Effect of pH, urea, peptide length, and neighboring amino acids on alanine alpha-proton random coil chemical shifts.

Accurate random coil alpha-proton chemical shift values are essential for precise protein structure analysis using chemical shift index (CSI) calculations. The current study determines the chemical shift effects of pH, urea, peptide length and neighboring amino acids on the alpha-proton of Ala using model peptides of the general sequence GnXaaAYaaGn, where Xaa and Yaa are Leu, Val, Phe, Tyr, His, Trp or Pro, and n = 1-3. Changes in pH (2-6), urea (0-1M), and peptide length (n = 1-3) had no effect on Ala alpha-proton chemical shifts. Denaturing concentrations of urea (8M) caused significant downfield shifts (0.10 +/- 0.01 ppm) relative to an external DSS reference. Neighboring aliphatic residues (Leu, Val) had no effect, whereas aromatic amino acids (Phe, Tyr, His and Trp) and Pro caused significant shifts in the alanine alpha-proton, with the extent of the shifts dependent on the nature and position of the amino acid. Smaller aromatic residues (Phe, Tyr, His) caused larger shift effects when present in the C-terminal position (approximately 0.10 vs. 0.05 ppm N-terminal), and the larger aromatic tryptophan caused greater effects in the N-terminal position (0.15 ppm vs. 0.10 C-terminal). Proline affected both significant upfield (0.06 ppm, N-terminal) and downfield (0.25 ppm, C-terminal) chemical shifts. These new Ala correction factors detail the magnitude and range of variation in environmental chemical shift effects, in addition to providing insight into the molecular level interactions that govern protein folding.

Paralog-selective ligands for bcl-2 proteins.

There is considerable current interest in molecules that bind intra- or extracellular protein surfaces and inhibit protein-protein interactions. Previously we have reported that miniature proteins based on pancreatic-fold polypeptides can recognize even shallow alpha-helix binding clefts with high affinity and selectivity against unrelated proteins. One such miniature protein, PPBH3-1, binds the anti-apoptotic protein paralogs Bcl-2 and Bcl-XL with nanomolar affinity and a DeltaDeltaG = 1.2 kcal.mol-1 preference for Bcl-XL. Here we describe the directed evolution of PPBH3-1 into two new miniature proteins, PPBH3-5 and PPBH3-6, whose paralog specificity is reversed relative to PPBH3-1. PPBH3-5 and PPBH3-6 bind Bcl-2 with nanomolar affinity and a DeltaDeltaG = 0.9-1.3 kcal.mol-1 preference for Bcl-2 over Bcl-XL. Experiments with Bcl-XL variants suggest that PPBH3-5 and PPBH3-6 achieve high paralog specificity by exploiting subtle structural or electrostatic differences in the Bcl-2 and Bcl-XL molecular landscapes. PPBH3-5 and PPBH3-6 may have unique applications as early examples of nonnatural ligands that interact selectively with Bcl-2 proteins.