the ATPase and the distribution of polyphosphates (polyP) by fractions. Growth parameters, ATP content, and in situ polyP distribution were determined on whole cells. To determine the ATPase activity in vitro, plasma membranes containing wild-type enzyme and mutant forms were isolated. Mutants S911D, T912D and S911D/T912A had ATPase activity close to the wild type; mutant S911A had increased activity. The growth rate of strains S911D, T912D and S911D/T912A was 2.0‒3.0 times lower than that of the wild type, and the growth rate of S911A was close to the wild type. Mutations S911D and S911D/T912A caused a decrease in ATP content by 2.0‒2.5 times. All substitutions affected the distribution of polyP by fractions. The effect depended on the chemical nature of the substitution: in the case of replacement with Asp, which changes the type of phosphosite, there was a decrease in the polyR1 fraction and an increase in the polyR2 fraction; when replaced with Ala, which removes phosphosite, the effect was the opposite. The content of the polyP3 fraction increased in all mutants. The data indicate that the residues of Ser911 and Thr-912 are important not only for the normal functioning of the PMA of H+-ATPase, but also for the regulation of phosphorus and energy metabolism.