Heteroassociation of antibiotic norfloxacin with aromatic vitamins in aqueous solution

Heteroassociation of antibacterial antibiotic norfloxacin with aromatic vitamins nicotinamide and flavin mononucleotide in aqueous solution was studied by ¹H NMR spectroscopy (500 MHz). Equilibrium constants, induced proton chemical shifts, and thermodynamic parameters (ΔH, ΔS) for the reactions of heteroassociation of the molecules were determined on the basis of the concentration and temperature dependences of proton chemical shifts for interacting aromatic molecules. The analysis of the results obtained indicates the formation of heterocomplexes between vitamin molecules and norfloxacin owing to stacking interactions between aromatic chromophores and additional intermolecular hydrogen bonding in norfloxacin-nicotinamide. The most probable spatial structures of 1:1 norfloxacin-flavin mononucleotide and norfloxacin-nicotinamide heterocomplexes were determined by molecular modeling methods using X-PLOR software on the basis of analysis of induced proton chemical shifts.     

Complexation of the quinolone antibiotic norfloxacin with DNA

¹H-NMR spectroscopy (500 MHz) was used to study the complexation of the antibacterial agent norfloxacin (NOR) with DNA tetramers 5′-d(TpGpCpA) and 5′-d(CpGpCpG) in aqueous solution. For the first time, the equilibrium parameters (equilibrium constants, enthalpy, and entropy) were obtained for NOR binding with single-stranded and duplex DNA tetramers. By analyzing the complexation parameters and the induced proton chemical shifts in NOR in various complexes, the character of NOR binding was identified as intercalation in the case of the duplex tetramers and as intercalation with external binding in the case of single-stranded tetramers. NOR proved to preferentially bind to GC sites in DNA duplexes.     

1H-NMR analysis of heteroassociation of caffeine with antibiotic actinomycin D in the aqueous solution

The molecular basis of the action of caffeine as a complex forming agent, an interceptor of aromatic drugs intercalating into DNA was studied by the example of the an anticancer antibiotic actinomycin D examined. The hetero-association of caffeine and actionomycin D was studied by one- and two-dimensional 1H-NMR spectroscopy (500 MHz). Concentration and temperature dependences of the proton chemical shifts of molecules in aqueous solution were measured. The equilibrium reaction constant of hetero-association of caffeine with actinomycin D (K = 246 +/- 48 M-1), the limiting chemical shifts of caffeine protons in complexes were determined. The most favourable structure of the 1:1 caffeine-actinomycin D hetero-complex in aqueous solution was constructed using the calculated values of the induced proton chemical shifts of molecules and the quantum-mechanical iso-shielding curves for caffeine and actinomycin D. The thermo-dynamical parameters of the hetero-complex formation between caffeine and actinomycin D were also determined. The structural and thermo-dynamical analysis showed that dispersive forces and hydrophobic interactions play the major role in hetero-association of caffeine and actinomycin D in aqueous-salt solution. The relative content of different complexes in mixed solutions containing caffeine and actinomycin D was calculated and distinctive features of the dynamic equilibrium of caffeine-actinomycin D hetero-associates were revealed as a function of concentration and temperature. It is concluded that hetero-association of caffeine and actinomycin D molecules a lowers the effective concentration of the drug in solution and hence the pharmacological activity of actinomycin D.     

Interaction of the antibiotic norfloxacin with ionic micelles: pH-dependent binding

The interaction of the antimicrobial drug norfloxacin (NFX) with anionic sodium dodecyl sulfate (SDS) and cationic cetyltrimethylammonium bromide (CTAB) micelles was studied using the intrinsic spectroscopic properties of NFX to obtain association constants and molecular modifications. Nonionic Tween^® 20 micelles were also investigated, but the spectroscopic properties of NFX did not detect interactions with these micelles, and quenching by iodide suggested a weak association constant around 47 M^?1. For SDS and CTAB, UV–Vis absorption spectroscopy, steady-state and time-resolved fluorometry were monitored as a function of surfactant concentration ranging from the premicellar to micellar region. It was found that cationic (pH 4.0) and zwitterionic NFX (pH 7.4) associate with SDS micelles, with binding constants equal to 5.4 × 10³ and 1.7 × 10³ M^?1, respectively. Premicellar interaction slightly decreases the critical micelle concentration of SDS. Association of anionic NFX (pH 10.6) is very weak. The fluorescence spectrum and lifetime showed that SDS-associated NFX is cationic and that the heterocycle penetrates the interfacial environment of decreased polarity. Cationic CTAB micelles do not bind cationic NFX, and the association constant with zwitterionic NFX is two orders of magnitude lower than that of SDS micelles. From a pharmacological point of view, it is important that at neutral pH, NFX presented a two orders of magnitude higher affinity for anionic than for cationic sites, and did not interact significantly with nonionic or zwitterionic micelle interfaces.     

