Conformations in solution and bound to bacterial ribosomes of ketolides, HMR 3647 (telithromycin) and RU 72366: a new class of highly potent antibacterials.

The new class of antibiotics called ketolides is endowed with remarkable antibacterial activity against macrolide-resistant strains. Further modifications of the 3 keto-macrolactone backbone led to 11,12-hydrazonocarbamate ketolides with an imidazolyl pyridine chain: the file-leader of ketolide class, HMR 3647 (telithromycin), and its N-bis-demethyl-derivative, RU 72366. The potency of HMR 3647 is higher than that of RU 72366. Stereospecific 1H and 13C resonance assignments of HMR 3647 and RU 72366 have been determined and have allowed a detailed quantitative conformational analysis of the uncomplexed form of the molecules. The comparative conformation of HMR 3647 in solution and its N-bis-demethyl-derivative in D2O has been carried out using different heteronuclear correlation experiments in conjunction with nuclear Overhauser effect experiments and in particular long-range 3J(CH) coupling constants and using molecular dynamics (MD) methods. The study of ketolide ribosome interaction has been investigated using two-dimensional transferred nuclear Overhauser effect spectroscopy (TRNOESY). The database of ribosome-bound ketolide structures has been used to compare the structure(s) of ketolide in ribosome-ketolide complexes with the conformational preferences of free ketolides and to highlight the significant differences between HMR 3647 and RU 72366. A comparison of the conformations bound to ribosome was made with those of other previously studied ketolide (RU 004) and macrolides and would explain the remarkable potencies of HMR 3647 in inhibiting protein synthesis.

Lincomycin and clindamycin conformations. A fragment shared by macrolides, ketolides and lincosamides determined from TRNOE ribosome-bound conformations.

Two important lincosamide antibiotics, lincomycin and clindamycin were studied in the complex state with the bacterial ribosome after a conformational analysis by 1H and 13C NMR spectroscopy and molecular modelling of the unbound molecules. Lincosamide-ribosome interactions were investigated using two-dimensional transferred nuclear Overhauser effect spectroscopy (TRNOESY), resulting in a bound structure compatible with the experimental NMR data. The results compared with the conformational analysis of the substrates in solution indicate that specific conformations are preferred in the bound state. Clindamycin, the more bioactive antibiotic studied, displayed a stronger NMR response than lincomycin showing that in lincosamide-ribosome interactions, a low affinity binding level is associated to the tight binding one and is related to biological activity. This study shows that conformation plays an essential role for the low affinity binding site. Superimposition of lincosamide, macrolide and ketolide bound structures exhibited conformational similarities in a particular fragment which is in agreement with a hypothesis of partial overlapping lincosamide and macrolide binding sites.

Conformational analysis of ketolide, conformations of RU 004 in solution and bound to bacterial ribosomes.

A new structurally distinct class of 14-membered-ring macrolides is characterized by a keto-function instead of the cladinose sugar, well-known for its fragility even in weakly acidic media. This new class called ketolides is endowed with remarkable antibacterial activity against macrolide-resistant strains. A complete assignment of the 1H and 13C NMR spectra of RU 004 in deuteriochloroform, methanol-d4 and D2O has been made using different two-dimensional (2D) chemical-shift correlation methods. The study of ketolide-ribosome interaction has been investigated using 2D transferred nuclear Overhauser effect spectroscopy (TRNOESY). A comparison of the conformations in solution and bound to ribosomes was made with those of previous macrolides. This study can highlight some of the significant differences between RU 004 and other antibiotics.

Predictive study by molecular modeling to promote specific probes of glutamate receptors, using methylated cyclic glutamic acid derivatives (trans- and cis-ACPD). Comparison with specific agonists.

Two classes of glutamate receptors (metabotropic and ionotropic) and their subclasses (groups I-III and N-methyl-D-aspartic acid (NMDA), kainic acid (KA)), respectively, are characterized by the binding of a L-glutamate moiety in a specific conformation. The conformations may be grouped by the two backbone torsion angles, chi1 [alpha-CO2-C(2)-C(3)-C4)] and chi2 [+NC(2)-C(3)-C(4)-gamma-CO2] and by the two characteristic distances between the potentially active functional groups, alpha-N+-gamma-CO2 (d1) and alpha-CO2-gamma-CO2 (d2). The conformational preferences of 2,3,4-methyl(a and b)-cis and trans-1-aminocyclopentane-1,3-dicarboxylate are discussed in the light of the physical features known for specific metabotropic (groups I-II) and specific ionotropic (NMDA, KA) agonists, respectively. The spatial orientation of the perceived functional groups was elucidated in cyclic derivatives which contain an embedded L-glutamate moiety in a particularly restricted conformation (relative to the C(2)-C(3)-C(4) bond) using a combination of NMR experimental results and mechanics and dynamics calculations. One important conclusion of the study is that a single glutamate receptor is privileged for each theoretical model considered by molecular dynamics. This study showed clearly what would be conformational preferences of cyclic glutamate derivatives following the geometrical isomerism of the methyl group.

