Francesca De Rienzo

Theoretical investigation of substrate specificity for cytochromes P450 IA2, P450 IID6 and P450 IIIA4.

Three-dimensional models of the cytochromes P450 IA2, P450 IID6 and P450 IIIA4 were built by means of comparative modeling using the X-ray crystallographic structures of P450 CAM, P450 BM-3, P450 TERP and P450 ERYF as templates. The three cytochromes were analyzed both in their intrinsic structural features and in their interaction properties with fifty specific and non-specific substrates. Substrate/enzyme complexes were obtained by means of both automated rigid and flexible body docking. The comparative analysis of the three cytochromes and the selected substrates, in their free and bound forms, allowed for the building of semi-quantitative models of substrate specificity based on both molecular and intermolecular interaction descriptors. The results of this study provide new insights into the molecular determinants of substrate specificity for the three different eukaryotic P450 isozymes and constitute a useful tool for predicting the specificity of new compounds.

Protein–surface interactions: challenging experiments and computations

Protein–surface interactions are fundamental in natural processes, and have great potential for applications ranging from nanotechnology to medicine. A recent workshop highlighted the current achievements and the main challenges in the field. Copyright

Insights into MAPK p38α DFG flip mechanism by accelerated molecular dynamics

The DFG motif at the beginning of the activation loop of the MAPK p38alpha undergoes a local structural reorganization upon binding of allosteric type-II and type-III inhibitors, which causes the residue F169 to move from a buried conformation (defined as DFG-in) to a solvent exposed conformation (defined as DFG-out). Although both experimental and computer simulation studies had been performed with the aim of unveiling the details of the DFG-in to DFG-out transition, the molecular mechanism is still far from being unequivocally depicted. Here, the accelerated molecular dynamics (AMD) technique has been applied to model the active loop flexibility of p38alpha and sample special protein conformations which can be accessible only in some conditions or time periods. Starting from the assumption of an experimentally known initial and final state of the protein, the study allowed the description of the interaction network and the structural intermediates which lead the protein to change its loop conformation and active site accessibility. Besides a few important hydrogen bond interactions, a primary role seems to be played by cation-pi interactions, involving the DFG-loop residue F(169), which participate in the stabilization of an intermediate conformation and in its consequent transition to the DFG-out conformation. From this study, insights which may prove useful for inhibitor design and/or site directed mutagenesis studies are derived.

Computational analysis of ligand recognition sites of homo- and heteropentameric 5-HT3 receptors.

Inhibition of the 5-hydroxytryptamine receptor (5-HT(3)R), a member of the Cys-loop superfamily of Ligand-Gated Ion Channels (LGICs), has been recognized to have important antiemetic effects. With respect to the many other drugs already in use, such as the first generation 5-HT(3)R antagonist granisetron, palonosetron, a second generation antagonist, clearly demonstrates superior inhibition potency towards the 5-HT(3)Rs. Five different receptor monomers, the 5-HT(3)R A-E, have been identified although the A and B subunits are the only known to build functional receptors, the homopentameric 5-HT(3A)R and the heteropentameric 5-HT(3B-A)R (with BBABA subunit arrangement). At present, however, no three-dimensional structure has been reported for any of the 5-HT(3)R subunits. To understand the binding properties of agonists and antagonists, models of the extracellular portion of the 5-HT(3)R A and B subunits are built and assembled into the receptor (homo- and hetero-) pentameric structure on the basis of the known three-dimensional structure of the nicotinic-acetylcholine receptor (nACh-R). The results of docking studies of the natural agonist serotonin and the antagonists palonosetron and granisetron into the modelled homomeric and heteromeric 5-HT(3)R binding interfaces, provide a possible rationalization both of the higher potency of palonosetron with respect to other antagonists, and of its previously reported allosteric binding and positive cooperativity properties.

Bivalent Ligands for the Serotonin 5-HT3 Receptor.

The serotonin 5-HT3 receptor is a ligand-gated ion channel, which by virtue of its pentameric architecture, can be considered to be an intriguing example of intrinsically multivalent biological receptors. This paper describes a general design approach to the study of multivalency in this multimeric ion channel. Bivalent ligands for 5-HT3 receptor have been designed by linking an arylpiperazine moiety to probes showing different functional features. Both homobivalent and heterobivalent ligands have shown 5-HT3 receptor affinity in the nanomolar range, providing evidence for the viability of our design approach. Moreover, the high affinity shown by homobivalent ligands suggests that bivalency is a promising approach in 5-HT3 receptor modulation and provides the rational basis for applying the concepts of multivalency to the study of 5-HT3 receptor function.

