De novo design of a monomeric three-stranded antiparallel beta-sheet

Position effect of cross-strand side-chain interactions on beta-hairpin formation

Previous conformational analysis of 10-residue linear peptides enabled us to identify some cross-strand side-chain interactions that stabilize beta-hairpin conformations. The stabilizing influence of these interactions appeared to be greatly reduced when the interaction was located at the N- and C-termini of these 10-residue peptides. To investigate the effect of the position relative to the turn of favorable interactions on beta-hairpin formation, we have designed two 15-residue beta-hairpin forming peptides with the same residue composition and differing only in the location of two residues within the strand region. The conformational properties of these two peptides in aqueous solution were studied by 1H and 13C NMR. Differences in the conformational behavior of the two designed 15-residue peptides suggest that the influence of stabilizing factors for beta-hairpin formation, in particular, cross-strand side-chain interactions, depends on their proximity to the turn. Residues adjacent to the turn are most efficient in that concern. This result agrees with the proposal that the turn region acts as the driving force in beta-hairpin folding.

Synthetic protein design: construction of a four-stranded beta-sheet structure and evaluation of its integrity in methanol-water systems

The characterization of a four-stranded beta-sheet structure in a designed 26-residue peptide Beta-4 is described. The sequence of Beta-4 (Arg-Gly-Thr-Ile-Lys-(D)pro-Gly-Ile-Thr-Phe-Ala-(D)Pro-Ala-Thr-Val-Leu-P he-Ala-Val-(D)Pro-Gly-Lys-Thr-Leu-Tyr-Arg) was chosen such that three strategically positioned (D)Pro-Xxx segments nucleate type II' beta-turns, which facilitate hairpin extension. A four-stranded beta-sheet structure is determined in methanol from 500 MHz 1H NMR data using a total of 100 observed NOEs, 11 dihedral restraints obtained from vicinal JCalphaH-NH values and 10 hydrogen bonding constraints obtained from H/D exchange data. The observed NOEs provide strong evidence for a stable four-stranded sheet and a nonpolar cluster involving Ile8, Phe10, Val15 and Phe17. Circular dichroism studies in water-methanol mixtures provide evidence for melting of the beta-sheet structure at high water concentrations. NMR analysis establishes that the four-stranded sheet in Beta-4 is appreciably populated in 50% (v/v) aqueous methanol. In water, the peptide structure is disorganized, although the three beta-turn nuclei appear to be maintained.

Folding simulations of a three-stranded antiparallel beta -sheet peptide

Protein folding is a grand challenge of the postgenomic era. In this paper, 58 folding events sampled during 47 molecular dynamics trajectories for a total simulation time of more than 4 micros provide an atomic detail picture of the folding of a 20-residue synthetic peptide with a stable three-stranded antiparallel beta-sheet fold. The simulations successfully reproduce the NMR solution conformation, irrespective of the starting structure. The sampling of the conformational space is sufficient to determine the free energy surface and localize the minima and transition states. The statistically predominant folding pathway involves the formation of contacts between strands 2 and 3, starting with the side chains close to the turn, followed by association of the N-terminal strand onto the preformed 2-3 beta-hairpin. The folding mechanism presented here, formation of a beta-hairpin followed by consolidation, is in agreement with a computational study of the free energy surface of another synthetic three-stranded antiparallel beta-sheet by Bursulaya and Brooks [(1999) J. Am. Chem. Soc. 121, 9947-9951]. Hence, it might hold in general for antiparallel beta-sheets with short turns.

Comparative conformational analysis of peptide libraries

Six computer-based combinatorial libraries, including tetrapeptide sequences (generated with five amino acids) and conformations (generated with five main chain and three side chain rotamers), were obtained and sequence-conformation probabilities were calculated with a molecular and statistical mechanics procedure. The structural motifs alpha-helix, beta-sheet, 3(10)-helix, reverse turn I and gamma-turn were focused in these calculations. It is shown that sequence-conformation-probability surfaces provide a broad view of structural changes accompanying changes in sequence. Numerical indices are defined to enable comparisons between frequencies of occurrence of these structural motifs in peptide libraries and in a database of low sequence identity protein structures. Fine details of sequence-conformation-probability surfaces show the effect of point mutations. Broad comparisons between different regions of these surfaces indicate how to select the occurrence of structural motifs in the combinatorial synthesis of peptide chains.

Synthesis and NMR solution structure of an alpha-helical hairpin stapled with two disulfide bridges

Helical coiled-coils and bundles are some of the most common structural motifs found in proteins. Design and synthesis of alpha-helical motifs may provide interesting scaffolds that can be useful as host structures to display functional sites, thus allowing the engineering of novel functional miniproteins. We have synthesized a 38-amino acid peptide, alpha2p8, encompassing the alpha-helical hairpin present in the structure of p8MTCP1, as an alpha-helical scaffold particularly promising for its stability and permissiveness of sequence mutations. The three-dimensional structure of this peptide has been solved using homonuclear two-dimensional NMR techniques at 600 MHz. After sequence specific assignment, a total of 285 distance and 29 dihedral restraints were collected. The solution structure of alpha2p8 is presented as a set of 30 DIANA structures, further refined by restrained molecular dynamics, using simulated annealing protocol with the AMBER force field. The RMSD values for the backbone and all heavy atoms are 0.65+/-0.25 and 1.51+/-0.21 A, respectively. Excised from its protein context, the alpha-hairpin keeps its native structure: an alpha-helical coiled-coil, similar to that found in superhelical structures, with two helices spanning residues 4-16 and 25-36, and linked by a short loop. This motif is stabilized by two interhelical disulfide bridges and several hydrophobic interactions at the helix interface, leaving most of its solvent-exposed surface available for mutation. This alpha-helical hairpin, easily amenable to synthetic chemistry and biological expression system, may represent a stable and versatile scaffold to display new functional sites and peptide libraries.

