Abstract
Known RGS proteins stimulate GTPase activity of Gi and Gq family members, but do not interact with Gsalpha and G12alpha. To determine the role of specific Galpha residues for RGS protein recognition, six RGS contact residues of chimeric transducin alpha-subunit (Gtalpha) corresponding to the residues that differ between Gialpha and Gsalpha have been replaced by Gsalpha residues. The ability of human retinal RGS (hRGSr) to bind mutant Gtalpha subunits and accelerate their GTPase activity was investigated. Substitutions Thr178 --> Ser, Ile181 --> Phe, and Lys205 --> Arg of Gtalpha did not alter its interaction with hRGSr. The Lys176 --> Leu mutant had the same affinity for hRGSr as Gtalpha, but the maximal GTPase stimulation by hRGSr was reduced by approximately 2.5-fold. The substitution His209 --> Gln led to a 3-fold decrease in the affinity of hRGSr for the Gtalpha mutant without significantly affecting the maximal GTPase enhancement. The Ser202 --> Asp mutation abolished Gtalpha recognition by hRGSr. A counteracting replacement of Glu129 by Ala in hRGSr did not restore the interaction of hRGSr with the Gtalpha Ser202 --> Asp mutant. Our data suggest that the Ser residue at position 202 of Gtalpha is critical for the specificity of RGS proteins toward Gi and Gq families of G-proteins. Consequently, the corresponding residue, Asp229 of Gsalpha, is likely responsible for the inability of RGS proteins to interact with Gsalpha.
Highlights
G-proteins by stimulating their GTPase activity (6 –10)
We have carried out mutational analysis of specific amino acid residues of chimeric Gt␣ corresponding to the RGS contact residues that are different between Gi␣ and Gs␣ to determine their specific role for RGS protein recognition
The family of RGS proteins has been rapidly growing. Those RGS proteins that have already been extensively characterized share a common specificity pattern. These RGS proteins interact with G-protein ␣-subunits from Gi and Gq families but have no activity toward Gs (6 – 8, 10) and G12 [9]
Summary
G-proteins by stimulating their GTPase activity (6 –10). Identification of RGS proteins has helped to solve a long standing discrepancy between the fast signal termination in vivo and relatively slow intrinsic GTPase rates typically observed under in vitro conditions [6, 11]. Effects of hRGSr on GTPase Activity of Gt␣ Mutants—Six residues directly interacting with RGS4 are different in Gi␣1 and Gs␣ [12].
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