Development of an IL-6 antagonist peptide that induces apoptosis in 7TD1 cells

Interleukin-6 (IL-6) is a pleiotropic cytokine involved in the regulation of proliferation and differentiation of hematopoietic cells and in the pathogenesis of many diseases, including multiple myeloma. This study pursues a way to interfere with IL-6 pathway in an attempt to modulate its biological activity. Here we describe the rational design and biological evaluation of peptides able to antagonize the murine IL-6 activity by interfering with IL-6 Receptor alpha in 7TD1 cells, a IL-6-dependent B-cell line. Of the peptide tested, only Guess 4a is capable of interfering with IL-6 transducing pathway, therefore inducing growth arrest and apoptosis of 7TD1 cells.

Synthesis and structure-activity relationship studies in serotonin 5-HT4 receptor ligands based on a benzo[de][2,6]naphthridine scaffold.

A small series of serotonin 5-HT4 receptor ligands has been designed from flexible 2-methoxyquinoline compounds 7a,b by applying the conformational constraint approach. Ligands 7a,b and the corresponding conformationally constrained analogues 8a-g were synthesized and their interactions with the 5-HT4 receptor were examined by measuring both binding affinity and the ability to promote or inhibit receptor-G protein coupling. Ester derivative 7a and conformationally constrained compound 8b were demonstrated to be the most interesting compounds showing a nanomolar 5-HT4R affinity similar to that shown by reference ligands cisapride (1) and RS-23,597-190 (4). The result was rationalized by docking studies in term of high similarity in the binding modalities of flexible 7a and conformationally constrained 8b. The intrinsic efficacy of some selected ligands was determined by evaluating the receptor-G protein coupling and the results obtained demonstrated that the nature and the position of substituents play a critical role in the interaction of these ligands with their receptor.

A computational protocol to probe the role of solvation effects on the reduction potential of azurin mutants

Semiquantitative relationships between thermodynamic parameters of Cu2+ reduction experimentally measured for a series of azurin mutants and the solvation free energy of the oxidized state of the proteins were derived. Solvation free energy calculations were carried out within an ONIOM/PCM scheme specifically adapted to this protein series. The method proved to be able to capture the main determinants of the measured reduction parameters, providing satisfactory predictions of the E°′. Proteins 2006.

A first step towards the understanding of the 5-HT3 receptor subunit heterogeneity from a computational point of view

The functional serotonin type-3 receptor (5-HT(3)-R), which is the target of many neuroactive drugs, is known to be a homopentamer made of five identical subunits A (5-HT(3A)-R) or a binary heteropentamer made of subunits A and B (5-HT(3A/B)-R) with a still debated arrangement and stoichiometry. This complex picture has been recently further complicated by the discovery of additional 5-HT(3)-R subunits, C, D, and E, which, similarly to the B subunit, are apparently able to form functional receptors only if co-expressed with subunit A. Being the binding site for both serotonin and antagonists (i.e. drugs) located at the extracellular interface between two adjacent subunits, the large variability of the 5-HT(3)-R composition becomes a crucial issue, since it can originate many different interfaces providing non-equivalent ligand binding sites and complicating the pharmacological modulation. Here, the different 5-HT(3)-R interfaces are analysed, on the bases of the structural conformations of previously built 3D homology models and of the known subunit sequences, by addressing their physicochemical characterization. The results confirm the presence of an aromatic cluster located in the core of the A-A interface as a key determinant for having an interface both stable and functional. This is used as a discriminant to make hypotheses about the capability of all the other possible interfaces constituted by the known 5-HT(3)-R sequences A, B, C, D, and E to build active receptors.

The extracellular subunit interface of the 5-HT3 receptors: a computational alanine scanning mutagenesis study

The functional serotonin 5-HT type-3 (5-HT3) receptor, the target of many neuroactive drugs, is known to be a pseudo-symmetric pentamer made either of five identical subunits A (homomeric 5-HT3 A -R) or of subunits A and B (heteromeric 5-HT3 A/B -R) in a still debated arrangement. The serotonin binding site is located in the extracellular region, at the interface between two monomers, called the principal and the complementary subunits. The results of molecular dynamics simulations and computational alanine scanning mutagenesis studies applied here to the homomeric human 5-HT3 A -R disclose an aromatic “hot” cluster in the centre of the interface formed by residues W178 (principal subunit), Y68, Y83, W85 and Y148 (complementary subunit). Moreover, investigation of the coupling of agonist/antagonist binding to channel activation/inactivation points out the presence of two putative functional pathways at the subunit interface: W116-H180-L179-W178-E124-F125 (principal subunit) and Y136-Y138-Y148-W85-(P150) (complementary subunit), where W178 and Y148 appear to be critical residues for the binding/activation mechanism. Finally, direct comparison of the main features shown by the AA interface in the human 5-HT3 A -R with those of the BB interface in the homopentameric human 5-HT3 B -R provides interesting clues about the possible reasons that cause the 5-HT3 B -R not to be functional.