Role of carboxyl-terminal charges on S-modulin membrane affinity and inhibition of rhodopsin phosphorylation.

Abstract

S-Modulin shows a higher affinity for urea-stripped frog rod outer segment membranes than s26 (a cone homologue of S-modulin). NaCl at a concentration of several hundred millimolar reduced the membrane affinity of S-modulin to the s26 level. Chimeric S-modulin and s26 whose respective 23 and 29 amino acids at the carboxyl terminus were swapped showed membrane affinites similar to those of s26 and S-modulin, respectively. The membrane affinity of an S-modulin mutant lacking C-terminal positive charges was reduced to the s26 level, while another S-modulin mutant lacking C-terminal negative charges has a higher membrane affinity than wild-type S-modulin. When the molar ratio of recombinant S-modulins to rhodopsin is 0.5, there was no large difference in the inhibition efficiency. However, S-modulin and mutants with high membrane affinities inhibit rhodopsin phosphorylation more efficiently than s26 and mutants with low membrane affinities at the molar ratio of 0.1. These results indicate that the C-terminal positive charges of these Ca2+-binding proteins enhance the membrane affinity and the inhibitory effect on rhodopsin phosphorylation by increasing the concentration of S-modulin on the membrane.