Jean-Pierre Dognon

Competition between local conformational preferences and secondary structures in gas-phase model tripeptides as revealed by laser spectroscopy and theoretical chemistry

The gas-phase model tripeptides N-acetyl-Phe-Pro-NH2 and N-acetyl-Pro-Phe-NH2 have been studied experimentally and theoretically in order to investigate the local conformational preferences of the peptide backbone and their competition with secondary structures under solvent-free conditions. The combination of UV and IR spectroscopies shows that, under supersonic beam conditions, only a reduced number of conformations are formed, indicating efficient conformational relaxation processes in these species. IR spectroscopy in the NH stretch spectral range combined with density functional theory calculations proves to be a very efficient tool to assign the structure of these species in terms of intramolecular H-bonding. Classical secondary structures of biology, like repeated γ-turns are observed as major conformations. Only one minor conformation of N-Ac-Phe-Pro-NH2 was assigned to a β-turn structure. According to the nature of the main conformers, the backbone conformational trends on the phenylalanine (Phe) residue is shown to be very dependent upon the neighbouring residues: Phe adopts a β conformation when alone (in N-acetyl-Phe-NH2) or when followed by a proline residue (in N-acetyl-Phe-Pro-NH2) but favours a γL conformation when preceded by proline (in N-acetyl-Pro-Phe-NH2). These subtle preferences, resulting from a competition between weakly polar or dispersive interactions, constitute a very stringent test of the theoretical tools for protein modelling and simulation.

Secondary structures of short peptide chains in the gas phase: double resonance spectroscopy of protected dipeptides

The conformational structure of short peptide chains in the gas phase is studied by laser spectroscopy of a series of protected dipeptides, Ac-Xxx-Phe-NH(2), Xxx=Gly, Ala, and Val. The combination of laser desorption with supersonic expansion enables us to vaporize the peptide molecules and cool them internally; IR/UV double resonance spectroscopy in comparison to density functional theory calculations on Ac-Gly-Phe-NH(2) permits us to identify and characterize the conformers populated in the supersonic expansion. Two main conformations, corresponding to secondary structures of proteins, are found to compete in the present experiments. One is composed of a doubly gamma-fold corresponding to the 2(7) ribbon structure. Topologically, this motif is very close to a beta-strand backbone conformation. The second conformation observed is the beta-turn, responsible for the chain reversal in proteins. It is characterized by a relatively weak hydrogen bond linking remote NH and CO groups of the molecule and leading to a ten-membered ring. The present gas phase experiment illustrates the intrinsic folding properties of the peptide chain and the robustness of the beta-turn structure, even in the absence of a solvent. The beta-turn population is found to vary significantly with the residues within the sequence; the Ac-Val-Phe-NH(2) peptide, with its two bulky side chains, exhibits the largest beta-turn population. This suggests that the intrinsic stabilities of the 2(7) ribbon and the beta-turn are very similar and that weakly polar interactions occurring between side chains can be a decisive factor capable of controlling the secondary structure.

Theoretical study of the hydrated Gd3+ ion: Structure, dynamics, and charge transfer

The dynamical processes taking place in the first coordination shells of the gadolinium (III) ion are important for improving the contrast agent efficiency in magnetic-resonance imaging. An extensive study of the gadolinium (III) ion solvated by a water cluster is reported, based on molecular dynamics simulations. The AMOEBA force field [P. Y. Ren and J. W. Ponder, J. Phys. Chem. B 107, 5933 (2003)] that includes many-body polarization effects is used to describe the interactions among water molecules, and is extended here to treat the interactions between them and the gadolinium ion. In this purpose accurate ab initio calculations have been performed on Gd(3+)-H(2)O for extracting the relevant parameters. Structural data of the first two coordination shells and some dynamical properties such as the water exchange rate between the first and second coordination shells are compared to available experimental results. We also investigate the charge transfer processes between the ion and its solvent, using a fluctuating charges model fitted to reproduce electronic structure calculations on [Gd(H(2)O)(n)](3+) complexes, with n ranging from 1 to 8. Charge transfer is seen to be significant (about one electron) and correlated with the instantaneous coordination of the ion.

Gas-phase models of γ turns: Effect of side-chain/backbone interactions investigated by IR/UV spectroscopy and quantum chemistry

The conformations of laser-desorbed jet-cooled short peptide chains Ac-Phe-Xxx-NH2 (Xxx=Gly, Ala, Val, and Pro) have been investigated by IR/UV double resonance spectroscopy and density-functional-theory (DFT) quantum chemistry calculations. Singly gamma-folded backbone conformations (betaL-gamma) are systematically observed as the most stable conformers, showing that in these two-residue peptide chains, the local conformational preference of each residue is retained (betaL for Phe and gamma turn for Xxx). Besides, beta turns are also spontaneously formed but appear as minor conformers. The theoretical analysis suggests negligible inter-residue interactions of the main conformers, which enables us to consider these species as good models of gamma turns. In the case of valine, two similar types of gamma turns, differing by the strength of their hydrogen bond, have been found both experimentally and theoretically. This observation provides evidence for a strong flexibility of the peptide chain, whose minimum-energy structures are controlled by side-chain/backbone interactions. The qualitative conformational difference between the present species and the reversed sequence Ac-Xxx-Phe-NH2 is also discussed.

