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ABSTRACT: The sugar puckering of adenosine and uridine nucleosides with an amino group at 2' in the ribo or arabino orientations are determined using high-level quantum mechanical calculations Only the conformations that have dihedrals compatible with their insertion into a duplex are retained. The amino group has always been found to be pyramidal and its orientation governs the conformation of the sugar. The energetically most favorable conformation of the 2'-aminoribonucleosides has the south puckering but must be discarded. For another orientation of the 2'-amino group, the conformation is energetically less favorable but has the north puckering. Calculations performed in the presence of a water molecule give similar results but with a smaller energy gap. The model then explains why the insertion of a 2'-aminoribonucleotide destabilizes double-stranded RNAs and also double-stranded DNAs. In the arabino orientation, an NH(2) substituent at 2' favors north puckering. In contrast to 2'-aminoribonucleosides, deoxynucleosides inserted into a duplex remain in the most energetically favorable conformation compatible with the canonical values of the torsion angles. The whole relaxed potential map, in the amplitude/pseudorotation space, shows that for natural deoxyadenosine there is only one valley in the east running from south to north puckering.
Journal of Computational Chemistry 08/2008; 29(9):1353-63. · 4.58 Impact Factor
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ABSTRACT: We used high-level quantum mechanical calculations to determine the pucker (north type or south type) of various compounds: uridine, 2'-deoxyuridine, and 2'-O-methyl uridine. Although the dihedrals of the backbone are set close to their experimental values in double-stranded nucleic acids, calculations using density functional theory show that, in vacuo or in a continuum mimicking the dielectric properties of water, the south puckering conformations of uridine is favored. This contrasts with experimental data: most ribonucleosides inserted into a duplex have the north puckering. We show here that the north puckering is favored when an explicit water molecule is introduced into the calculation. The orientations of the 2' group and of the water molecule have implications for the prevalence of the north puckering. We studied several orientations of the water molecule binding uracil O2 and the 2' group and estimated the energy barriers in the path between the north-to-south conformations. The north puckering is more favored in 2'-OH than in 2'-OCH3 compounds in the presence of the explicit water molecule.
The Journal of Physical Chemistry A 03/2008; 112(5):989-99. · 2.95 Impact Factor
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Journal of Computational Chemistry. 01/2008; 29:1353-1363.
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Halina Niedbala,
Jaroslaw Polanski,
Rafal Gieleciak,
Robert Musiol,
Dominik Tabak,
Barbara Podeszwa,
Andrzej Bak,
Anna Palka,
Jean-Francois Mouscadet,
Johann Gasteiger, Marc Le Bret
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ABSTRACT: We used comparative molecular surface analysis to design molecules for the synthesis as part of the search for new HIV-1 integrase inhibitors. We analyzed the virtual combinatorial library (VCL) constituted from various moieties of styrylquinoline and styrylquinazoline inhibitors. Since imines can be applied in a strategy of dynamic combinatorial chemistry (DCC), we also tested similar compounds in which the -C=N- or -N=C- linker connected the heteroaromatic and aromatic moieties. We then used principal component analysis (PCA) or self-organizing maps (SOM), namely, the Kohonen neural networks to obtain a clustering plot analyzing the diversity of the VCL formed. Previously synthesized compounds of known activity, used as molecular probes, were projected onto this plot, which provided a set of promising virtual drugs. Moreover, we further modified the above mentioned VCL to include the single bond linker -C-N- or -N-C-. This allowed increasing compound stability but expanded also the diversity between the available molecular probes and virtual targets. The application of the CoMSA with SOM indicated important differences between such compounds and active molecular probes. We synthesized such compounds to verify the computational predictions.
