Monique Genest

Lipopeptides with Improved Properties: Structure by NMR, Purification by HPLC and Structure–Activity Relationships of New Isoleucyl‐rich Surfactins

The biosynthesis of bacterial isoleucyl‐rich surfactins was controlled by supplementation of L‐isoleucine to the culture medium. Two new variants, the [Ile4,7]‐ and [Ile2,4,7]surfactins, were thus produced by Bacillus subtilis and their separation was achieved by reverse‐phase HPLC. Amino acids of the heptapeptide moiety were analysed by chemical methods, and the lipid moiety was identified to β‐hydroxy anteiso pentadecanoic acid by combined GC/MS. Sequences were established on the basis of two‐dimensional NMR data. Because conformational parameters issuing from NMR spectra suggested that the cyclic backbone fold was globally conserved in the new variants, structure–activity relationships were discussed in details on the basis of the three‐dimensional model of surfactin in solution. Indeed, both variants have increased surface properties compared with that of surfactin, and this improvement is assigned to an increase of the hydrophobicity of the apolar domain favouring micellization. Furthermore, the additional Leu‐to‐Ile substitution at position 2 in the [Ile2,4,7]surfactin leads to a substantial increase of its affinity for calcium, when compared with that of [Ile4,7]surfactin or surfactin. This effect is assigned, from the model, to an increase in the accessibility of the acidic side chains constituting the calcium binding site. Thus, the propensities of such active lipopeptides for both hydrophobic and electrostatic interactions were improved, further substantiating that they can be rationally designed.

Reconstruction of NOESY maps: A requirement for a reliable conformational analysis of biomolecules using 2D NMR

The modelling of the conformation of a biomolecule in solution is based mainly on the internuclear distances deduced from measurements of nuclear Overhauser effects (nOe) in NOESY correlation maps. The distances are then used as restraints in the energy minimization procedure, which leads to one or several optimized conformations. A general and safe technique for validating these structures with respect to the experimental data is here proposed: from the internuclear distances, the relaxation matrix can be computed under the assumption of a unique rotational correlation time. By stepwise integration of these relaxation equations, the NOESY maps can be accurately reconstructed for any mixing time. Because multi-spin effects are correctly taken into account, any difference between the experimental and theoretical maps can be easily interpreted in terms of conformation, and possible inconsistencies due to conformational averaging can be pointed out. The technique is illustrated for a bacterial lipopeptide, mycosubtilin, the spectrum of which is completely assigned.

Structure prediction of the dimeric neu/ErbB-2 transmembrane domain from multi-nanosecond molecular dynamics simulations

Abstract Dimerization of the neu/ErbB-2 receptor tyrosine kinase is a necessary but not a sufficient step for signaling. Despite the efforts expended to identify the molecular interactions responsible for receptor-receptor contacts and particularly those involving the transmembrane domain, structural details are still unknown. In this work, molecular dynamics simulations of the helical transmembrane domain (TM) of neu and ErbB-2 receptors are used to predict their dimer structure both in the wild and oncogenic forms. A global conformational search method, applied to define the best orientations of parallel helices, showed an energetically favorable configuration with the specific mutation site within the interface, common for both the nontransforming and the transforming neu/ErbB-2 TM dimers. Starting from this configuration, a total of 10 simulations, about 1.4 ns each, performed in vacuum, without any constraints, show that the two helices preferentially wrap in left-handed interactions with a packing angle at about 20°. The resulting structures are nonsymmetric and the hydrogen bond network analysis shows that helices experience π local distortions that facilitate inter-helix hydrogen bond interactions and may result in a change in the helix packing, leading to a symmetric interface. For the mutated sequences, we show that the Glu side chain interacts directly with its cognate or with carbonyl groups of the facing backbone. We show that the connectivity between interfacial residues conforms to the knobs-into-holes packing mode of transmembrane helices. The dimeric interface described in our models is discussed with respect to mutagenesis studies.

Detailed description of an alpha helix-->pi bulge transition detected by molecular dynamics simulations of the p185c-erbB2 V659G transmembrane domain.

Molecular dynamics simulations of a 29-residue peptide including the transmembrane domain of the V659G mutant of the c-erbB2 protein demonstrate important dynamical behavior. Although the alpha helix is the structure commonly assumed for transmembrane hydrophobic segments, we found that hydrogen bond rearrangements can occur, giving rise to a structural deformation termed pi bulge stabilized by successive hydrogen bonds of pi helix type. A series of simulations enables us to give a detailed description, at the atomic level, of the alpha helix->pi bulge transition. The major consequence of this deformation covering one and a half turn of helix results in a noticeable shift around the helix axis of the C-Terminal residues relatively to those of the N-terminus. Such a deformation closely related to structural motifs described in the literature, induces a change in the distribution of the residues along the helix faces which could modulate the protein activity mediated by a dimerization process.

Insight into Signal Transduction: Structural Alterations in Transmembrane Helices Probed by Multi-1 ns Molecular Dynamics Simulations

The hypothesis of structural alteration in transmembrane helices for signal transduction process is viewed by molecular dynamics simulation techniques. For the c-erbB-2 transmembrane domain involved in oncogenicity, the occurrence of conformational changes has been previously described as transition from the alpha to pi helix. This dynamical feature is thoroughly analyzed for the wild phenotype and oncogenic sequences from a series of 18 simulations carried out on one nanosecond time scale. We show that these structural events do not depend upon the conditions of simulations like force field or starting helix coordinates. We demonstrate that the oncogenic mutations Val659 Glu, Gln and Asp do not prevent the transition. Furthermore, we show that beta branched residues, in conjunction with Gly residues in the c-erbB-2 sequence, act as destabilizers for the alpha helix structure, pi deformations are tightly related to other local structural motifs found in soluble and membrane proteins. These structural alterations are discussed in term of structure-activity relationships for the c-erbB-2 activating mechanism mediated by transmembrane domain dimerization.

