A Point Mutation (G338S) and Its Suppressor Mutations Affect Both the pH Response of the NhaA-Na+/H+ Antiporter as Well as the Growth Phenotype of Escherichia coli

pH controls the activity of the NhaA Na+/H+ antiporter of Escherichia coli. In the present work we show that replacement of glycine 338 of NhaA with serine (G338S) alleviates the pH control of the antiporter. Monitoring Na+-dependent collapse of ΔpH, to assess antiporter activity in isolated membrane vesicles, shows that the mutant protein is practically independent of pH, between pH 7 and 9, and even at pH 6 is 70% active. Similarly the purified reconstituted mutant protein catalyzes pH-independent passive efflux of22Na from proteoliposomes as well as ΔpH-driven influx. Whereas the native NhaA in isolated membrane vesicles is exposed to digestion by trypsin only above pH 7, the mutated protein is degraded already at pH 6.5. ΔnhaAΔnhaB cells transformed with a plasmid encoding the pH-independent antiporter are sensitive to Na+ but not to K+ at alkaline pH, while growing in the presence of both ions at neutral pH. Several possibilities that could explain the Na+ sensitivity of the mutant at alkaline pH were excluded; Western analysis and measurement of Na+/H+ antiporter activity in membrane vesicles, isolated from cells shifted to the non-permissive growth conditions, showed neither reduced expression of G338S-NhaA nor defective activity. The finding that the mutated protein is electrogenic led to the retraction of the idea that the protein is active in vitro but not in vivo at alkaline pH, when only Δψ exists in the cells. The Na+ concentration needed for half-maximal activity of G338S in isolated everted membrane vesicles is similar to that of the wild type. Therefore an increase in intracellular Na+ due to a reduced antiporter affinity could not explain the results. It is suggested that the loss of growth at alkaline pH in the presence of Na+ is due to the loss of the pH control of the mutated NhaA. Indeed, in the four mutations suppressing G338S phenotype, growth at alkaline pH was restored together with the pH regulation of NhaA. Three of the four suppressor mutations cluster in helix IV, whereas the original mutation is in helix XI, suggesting that the two helixes interact.