Combinatorial Chemistry & High Throughput Screening 01/2007; 9(10):753-70. · 1.78 Impact Factor
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ABSTRACT: The specific activity of the human immunodeficiency virus, type 1 (HIV-1), integrase on the viral long terminal repeat requires the binding of the enzyme to certain sequences located in the U3 and U5 regions at the ends of viral DNA, but the determinants of this specific DNA-protein recognition are not yet completely understood. We synthesized DNA duplexes mimicking the U5 region and containing either 2'-modified nucleosides or 1,3-propanediol insertions and studied their interactions with HIV-1 integrase, using Mn2+ or Mg2+ ions as integrase cofactors. These DNA modifications had no strong effect on integrase binding to the substrate analogs but significantly affected 3'-end processing rate. The effects of nucleoside modifications at positions 5, 6, and especially 3 strongly depended on the cationic cofactor used. These effects were much more pronounced in the presence of Mg2+ than in the presence of Mn2+. Modifications of base pairs 7-9 affected 3'-end processing equally in the presence of both ions. Adenine from the 3rd bp is thought to form at least two hydrogen bonds with integrase that are crucial for specific DNA recognition. The complementary base, thymine, is not important for integrase activity. For other positions, our results suggest that integrase recognizes a fine structure of the sugar-phosphate backbone rather than heterocyclic bases. Integrase interactions with the unprocessed strand at positions 5-8 are more important than interactions with the processed strand for specific substrate recognition. Based on our results, we suggest a model for integrase interaction with the U5 substrate.
Journal of Biological Chemistry 05/2006; 281(17):11530-40. · 4.77 Impact Factor
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ABSTRACT: 2-[(2,5-dichloro-4-nitro-phenylamino)-methoxy-methyl]-8-hydroxy-quinoline 1 and 2-methyl-quinoline-5,8-dione-5-oxime 2 were obtained as potential HIV-1 integrase inhibitors and analyzed by X-ray crystallography. Semiempirical theoretical calculations of energy preferred conformations were also carried out. The crystal structures of both compounds are stabilized via hydrogen bonds and pi-pi stacking interactions. The planarity of compound 1 is caused by intramolecular hydrogen bonds.
Bioorganic & Medicinal Chemistry Letters 03/2006; 16(4):1005-9. · 2.55 Impact Factor
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ABSTRACT: The D816V activating mutation of the c-Kit kinase domain often causes human mastocytosis. Although inhibitors of wild-type c-Kit are known (e.g. STI-571), they are at least 10 times less active against the c-Kit mutant. Several derivatives of ellipticine (5,11-dimethyl-6H-pyrido[3,4-b]carbazole), substituted at positions 1, 2, 9, and 11, were found to inhibit purified D816V and wild-type c-Kit kinase domains with comparable potencies by competing with ATP binding. We investigated the difference between these inhibitors by modeling the D816V mutation in crystal structures of inactive and active c-Kit. Molecular dynamics simulations strongly suggested that the D816V point mutation shifts the conformational equilibrium of c-Kit kinase domain toward the active conformation. All ellipticine compounds were subsequently docked to the D816V mutant c-Kit model. The model provides possible explanations for the structure-activity relationships observed among ellipticine compounds, resulting in new insights into D816V c-Kit mutant inhibition.
Journal of Medicinal Chemistry 11/2005; 48(20):6194-201. · 5.25 Impact Factor
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ABSTRACT: In this article, we describe the program MORMIN, which can simultaneously minimize the mechanical energy of a given macromolecular structure, together with a weighted quadratic penalty function of the difference between the observed and computed nuclear Overhauser effect (nOe) peaks. The gradient of the nOe penalty function relatively to the proton coordinates is computed from an exact closed formula of a matrix exponential derivative. To cut CPU time, the molecular system is partitioned into nonoverlapping subsets containing the protons involved in the observed peaks. The algorithm is no longer exact, but if a 1% relative error is accepted it can be run, on a scalar computer, in about the same CPU time as needed for the calculation of the mechanical energy. We have successfully run the program in more than 1000 situations, including cases where the hybrid method failed because of the occurrence of negative eigenvalues. In some cases, the optimization of the Cartesian coordinates could be successfully extended to individual atomic diffusion times. © 1993 John Wiley & Sons, Inc.
