The effect of detergents on trimeric G-protein activity in isolated plasma membranes from rat brain cortex: Correlation with studies of DPH and Laurdan fluorescence

The effect of non-ionic detergents on baclofen (GABA_B-R agonist)-stimulated G-protein activity was measured as a [³⁵S]GTPγS binding assay in the plasma membranes (PM) isolated from the brain tissue. The effect was clearly biphasic — a decrease in the activity was followed by an activation maximum and finally, at high concentrations, drastic inhibition of the G-protein activity was noticed. Contrarily, specific radioligand binding to GABA_B-receptor was inhibited in the whole range of detergent concentrations step by step, i.e. it was strictly monophasic. The magnitude of both detergent effects was decreased in the same order of potency: Brij58 > Triton X-100 > Digitonin. The identical order was found when comparing detergents ability to alter fluorescence anisotropy of the membrane probe 1,6-diphenyl-1,3,5-hexatriene (r_DPH) incorporated into the hydrophobic PM interior. Decrease of r_DPH, in the order of Brij58 > Triton X-100 > Digitonin, was reflected as decrease of the S-order parameter and rotation correlation time ? paralleled by an increase of diffusion wobbling constant D_w (analysis by time-resolved fluorescence according to “wobble-in-cone” model). The influence of the detergents on the membrane organization at the polar headgroup region was characterized by Laurdan generalized polarization (GP). As before, the effect of detergents on GP parameters proceeded in the order: Brij58 > Triton X-100 > Digitonin.     

Evolution of Class-Specific Peptides Targeting a Hot Spot of the Gαs Subunit

The four classes of heterotrimeric G-protein α subunits act as molecular routers inside cells, gating signals based on a bound guanosine nucleotide (guanosine 5′-triphosphate versus guanosine 5′-diphosphate). Ligands that specifically target individual subunits provide new tools for monitoring and modulating these networks, but are challenging to design due to the high sequence homology and structural plasticity of the Gα-binding surface. Here we have created an mRNA display library of peptides based on the short Gα-modulating peptide R6A-1 and selected variants that target a convergent protein-binding surface of Gαs·guanosine 5′-diphosphate. After selection/evolution, the most Gαs-specific peptide, Gαs(s)-binding peptide (GSP), was used to design a second-generation library, resulting in several new affinity- and selectivity-matured peptides denoted as mGSPs. The two-step evolutionary walk from R6A-1 to mGSP-1 resulted in an 8000-fold inversion in binding specificity, altered seven out of nine residues in the starting peptide core, and incorporated both positive and negative design steps. The resulting mGSP-1 peptide shows remarkable selectivity and affinity, exhibiting little or no binding to nine homologous Gα subunits or human H-Ras, and even discriminates the Gαs splice variant Gαs(l). Selected peptides make specific contacts with the effector-binding region of Gα, which may explain an interesting bifunctional activity observed in GSP. Overall, our work demonstrates a design of simple, linear, highly specific peptides that target a protein-binding surface of Gαs and argues that mRNA display-based selection/evolution is a powerful route for targeting protein families with high class specificity and state specificity.