Alternate binding mode of C-terminal phenethylamine analogs of G(t)alpha(340-350) to photoactivated rhodopsin.

The C-terminus of the Galpha-subunit of transducin plays an important role in receptor recognition. Synthetic peptides corresponding to the last 11 residues of the subunit have been shown to stabilize the photoactivated form of rhodopsin, Rh*. The Rh*-bound structure of the G(t)alpha(340-350) peptide has been determined using transferred nuclear overhauser effect NMR. In that structure, we observed two interactions between Lys341 and Phe350, a cation-pi interaction between the epsilon-amine and the aromatic ring of Phe350 and a salt-bridge between the epsilon-amine and the C-terminal carboxylate. A series of C-terminal phenethylamine analogs of the G(t)alpha(340-350) peptide were synthesized, lacking the C-terminal carboxylate group, to investigate the forces that contribute to the stability of the Rh*-bound conformation of the peptide. Rh*-stabilization assay data suggest that the C-terminal carboxylate is not necessary to maintain binding affinity. Transferred nuclear overhauser effect NMR experiments reveal that these C-terminal phenethylamine peptides adopt an Rh*-bound structure that is similar overall, but lacking some of the intramolecular interactions observed in the native Rh*-bound G(t)alpha(340-350) structure. These studies suggest that the binding site for G(t)alpha(340-350) on Rh* is adaptable, and we propose that the charged carboxylate of Phe350 does not play a significant role in the interaction with Rh*, but helps stabilize the Rh*-bound confirmation of the native peptide.

Relative strength of cation-pi vs salt-bridge interactions: the Gtalpha(340-350) peptide/rhodopsin system.

Interactions between cationic and aromatic side chains of amino acid residues, the so-called cation-pi interaction, are thought to contribute to the overall stability of the folded structure of peptides and proteins. The transferred NOE NMR structure of the G(t)alpha(340-350) peptide bound to photoactivated rhodopsin (R*) geometrically suggests a cation-pi interaction stabilizing the structure between the epsilon-amine of Lys341 and the aromatic ring of the C-terminal residue, Phe350. This interaction has been explored by varying substituents on the phenyl ring to alter the electron density of the aromatic ring of Phe350 and observing the impact on binding of the peptide to R*. The results suggest that while a cation-pi interaction geometrically exists in the G(t)alpha(340-350) peptide when bound to R*, its energetic contribution to the stability of the receptor-bound structure is relatively insignificant, as it was not observed experimentally. The presence of an adjacent and competing salt-bridge interaction between the epsilon-amine of Lys341 and the C-terminal carboxylate of Phe350 effectively shields the charge of the ammonium group. Experimental data supporting a significant cation-pi interaction can be regained through a series of Phe350 analogues where the C-terminal carboxyl has been converted to the neutral carboxamide, thus eliminating the shielding salt-bridge. TrNOE NMR experiments confirmed the existence of the cation-pi interaction in the carboxamide analogues. Various literature estimates of the strength of cation-pi interactions, including some that estimate strengths in excess of salt-bridges, are compromised by omission of the relevant anion in the calculations.

The NMR structure of a stable and compact all-beta-sheet variant of intestinal fatty acid-binding protein.

Intestinal fatty acid-binding protein (I-FABP) has a clam-shaped structure that may serve as a scaffold for the design of artificial enzymes and drug carriers. In an attempt to optimize the scaffold for increased access to the interior-binding cavity, several helix-less variants of I-FABP have been engineered. The solution-state NMR structure of the first generation helix-less variant, known as Delta17-SG, revealed a larger-than-expected and structurally ill-defined loop flanking the deletion site. We hypothesized that the presence of this loop, on balance, was energetically unfavorable for the stability of the protein. The structure exhibited no favorable pairwise or nonpolar interactions in the loop that could offset the loss of configurational entropy associated with the folding of this region of the protein. As an attempt to generate a more stable protein, we engineered a second-generation helix-less variant of I-FABP (Delta27-GG) by deleting 27 contiguous residues of the wild-type protein and replacing them with a G-G linker. The deletion site of this variant (D9 through N35) includes the 10 residues spanning the unstructured loop of Delta17-SG. Chemical denaturation experiments using steady-state fluorescence spectroscopy showed that the second-generation helix-less variant is energetically more stable than Delta17-SG. The three-dimensional structure of apo-Delta27-GG was solved using triple-resonance NMR spectroscopy along with the structure calculation and refinement protocols contained in the program package ARIA/CNS. In spite of the deletion of 27 residues, the structure assumes a compact all-beta-sheet fold with no unstructured loops and open access to the interior cavity.