Journal of Computational Chemistry 09/2004; 14(2):226 - 236. · 4.58 Impact Factor
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Christophe Bénard,
Fatima Zouhiri,
Marie Normand-Bayle,
Michèle Danet,
Didier Desmaële,
Hervé Leh,
Jean-François Mouscadet,
Gladys Mbemba,
Claire-Marie Thomas,
Sabine Bonnenfant, Marc Le Bret,
Jean d'Angelo
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ABSTRACT: A novel series of HIV-1 integrase inhibitors was synthesized and tested in both in vitro and ex vivo assays. These inhibitors are featured by the presence of a quinoline subunit and an ancillary aromatic ring linked by functionalized spacers such as amide, hydrazide, urea and 1-hydroxyprop-1-en-3-one moiety. Amide derivatives are the most promising ones and could serve as leads for further developments.
Bioorganic & Medicinal Chemistry Letters 06/2004; 14(10):2473-6. · 2.55 Impact Factor
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ABSTRACT: Styrylquinoline derivatives (SQ) efficiently inhibit the 3'-processing activity of integrase (IN) with IC50 values of between 0.5 and 5 microM. We studied the mechanism of action of these compounds in vitro. First, we used steady-state fluorescence anisotropy to assay the effects of the SQ derivatives on the formation of IN-viral DNA complexes independently of the catalytic process. The IC50 values obtained in activity and DNA-binding tests were similar, suggesting that the inhibition of 3'-processing can be fully explained by the prevention of IN-DNA recognition. SQ compounds act in a competitive manner, with Ki values of between 400 and 900 nM. In contrast, SQs did not inhibit 3'-processing when IN-DNA complexes were preassembled. Computational docking followed or not by molecular dynamics using the catalytic core of HIV-1 IN suggested a competitive inhibition mechanism, which is consistent with our previous data obtained with the corresponding Rous sarcoma virus domain. Second, we used preassembled IN-preprocessed DNA complexes to assay the potency of SQs against the strand transfer reaction, independently of 3'-processing. Inhibition occurred even if the efficiency was decreased by about 5- to 10-fold. Our results suggest that two inhibitor-binding modes exist: the first one prevents the binding of the viral DNA and then the two subsequent reactions (i.e., 3'-processing and strand transfer), whereas the second one prevents the binding of target DNA, thus inhibiting strand transfer. SQ derivatives have a higher affinity for the first site, in contrast to that observed for the diketo acids, which preferentially bind to the second one.
Molecular Pharmacology 02/2004; 65(1):85-98. · 4.88 Impact Factor
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ABSTRACT: Using the Kohonen neural network, the electrostatic potentials on the molecular surfaces of 14 styrylquinoline derivatives were drawn as comparative two-dimensional maps and compared with their known human immunodeficiency virus (HIV)-1 replication blocking potency in cells. A feature of the potential map was discovered to be related with the HIV-1 blocking activity and was used to unmask the activity of further five analogues, previously described but whose cytotoxicity precluded an estimation of their activity, and to predict the activity of 10 new compounds while the experimental data were unknown. The measurements performed later turned out to agree with the predictions.
Journal of Medicinal Chemistry 11/2002; 45(21):4647-54. · 5.25 Impact Factor
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ABSTRACT: Protein structures can be encoded into binary sequences (Gabarro-Arpa et al., Comput Chem 2000;24:693-698) these are used to define a Hamming distance in conformational space: the distance between two different molecular conformations is the number of different bits in their sequences. Each bit in the sequence arises from a partition of conformational space in two halves. Thus, the information encoded in the binary sequences is also used to characterize the regions of conformational space visited by the system. We apply this distance and their associated geometric structures to the clustering and analysis of conformations sampled during a 4-ns molecular dynamics simulation of the HIV-1 integrase catalytic core. The cluster analysis of the simulation shows a division of the trajectory into two segments of 2.6 and 1.4 ns length, which are qualitatively different: the data points to the fact that equilibration is only reached at the end of the first segment. The Hamming distance is compared also to the r.m.s. deviation measure. The analysis of the cases studied so far shows that under the same conditions the two measures behave quite differently, and that the Hamming distance appears to be more robust than the r.m.s. deviation.