Molecular dynamics simulations of the ErbB-2 transmembrane domain within an explicit membrane environment: comparison with vacuum simulations

Two 500-ps molecular dynamics simulations performed on the single transmembrane domain of the ErbB-2 tyrosine kinase receptor immersed in a fully solvated dilauroylphosphatidyl-ethanolamine bilayer (DLPE) are compared to vacuum simulations. One membrane simulation shows that the initial alpha helix undergoes a local pi helix conversion in the peptide part embedded in the membrane core similar to that found in simulation vacuum. Lipid/water/peptide interaction analysis shows that in the helix core, the intramolecular peptide interactions are largely dominant compared to the interactions with water and lipids whereas the helix extremities are much more sensitive to these interactions at the membrane interfaces. Our results suggest that simulations in a lipid environment are required to understand the dynamics of transmembrane helices, but can be reasonably supplemented by in vacuo simulations to explore rapidly its conformational space and to describe the internal deformation of the hydrophobic core.

Molecular modeling of c‐erbB2 receptor dimerization: Coiled‐coil structure of wild and oncogenic transmembrane domains—Stabilization by interhelical hydrogen bonds in the oncogenic form

Dimerization models of c-erbB2 transmembrane domains (Leu651-Ile675) are studied by molecular mechanics and molecular dynamics simulations. Both wild and Glu mutated transmembrane helices exhibit the same relative orientation for favorable associations and dimerize preferentially in left-handed coiled-coil structures. The mutation point 659 belongs to the interfacing residues, and in the transforming domain, symmetric hydrogen bonds between Glu carboxylic groups stabilize the dimeric structure. The same helix packing found for the wild dimers, except side-chain-side-chain hydrogen bonds, suggests that the transmembrane domains dimerize according to similar process. Structural and energetical characterization of the models are presented.

Transmembrane recognition of the semaphorin co-receptors neuropilin 1 and plexin A1: coarse-grained simulations.

The cancer associated class 3 semaphorins require direct binding to neuropilins and association to plexins to trigger cell signaling. Here, we address the role of the transmembrane domains of neuropilin 1 and plexin A1 for the dimerization of the two receptors by characterizing the assembly in lipid bilayers using coarse-grained molecular dynamics simulations. From experimental evidence using a two-hybrid system showing the biochemical association of the two receptors transmembrane domains, we performed molecular simulations in DOPC and POPC demonstrating spontaneously assembly to form homodimers and heterodimers with a very high propensity for right-handed packing of the helices. Inversely, left-handed packing was observed with a very low propensity. This mode of packing was observed uniquely when the plexin A1 transmembrane domain was involved in association. Potential of mean force calculations were used to predict a hierarchy of self-association for the monomers: the two neuropilin 1 transmembrane domains strongly associated, neuropilin 1 and plexin A1 transmembrane domains associated less and the two plexin A1 transmembrane domains weakly but significantly associated. We demonstrated that homodimerization and heterodimerization are driven by GxxxG motifs, and that the sequence context modulates the packing mode of the plexin A1 transmembrane domains. This work presents major advances towards our understanding of membrane signaling platforms assembly through membrane domains and provides exquisite information for the design of antagonist drugs defining a novel class of therapeutic agents.

TIME RESOLVED FLUORESCENCE PROPERTIES OF PHENYLALANINE IN DIFFERENT ENVIRONMENTS. COMPARISON WITH MOLECULAR DYNAMICS SIMULATION

Time resolved fluorescence of the phenylalanine residue (Phe) alone and included in the transmembrane domain (TMD) sequences of the epidermal growth factor receptor (EGFR) and ErbB-2 was studied using the synchrotron radiation source of light, and compared to molecular dynamics (MD) simulations. The fluorescence intensity decay is strongly sensitive to the environment. A mono-exponential decay was obtained for Phe amino acid alone in two different solvents and for Phe included in EGFR transmembrane sequence, with fluorescence lifetime values varying from 1.7 ns (EGFR) to 7.4 ns (Phe dissolved in water). In ErbB-2 transmembrane sequence three lifetimes were detected. The relative amplitude of the shortest one (0.14 ns) is smaller than 10%, whereas the others (0.6 and 2.2 ns) are almost equally represented. They have been attributed to different rotamers exchanging slowly. This interpretation is supported by MD simulations which evidence transitions in time series of the chi 1 dihedral angle of Phe observed in the case of ErbB-2. The anisotropy decays are similar for both peptides and indicate the presence of a correlation time in the nanosecond range (1-4 ns) and the probable existence of a very fast one (< 0.05 ns). Autocorrelation functions computed from MD simulations corroborate these results.

Transmembrane domain targeting peptide antagonizing ErbB2/Neu inhibits breast tumor growth and metastasis.

Breast cancer is still a deadly disease despite major achievements in targeted therapies designed to block ligands or ligand-binding subunits of major tyrosine kinase receptors. Relapse is significant and metastases deleterious, which demands novel strategies for fighting this disease. Here, we report a proof-of-concept experiment demonstrating that small peptides interfering with the transmembrane domain of the tyrosine kinase epidermal growth factor receptor ErbB2 exhibit anticancer properties when used at micromolar dosages in a genetically engineered mouse model of breast cancer. Different assays demonstrate the specificity of the ErbB2-targeting peptide, which induces long-term reduction of ErbB2 phosphorylation and Akt signaling consistent with reduced tumor cell proliferation and increased survival. Microcomputed tomography analysis established the antimetastatic activity of the peptide and its impact on primary tumor growth. This reveals the interior of the cell membrane as an unexplored dimension for drug design.