Consequences of amino acid insertions and/or deletions in transmembrane helix C of bacteriorhodopsin.

Abstract

Six bacterioopsin mutants containing either single amino acid deletions (delta A84, delta L87), insertions (delta 85A, delta 88A), or both deletions and insertions (delta A84/delta 88A, delta 85A/delta L87) within the first two turns of transmembrane helix C, starting from the extracellular side, have been prepared. The mutant apoproteins refold in phospholipid/detergent micelles and display secondary structures similar to that of the wild type. However, the mutants delta 88A and delta A84/delta 88A do not form a chromophore with retinal. The regenerated chromophore of delta 85A displays absorption maxima and retinal isomer compositions in the dark- and light-adapted states similar to those of the wild type. In delta A84, delta L87, and delta 85A/delta L87 these chromophore properties are altered, and the structures are less stable than that of the wild type, as shown by an enhanced rate of reaction with hydroxylamine in the dark, an increased pKa of the denaturation at acidic pH, and a decreased pKa of Schiff base deprotonation. Proton translocation is abolished in the delta A84 and delta 85A/delta L87 mutants, whereas in delta 85A and delta L87 the activity is reduced to about 25% of the wild-type value at pH 6. The overall properties of the delta 85A, delta 85A/delta L87, and delta L87 mutants indicate that the deletions and/or insertions result in displacement of residues Arg-82, Asp-85, or Asp-96, respectively, which participate in proton translocation. The results are compatible with a helical structure for transmembrane segment C and emphasize the flexibility of intramolecular contacts in bacteriorhodopsin.