Proteins Structure Function and Bioinformatics 06/2002; 47(2):169-79. · 3.39 Impact Factor
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ABSTRACT: Protein structures can be encoded into binary sequences (Gabarro-Arpa et al., Comput Chem 2000;24:693–698) these are used to define a Hamming distance in conformational space: the distance between two different molecular conformations is the number of different bits in their sequences. Each bit in the sequence arises from a partition of conformational space in two halves. Thus, the information encoded in the binary sequences is also used to characterize the regions of conformational space visited by the system. We apply this distance and their associated geometric structures to the clustering and analysis of conformations sampled during a 4-ns molecular dynamics simulation of the HIV-1 integrase catalytic core. The cluster analysis of the simulation shows a division of the trajectory into two segments of 2.6 and 1.4 ns length, which are qualitatively different: the data points to the fact that equilibration is only reached at the end of the first segment. The Hamming distance is compared also to the r.m.s. deviation measure. The analysis of the cases studied so far shows that under the same conditions the two measures behave quite differently, and that the Hamming distance appears to be more robust than the r.m.s. deviation. Proteins 2002;47:169–179. © 2002 Wiley-Liss, Inc.
Proteins Structure Function and Bioinformatics 04/2002; 47(2):169 - 179. · 3.39 Impact Factor
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ABSTRACT: Protein structures can be encoded into binary sequences, these are used to define a Hamming distance in conformational space: the distance between two different molecular conformations is the number of different bits in their sequences. Each bit in the sequence arises from a partition of conformational space in two halves. Thus, the information encoded in the binary sequences is also used to characterize the regions of conformational space visited by the system. We apply this distance and their associated geometric structures, to the clustering and analysis of conformations sampled during a 4 ns molecular dynamics simulation of the HIV-1 integrase catalytic core. The cluster analysis of the simulation shows a division of the trajectory into two segments of 2.6 and 1.4 ns length, which are qualitatively different: the data points to the fact that equilibration is only reached at the end of the first segment. Some length of the paper is devoted to compare the Hamming distance to the r.m.s. deviation measure. The analysis of the cases studied so far, shows that under the same conditions the two measures behave quite differently, and that the Hamming distance appears to be more robust than the r.m.s. deviation.
11/2001;
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ABSTRACT: Our prior studies showed that polyhydroxylated styrylquinolines are potent HIV-1 integrase (IN) inhibitors that block the replication of HIV-1 in cell culture at nontoxic concentrations. To explore the mechanism of action of these inhibitors, various novel styrylquinoline derivatives were synthesized and tested against HIV-1 IN and in cell-based assays. Regarding the in vitro experiments, the structural requirements for biological activity are a carboxyl group at C-7, a hydroxyl group at C-8 in the quinoline subunit, and an ancillary phenyl ring. However the in vitro inhibitory profile tolerates deep alterations of this ring, e.g. by the introduction of various substituents or its replacement by heteroatomic nuclei. Regarding the ex vivo assays, the structural requirements for activity are more stringent than for in vitro inhibition. Thus, in addition to an o-hydroxy acid group in the quinoline, the presence of one ortho pair of substituents at C-3‘ and C-4‘, particularly two hydroxyl groups, in the ancillary phenyl ring is imperatively required for inhibitory potency. Starting from literature data and the SARs developed in this work, a putative binding mode of styrylquinoline inhibitors to HIV-1 IN was derived.
Journal of Medicinal Chemistry 03/2000; 43(8). · 5.25 Impact Factor
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Computers & Chemistry. 01/1997; 21:343-345.
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ABSTRACT: We have written a programming language OCL (Object Command Language) to solve, in a general way, two recurring problems that arise during the construction of molecular models and during the geometrical characterization of macromolecules: how to move precisely and reproducibly any part of a molecular model in any user-defined local reference axes; and how to calculate standard or userdefined structural parameters that characterize the complex geometries of any macromolecule. OCL endows the user with three main capabilities: the definition of subsets of the macromolecule, called objects in OCL, with a formalism from elementary set theory or lexical analysis; the definition of sequences of elementary geometrical operations, called procedures in OCL, enabling one to build arbitrary three-dimensional (3D) orthonormal reference frames, to be associated with previously defined objects; and the transmission of these definitions to programs that allow one to display, to modify and to analyze interactively the molecular structure, or to programs that perform energy minimizations or molecular dynamics. Several applications to nucleic acids are presented.
Journal of Molecular Graphics.
