Dehydration-driven solvent exposure of hydrophobic surfaces as a driving force in peptide folding

Hydrated and dehydrated tertiary interactions--opening and closing--of a four-helix bundle peptide

The structural heterogeneity and thermal denaturation of a dansyl-labeled four-helix bundle homodimeric peptide was studied with steady-state and time-resolved fluorescence spectroscopy and with circular dichroism (CD). At room temperature the fluorescence decay of the polarity-sensitive dansyl, located in the hydrophobic core region, can be described by a broad distribution of fluorescence lifetimes, reflecting the heterogeneous microenvironment. However, the lifetime distribution is nearly bimodal, which we ascribe to the presence of two major conformational subgroups. Since the fluorescence lifetime reflects the water content of the four-helix bundle conformations, we can use the lifetime analysis to monitor the change in hydration state of the hydrophobic core of the four-helix bundle. Increasing the temperature from 9 degrees C to 23 degrees C leads to an increased population of molten-globule-like conformations with a less ordered helical backbone structure. The fluorescence emission maximum remains constant in this temperature interval, and the hydrophobic core is not strongly affected. Above 30 degrees C the structural dynamics involve transient openings of the four-helix bundle structure, as evidenced by the emergence of a water-quenched component and less negative CD. Above 60 degrees C the homodimer starts to dissociate, as shown by the increasing loss of CD and narrow, short-lived fluorescence lifetime distributions.

Collapse transition of a hydrophobic self-avoiding random walk in a coarse-grained model solvent

In order to study solvation effects on protein folding, we analyze the collapse transition of a self-avoiding random walk composed of hydrophobic segments that is embedded in a lattice model of a solvent. As expected, hydrophobic interactions lead to an attractive potential of mean force among chain segments. As a consequence, the random walk in solvent undergoes a collapse transition at a higher temperature than in its absence. Chain collapse is accompanied by the formation of a region depleted of solvent around the chain. In our simulation, the depleted region at collapse is as large as our computational domain.

Nanoparticles of adaptive supramolecular networks self-assembled from nucleotides and lanthanide ions

Amorphous nanoparticles of supramolecular coordination polymer networks are spontaneously self-assembled from nucleotides and lanthanide ions in water. They show intrinsic functions such as energy transfer from nucleobase to lanthanide ions and excellent performance as contrast enhancing agents for magnetic resonance imaging (MRI). Furthermore, adaptive inclusion properties are observed in the self-assembly process: functional materials such as fluorescent dyes, metal nanoparticles, and proteins are facilely encapsulated. Dyes in these nanoparticles fluoresce in high quantum yields with a single exponential decay, indicating that guest molecules are monomerically wrapped in the network. Gold nanoparticles and ferritin were also wrapped by the supramolecular shells. In addition, these nucleotide/lanthanide nanoparticles also serve as scaffolds for immobilizing enzymes. The adaptive nature of present supramolecular nanoparticles provides a versatile platform that can be utilized in a variety of applications ranging from material to biomedical sciences. As examples, biocompatibility and liver-directing characteristics in in vivo tissue localization experiments are demonstrated.

Folding propensity and biological activity of peptides: the effect of a single stereochemical isomerization on the conformational properties of bombinins in aqueous solution

Folding propensities of bombinins H2 and H4, two members of amphibian bombinins H, a family of 17-20 residue alpha-helical peptides, have been investigated by means of circular dichroism (CD) measurements and molecular dynamics (MD) simulations. The two peptides, with primary structure IIGPVLGLVGSALGGLLKKI-NH2 and differing only for the configuration of the second aminoacid (an L-isoleucine in H2 and a D-alloisoleucine in H4) behave rather differently in solution. In particular both CD measurements and MD simulations indicate that bombinin H2 shows a markedly higher tendency to fold. From a careful inspection of MD trajectories it emerges that the stereochemical isomerization mutation of residue 2 to D-alloisoleucine in H4 peptide, drastically decreases its ability to form intrapeptide contacts. MD simulations also indicate that the conformational sampling in both systems derives from a subtle combination of energetic and entropic effects both involving the peptide itself and the solvent. The present results have been finally paralleled with preliminary information on bombinins H2 and H4 biological activity, i.e. interaction with membrane, supporting the hypothesis of an "already folded" conformation in water rather than interfacial folding tenet.

The key-role of tyrosine 155 in the mechanism of prion transconformation as highlighted by a study of sheep mutant peptides

Prion protein is a strongly conserved and ubiquitous glycoprotein. The conformational conversion of the non-pathogenic cellular prion isoform (PrP(C)) into a pathogenic scrapie isoform (PrP(Sc)) is a fundamental event in the onset of transmissible spongiform encephalopathies (TSE). During this conversion, helix H1 and its two flanking loops are known to undergo a conformational transition into a beta-like structure. In order to understand mechanisms which trigger this transconformation, sheep prion protein synthetic peptides spanning helix 1 and beta-strand 2 (residues 142-166) were studied: (1) the N3 peptide, studied earlier, is known to fold into beta-hairpin-like conformation in phosphate buffer at neutral pH and to adopt a helix H1 conformation when dissolved in trifluoroethanol/phosphate buffer mixture, (2) The R156A mutant (peptide R15) and (3) the Y155A mutant (peptide Y14) of the N3 peptide are studied by circular dichroism and NMR spectroscopy in this article. Structural characterization of these peptides highlights the key role of tyrosine 155 in the stabilization of the beta-hairpin-like conformation of the sheep peptide in phosphate buffer. We propose a model where tyrosine 155 could stabilize the beta-hairpin structure by creating a hydrophobic core in phosphate buffer, necessary to initiate the beta-type structure formation. In the turn, the side chain ionic interaction, E152-R156 described before, seems to play a minor role relative to the hydrophobic packing, as observed with the R156A mutation (peptide R15). Interestingly, homology at amino acid residue 155 could be responsible for the species barrier in TSE.

Subdiffusion in peptides originates from the fractal-like structure of configuration space

Molecular dynamics simulation of oligopeptide chains reveals configurational subdiffusion at equilibrium extending from 10(-12) to 10(-8) s. Trap models, involving a random walk with a distribution of waiting times, cannot account for the subdiffusion, which is found rather to arise from the fractal-like structure of the accessible configuration space.

Recent advances in implicit solvent-based methods for biomolecular simulations

Implicit solvent-based methods play an increasingly important role in molecular modeling of biomolecular structure and dynamics. Recent methodological developments have mainly focused on the extension of the generalized Born (GB) formalism for variable dielectric environments and accurate treatment of nonpolar solvation. Extensive efforts in parameterization of GB models and implicit solvent force fields have enabled ab initio simulation of protein folding to native or near-native structures. Another exciting area that has benefited from the advances in implicit solvent models is the development of constant pH molecular dynamics methods, which have recently been applied to the calculations of protein pK(a) values and the studies of pH-dependent peptide and protein folding.