Solution conformation of methylated macrolide antibiotics roxithromycin and erythromycin using NMR and molecular modelling. Ribosome-bound conformation determined by TRNOE and formation of cytochrome P450-metabolite complex.

Conformational study of methylated derivatives of macrolide antibiotics roxithromycin (6-OMe-roxithromycin and 6,11-OMe-roxithromycin) has been achieved by NMR in solution and molecular dynamics (MD) simulations and compared to 6-OMe-erythromycin (clarithromycin). A complete conformational study by NMR has been led by determination of homonuclear coupling constants and NOEs. Heteronuclear 1H-13C coupling constants were also measured to investigate the orientation of the sugar moieties with respect to the erythronolide. MD simulations were performed using the crystallographic coordinates as the starting conformation. For each compound, experimental results were compared to calculated conformations in order to identify eventual conformational equilibrium in solution. It is shown that the effect of the methylation is opposite for roxithromycin compared to erythromycin especially on motional properties as the roxithromycin derivatives gain in mobility while the erythromycin derivatives behaves as a more restrained molecule. The study of macrolide-ribosome interactions has been investigated using transferred NOESY 1H NMR experiments and the conformations weakly bound to bacterial ribosomes were determined. Biological interactions of these compounds with membranar liver protein cytochrome P450 was also discussed with regard to their structural properties.

Transferred nuclear Overhauser effect study of macrolide-ribosome interactions: correlation between antibiotic activities and bound conformations.

The study of macrolide-ribosome interactions has been investigated using two-dimensional transferred nuclear Overhauser effect spectroscopy (TRNOESY). A new medically important macrolide antibiotic, roxithromycin, with the replacement of the 9-keto group in erythromycin by a 9-oxime chain, was studied in the complex state with the bacterial ribosome. Analysis of transferred nuclear Overhauser effect (TRNOE) experiment resulted in a set of constraints for all protons pairs. These constraints were used in structure determination procedures based on molecular modelling to obtain a bound structure compatible with the experimental NMR data. The results compared with the conformational analysis of the substrate in solution indicate that only one specific conformation is preferred in the bound state while in the free state the sugar ring moities were relatively disordered. The bioactive macrolide antibiotics studied roxithromycin and erythromycin which displayed a strong NMR response, are metabolized in RU39001 and erythralosamine respectively which do not retain antimicrobial activity. The inactive major metabolites were used to define if TRNOEs observation may be characteristic of a biological activity. These control experiments gave essentially blank TRNOESY spectra. This study shows that Mg2+ does not play a direct role for the low affinity binding site studied by TRNOE what is in agreement with an hypothesis of two distinct binding levels, with a low affinity binding level necessary for the tight binding one.

Structure of kainic acid totally elucidated by NMR and molecular modelling.

One class of glutamate receptors is characterized by the binding of the neuroexcitant and toxin kainic acid (KA), which contains an embedded L-glutamate moiety in a partially restricted (about the 2,3-bond) conformation. While there are a number of compounds that exhibit high specificity and selectivity at the ionotropic N-methyl-D-aspartate receptor, there has been a lack of selective and high-affinity ligands for the ionotropic KA subclass of excitatory amino acid receptors. This substance has received some attention recently being the least understood of the ionotropic type of glutamate receptor. The spatial orientation of the perceived functional groups of KA has been elucidated by a conformational analysis of an aqueous solution of KA using a combination of nuclear magnetic resonance (NMR) experimental results, mechanics and dynamics calculations, and theoretical simulation of NMR spectra. The weak pH-dependent effects on overall conformation and the structure of the principal '4E-envelope' KA conformer are established in aqueous solution. This study clearly shows the structural 'down' position of the double bond and the preferred 'g(-)-c' conformation of the C(3) carboxymethyl side-chain. The complex structure of this compound is thus definitively resolved. The conformation of the envelope ring such as C(3) carboxymethyl and C(4)-isopropenyl groups may strongly influence the potencies of KA interactions with the KA receptor.

Solution conformation of alpha, beta or gamma-methylglutamyl-containing derivatives as probes of vitamin K-dependent carboxylase using molecular modelling and nuclear magnetic resonance.