Can we understand the different coordinations and structures of closed-shell metal cation-water clusters?

We present a model potential for studying Mq+(H2O)n=1,9 clusters where M stands for either Na+, Cs+, Ca2+, Ba2+, or La3+. The potential energy surfaces (PES) are explored by the Monte Carlo growth method. The results for the most significant equilibrium structures of the PES as well as for energetics are favorably compared to the best ab initio calculations found in the literature and to experimental results. Most of these complexes have a different coordination number in cluster compared to experimental results in solution or solid phase. An interpretation of the coordination number in clusters is given. In order to well describe the transition between the first hydration sphere and the second one we show that an autocoherent treatment of the electric field is necessary to correctly deal with polarization effects. We also explore the influence of the cation properties (charge, size, and polarizability) on both structures and coordination number in clusters, as well as the meaning of the second hydration sphere. Such an approach shows that the leading term in the interaction energy for a molecule in the second hydration sphere is an electrostatic attraction to the cation and not a hydrogen bond with the water molecules in the first hydration sphere.

Design and Synthesis of New Cryptophanes with Intermediate Cavity Sizes

The development of molecular imaging using hyperpolarized xenon MRI needs highly optimized biosensors. Cryptophane-111 and cryptophane-222 are promising candidates that show complementary encapsulation properties although they only differ by the length of the three alkane linkers joining two cyclotriphenolene units. Cryptophanes containing both methoxy and ethoxy linkers have never been synthesized. Here we synthesize two new cages with intermediate internal volumes, in two steps from cyclotriphenolene.

Electronic Spectrum of Tryptophan-Phenylalanine. A Correlated Ab Initio and Time-Dependent Density Functional Theory Study

The theoretical electronic spectrum of the tryptophan-phenylalanine bichromophoric dipeptide was obtained for one of the lowest-energy conformer by various high-level computational methods such as complete active space with second order perturbation theory, second-order approximate coupled-cluster theory, and time-dependent density functional theory. The results show that the first excited state is located on the tryptophan residue and called L(b) state in the amino-acid. The second and third excited states correspond respectively to the L(a) state of Trp and the excited state in the Phe residue. Time-dependent density functional methods appeared to be not efficient to calculate the excited states of such a peptide (except the first one) due to the inclusion of charge transfer states.

New model potentials for sulfur–copper(I) and sulfur–mercury(II) interactions in proteins: From ab initio to molecular dynamics

We have developed new force field and parameters for copper(I) and mercury(II) to be used in molecular dynamics simulations of metalloproteins. Parameters have been derived from fitting of ab initio interaction potentials calculated at the MP2 level of theory, and results compared to experimental data when available. Nonbonded parameters for the metals have been calculated from ab initio interaction potentials with TIP3P water. Due to high charge transfer between Cu(I) or Hg(II) and their ligands, the model is restricted to a linear coordination of the metal bonded to two sulfur atoms. The experimentally observed asymmetric distribution of metal ligand bond lengths (r) is accounted for by the addition of an anharmonic (r3) term in the potential. Finally, the new parameters and potential, introduced into the CHARMM force field, are tested in short molecular dynamics simulations of two metal thiolates fragments in water. (Brooks BR et al. J Comput Chem 1983, 4, 1987. 1 )

Secondary structures of Val–Phe and Val–Tyr(Me) peptide chains in the gas phase: effect of the nature of the protecting groups

Recent experimental gas-phase studies of very similar peptide chain models (Ac–Val–Tyr(Me)–NHMe and Ac–Val–Phe–NH2) have led to different assignments for the secondary structures adopted: β-strand and β-turn, respectively. We present a discussion of the possible causes for such different behaviour in the light of quantum chemistry calculations. The consistent set of data presently obtained (relative energies and IR calculated spectra) leads us to propose the same structural assignment for the experimentally observed Val–Tyr(Me) and Val–Phe peptide chains, i.e. a β-turn conformation. In addition, calculations also suggest that the nature of the chemical protection on the C-terminal (–NHMe vs. –NH2) of the chain model does not affect its conformational preference, nor its structure or its energetics, which suggests the less simple, but more informative, –NH2-protected models for the determination of the intrinsic structural properties of a peptide chain.

Understanding a Host–Guest Model System through 129Xe NMR Spectroscopic Experiments and Theoretical Studies

Gaining an understanding of the nature of host-guest interactions in supramolecular complexes involving heavy atoms is a difficult task. Described herein is a robust simulation method applied to complexes between xenon and members of a cryptophane family. The calculated chemical shift of xenon caged in a H2O2 probe, as modeled by quantum chemistry with complementary-orbital, topological, and energy-decomposition analyses, is in excellent agreement with that observed in hyperpolarized (129)Xe NMR spectra. This approach can be extended to other van der Waals complexes involving heavy atoms.