Molecular dynamics simulations of a beta-hairpin fragment of protein G: balance between side-chain and backbone forces

How is the native structure encoded in the amino acid sequence? For the traditional backbone centric view, the dominant forces are hydrogen bonds (backbone) and phi-psi propensity. The role of hydrophobicity is non-specific. For the side-chain centric view, the dominant force of protein folding is hydrophobicity. In order to understand the balance between backbone and side-chain forces, we have studied the contributions of three components of a beta-hairpin peptide: turn, backbone hydrogen bonding and side-chain interactions, of a 16-residue fragment of protein G. The peptide folds rapidly and cooperatively to a conformation with a defined secondary structure and a packed hydrophobic cluster of aromatic side-chains. Our strategy is to observe the structural stability of the beta-hairpin under systematic perturbations of the turn region, backbone hydrogen bonds and the hydrophobic core formed by the side-chains, respectively. In our molecular dynamics simulations, the peptides are solvated. with explicit water molecules, and an all-atom force field (CFF91) is used. Starting from the original peptide (G41EWTYDDATKTFTVTE56), we carried out the following MD simulations. (1) unfolding at 350 K; (2) forcing the distance between the C(alpha) atoms of ASP47 and LYS50 to be 8 A; (3) deleting two turn residues (Ala48 and Thr49) to form a beta-sheet complex of two short peptides, GEWTYDD and KTFTVTE; (4) four hydrophobic residues (W43, Y45, F52 and T53) are replaced by a glycine residue step-by-step; and (5) most importantly, four amide hydrogen atoms (T44, D46, T53, and T55, which are crucial for backbone hydrogen bonding), are substituted by fluorine atoms. The fluorination not only makes it impossible to form attractive hydrogen bonding between the two beta-hairpin strands, but also introduces a repulsive force between the two strands due to the negative charges on the fluorine and oxygen atoms. Throughout all simulations, we observe that backbone hydrogen bonds are very sensitive to the perturbations and are easily broken. In contrast, the hydrophobic core survives most perturbations. In the decisive test of fluorination, the fluorinated peptide remains folded under our simulation conditions (5 ns, 278 K). Hydrophobic interactions keep the peptide folded, even with a repulsive force between the beta-strands. Thus, our results strongly support a side-chain centric view for protein folding.

beta-hairpin stability and folding: molecular dynamics studies of the first beta-hairpin of tendamistat

The stability and (un)folding of the 19-residue peptide, SCVTLYQSWRYSQADNGCA, corresponding to the first beta-hairpin (residues 10 to 28) of the alpha-amylase inhibitor tendamistat (PDB entry 3AIT) has been studied by molecular dynamics simulations in explicit water under periodic boundary conditions at several temperatures (300 K, 360 K and 400 K), starting from various conformations for simulation lengths, ranging from 10 to 30 ns. Comparison of trajectories of the reduced and oxidized native peptides reveals the importance of the disulphide bridge closing the beta-hairpin in maintaining a proper turn conformation, thereby insuring a proper side-chain arrangement of the conserved turn residues. This allows rationalization of the conservation of those cysteine residues among the family of alpha-amylase inhibitors. High temperature simulations starting from widely different initial configurations (native beta-hairpin, alpha and left-handed helical and extended conformations) begin sampling similar regions of the conformational space within tens of nanoseconds, and both native and non-native beta-hairpin conformations are recovered. Transitions between conformational clusters are accompanied by an increase in energy fluctuations, which is consistent with the increase in heat capacity measured experimentally upon protein folding. The folding events observed in the various simulations support a model for beta-hairpin formation in which the turn is formed first, followed by hydrogen bond formation closing the hairpin, and subsequent stabilization by side-chain hydrophobic interactions.

Biophysical characterization of betabellin 16D: a beta-sandwich protein that forms narrow fibrils which associate into broad ribbons

The betabellin structure is a de novo designed beta-sandwich protein consisting of two 32-residue beta sheets packed against one another by hydrophobic interactions. Betabellin 16S (B16S), a 32-residue peptide chain (HSLTAKIakLTFSIAahTYTCAVakYTAKVSH, where a is DAla, h is DHis, and k is DLys), did not have beta structure in water at pH 6.5. Air oxidation of B16S furnished betabellin 16D (B16D), a 64-residue disulfide-bridged two-chain protein, which also did not fold in water at pH 6.5. However, the extent of beta structure observed for B16D increased with pH and ionic strength of the solution and the B16D concentration as observed by circular dichroism spectropolarimetry. Transmission electron microscopy showed that B16D formed narrow fibrils that associated into broad ribbons in 5.0 mM Mops and 0.25 M NaCl at pH 6.9.

Elementary steps in protein folding

The mechanism of protein folding is under intense theoretical and experimental investigation. From stopped-flow mixing experiments we have detailed knowledge of processes slower than about 1 ms, but until recently little was known about folding and unfolding reactions on the microsecond to nanosecond time scale. The use of novel techniques allowed to explore the elementary steps in protein folding, such as intrachain diffusion and formation of alpha-helices, beta-hairpins and loop structures. This brief review discusses the time scales of these early elementary events which are crucial for the understanding of how proteins fold.