In the present study, the conformational behaviour of methyl substituted N-BOC glutamic acid methyl esters (2M, 3T, 3E, 4T, 4E) has been completely characterized through combined NMR and molecular modeling studies. Hetero- and homonuclear coupling constants were measured in order to assign the remaining diastereotopic methylene protons at C(3) and/or C(4), and used for comparison with theoretical data. In parallel, the complete conformational analysis of these analogues has been achieved using molecular mechanics and molecular dynamics (MD) methods. The conformation of the glutamyl residue is established by the excellent agreement between the experimental and calculated side chain scalar coupling constants. The theoretical NMR data were calculated taking into account all the accessible conformations and using the averaging methods appropriate for internal motions. There is a significant influence of the methyl group on the conformational behaviour and on the biological relevance of these structures. Steric effect or electrostatic interaction may also have a considerable influence in stabilizing a conformational population in D2O solution. The conformational preferences of those different analogues in aqueous and methanol solution are discussed in the light of biological results obtained on the vitamin K-dependent carboxylase system.

Conformational analysis of glutamic acid analogues as probes of glutamate receptors using molecular modelling and NMR methods. Comparison with specific agonists.

The activity of five glutamic acid analogues substituted in position 3 or 4 by a methyl (3T, 3E, 4T, and 4E) or a methylene group (4M) has been examined at one cloned Glu receptor subtype, mGluR1. These analogues interact with glutamate receptors of the central nervous system, especially the ligand 4T [(2S,4S)-4-methylglutamic acid] at the metabotropic glutamate receptor mGluR1. It was observed that only the 4T isomer is as potent an agonist as glutamic acid, whereas other isomers are less active. Furthermore, 4E [(2S,4R)-4-methylglutamic acid] exhibited an exceptional selectivity for the KA ionotropic receptor subtype while 4M [(2S)-4-methyleneglutamic acid] was active at the NMDA receptors. These molecules represent suitable tools among a population of similar glutamate analogues for a classical structure-function relationship study. We have undertaken a conformational analysis by 1H and 13C NMR spectroscopy and molecular modelling of these molecules. Hetero- and homonuclear coupling constants were measured in order to assign the diastereotopic methylene protons at C(3) or C(4), and used for comparison in molecular dynamics (MD) simulations. The hydrogen-bonding possibility, steric effects or electrostatic interactions may be a considerable influence in stabilizing a conformational population in D2O solution. The conformations may be grouped by the two backbone torsion angles, chi 1 [alpha-CO2(-)-C(2)-C(3)-C(4)] and chi 2 [+NC(2)-C(3)-C(4)-gamma CO2-] and by the two characteristic distances between the potentially active functional groups, alpha N(+)-gamma CO2- (d1) and alpha CO2(-)-gamma CO2- (d2). The conformational preferences in solution of 4T, 4E and (3T, 3E, 4M) are discussed in the light of the physical features known for a specific metabotropic agonist (ACPD) and specific ionotropic agonists (KA) and (NMDA), respectively.

Vitamin K-dependent carboxylase. In vitro inhibitory activity of cyclopentane and cyclohexane-derived analogues of glutamic acid and their conformational study by NMR and molecular dynamics in aqueous solution.

The conformational analysis of four glutamic acid analogues containing a cyclopentyl or cyclohexyl ring, substituted in position 1 by a Boc-protected amino group and a methyl ester group and in position 3 by a free carboxylate group (6-9), has been carried out in an aqueous environment, by 1H and 13C NMR spectroscopy, and molecular dynamics (MD). These compounds have been shown to be weak competitive inhibitors (Ki approximately 20-65 mM) of the vitamin K-dependent carboxylation of Boc-Glu-OMe in rat liver microsomes independently of their ring size and stereochemical features. However, the cyclic trans isomers have been found more active than the cis ones, and Boc-trans-C5-OMe (9) is the most potent inhibitor in the series (cis and trans isomers are defined by the relative arrangement of the carboxyl functions). Such cyclic glutamyl derivatives may provide valuable informations on the preferred bioactive conformations of synthetic glutamyl substrates at the active site of the carboxylase. In aqueous solution, the Boc-cis- and trans-C6 esters exhibit chair conformations with exclusively equatorial and axial substituent positions, while the Boc-cis- and -trans-C5 compounds may display envelope E or 'twist' T conformations with the substituents in the following positions, equatorial; axial and isoclinal. For each compound, the conformations resulting from NMR and MD data were analyzed and classified according to the dihedral angles chi 1 and chi 2, the distances of functional groups, and the spatial charge distribution involving the free carboxyl group. A reduced number of conformational families were found to be in qualitative agreement with NMR and MD data. These results are discussed in relation with the carboxylase inhibitory activity of the analogues, and a spatial disposition of the glutamyl side chain that could be recognized by the carboxylase is deduced.

Conformational study in water by NMR and molecular modeling of cyclic glutamic acid analogues as probes of vitamin K dependent carboxylase.

The conformational analysis of four glutamic acid analogues containing a cyclopentyl or cyclohexyl ring, substituted in position 1 by a BOC protected amino group and a methyl ester group and in position 3 by a free carboxylate group, has been carried out in an aqueous environment, by 1H and 13C NMR spectroscopy, and molecular dynamics (MD). Their structural properties were under investigation for a structure-activity relationship analysis to determine the preferred conformation in the carboxylase active site. For each compounds, resulting conformations from NMR and MD data were analyzed and classified according to the dihedral angles chi 1 and chi 2, the distances and the spatial distribution involving charged or substituted C- and N-terminal groups. A reduced number of conformational families were found to be in qualitative agreement with NMR and MD data. A comparison between these different classes of the active and nonactive derivatives was achieved.

Conformational change due to esterification of hydroxy groups in erythromycin A and its major metabolite: analysis of these derivatives with different biological properties using NMR and molecular dynamics (MD) data.

A conformational study is performed on the acylated erythromycin and erythralosamine derivatives from comparison between experimental results (NMR) and theoretical calculations by Molecular Dynamics (MD) in attempts to correlate their conformations with their abilities to generate cytochrome P450-nitroso metabolite complexes in vitro. As the 3'-dimethyl-amino function of the desosamine is metabolized and responsible for the interaction with cytochrome P450, its position, mobility and steric hindrance in the proximity of this functional group are related to its biological properties. The major conformations of the lactone ring were termed A (A1, A2, A3) and B (B1, B2), and this macrocycle flexibility induced five different orientations a, b, c, d and e for the desosamine sugar. Conformations A and B differ in many ways but the major change is the inward folding of the C(3) fragment in B. Conformer a exhibits an orientation of the desosamine nearly perpendicular to the macrocycle whereas the two units are in the same plane in conformations c and e. For conformation b, the cladinose unit lifts up above the macrocycle. Conformation d exhibits a turned-back cladinose. In the erythromycin derivatives esterification at the beta position to the N(CH3)2 group of the desosamine reduces the degree of freedom of the macrocyclic lactone ring which corresponds to conformation A only. The desosamine sugar was found to be perpendicular to the macrocycle (a conformer) and both sugar groups are parallel to reduce the steric energy. In the erythralosamine derivatives, the macrocycle is always present as conformation B with the two conformations b and c of the sugar rings. The steric parameters favour the b conformers in which the amino group is tilted up, while in 3,2'-dibenzoylated stacking aromatic attraction stabilizes the planar c conformer. Both isomers are thus shown to adopt well-defined conformations and to be well-adapted for a comparative structure-activity correlation studies. There is a significant relationship between the conformation b and the formation of cytochrome P450-nitroso metabolite complexes.

A comparative NMR study between the macrolide antibiotic roxithromycin and erythromycin A with different biological properties.

1H nuclear Overhauser enhancement studies and 1H NMR 3J analysis establish the similarity between the major solution-state conformation of roxithromycin (1) and the erythromycin (2). A major difference between the structure of antibiotics 1 and 2 is the replacement of the 9-keto group in 2 by a 9-[O-(2,5-dioxahexyl)oxime] group. The NOE studies show that this oxime chain is oriented above the macrocyclic lactone ring and that the oxygen atoms of this chain are engaged in tight hydrogen bonding with a water molecule and with the 6- and 11-hydroxyl groups of the macrocycle. It results in a globular form of the whole roxithromycin molecule. These data explain also a relative hydrophobicity of this antibiotic. Erythromycin A (2), which presents a less rigid macrocycle with two free hydroxyl groups (6-OH and 11-OH), forms a dimer detected by FAB mass spectroscopy. 1H and 13C NMR relaxation measurements (T1) for both antibiotics show that interresidue hydrogen bonds in roxithromycin reduce the rotational freedom of the macrocyclic lactone ring and consequently the motions of desosamine and cladinose sugars. In another way, an ionization of the amino function occurs in the various media according to the nature of the antibiotic. This would allow the reactivity modification of the desosamine unit. In the biological study, the modifications of the 455-nm metabolite-cytochrome P-450 complex formation are observed.