1H NMR analysis of the complex formation of aromatic molecules of antibiotic and vitamin in aqueous solution: heteroassociation of actinomycin D and flavin mononucleotide

The molecular mechanism of the combined action of antibiotic and vitamin was studied by NMR spectroscopy. The heteroassociation of the antitumor antibiotic actinomycin D and flavin mononucleotide was investigated as a function of concentration and temperature by 500 MHz 1H NMR spectroscopy. The equilibrium association constant, the thermodynamic parameters (deltaH, deltaS) of heteroassociation of actinomycin D with flavin mononucleotide, and the limiting values of proton chemical shifts in the heterocomplex were determined from the concentration and temperature dependences of proton chemical shifts of molecules. The most favorable structure of the 1:1 actinomycin D-flavin mononucleotide heteroassociation complex was determined using both the molecular mechanics methods (X-PLOR software) and the limiting values of proton chemical shifts of the molecules. In the calculated structure, the planes of the chromophores of actinomycin D and flavin mononucleotide molecules in the 1:1 heterocomplex are parallel and separated from each other by a distance of about 0.34 nm. At the same time, there is a probability of formation of intermolecular hydrogen bonds in the calculated structure of 1:1 actinomycin D-flavin mononucleotide complex. The analysis of the results obtained suggests that aromatic molecules of vitamins, e.g., flavin mononucleotide, can form energetically favorable heterocomplexes with aromatic antitumor antibiotics in aqueous solution, modulating thereby the efficacy of their medical and biological action.     

1H NMR study of the complexation of the quinolone antibiotic norfloxacin with DNA

Complexation of antibiotic norfloxacin (NOR) with DNA fragments 5'-d(TpGpCpA) and 5'-d(CpGpCpG) has been studied in aqueous solution by 1H NMR spectroscopy (500 MHz). Equilibrium parameters of the complexation with single-stranded and duplex forms of DNA oligomer--equilibrium constants, enthalpy and entropy--have been obtained for the first time. Based on the analysis of the complexation parameters as well as induced chemical shifts of the antibiotic protons within different complexes, it was found that NOR binds with the tetramer duplexes mainly by intercalation. The complexation with the single-stranded form may occur either by intercalation and external binding. The site of preferential binding of the antibiotic with DNA duplex is GC site.     

1H-NMR analysis of the heteroassociation of caffeine with the antibiotic actinocyl-bis(3-dimethylaminopropylamine) in aqueous solution

The heteroassociation of caffeine (CAF) and the synthetic antibiotic actinocyl-bis(3-dimethylaminopropylamine) (ACT) was studied in aqueous solution by one- and two-dimensional 1H NMR spectroscopy at 500 MHz. The equilibrium reaction constants, thermodynamic parameters (delta H and delta S) of ACT heteroassociation with CAF, the limiting values of proton chemical shifts of their molecules in the heteroassociation complex, and the spatial structure of the ACT-CAF complex were determined from the experimental dependences of proton chemical shifts of the aromatic molecules on concentration and temperature. The parameters of CAF heteroassociation with the phenoxazone antibiotic actinomycin D and its synthetic analogue ACT were comparatively analyzed and conclusions were made on the crucial role of stacking interactions of the chromophores of CAF and the phenoxazone antibiotics in the formation of the heterocomplexes in aqueous solution.     

A well-defined amphipathic conformation for the calcium-free cyclic lipopeptide antibiotic, daptomycin, in aqueous solution

Daptomycin is a 13-residue cyclic lipopeptide with Ca2+-dependent bactericidal activity against a variety of high-risk pathogens. Ring closure in daptomycin is via an ester linkage between the side chain of Thr4 and the C-terminal carboxyl of the main chain; the N-terminal residue is capped by a decanoyl aliphatic chain. Extensive NMR data obtained under solution conditions that minimize aggregation have provided constraints for a detailed conformational analysis of daptomycin in aqueous solution, which should facilitate the rational design of improved analogs and enhance understanding of its mode of action. Transannular and shorter-range nuclear Overhauser effects (NOEs) as well as amide temperature shifts and 3J(NH alpha) coupling constants indicate that daptomycin adopts a well-defined conformation containing a distorted hairpin formed by Gly5-D-Ala6 type II' beta-turn. A number of hydrophobic moieties (the lipid N-cap and the Trp1 and Kyn13 side chains) are clustered at one end of the hairpin, while neutral polar and anionic residues are localized on the other end, leading to amphipathicity in the molecule. These features suggest a mode of action in which the large hydrophobic cluster of the peptide interacts with the acyl chain region of a membrane. This interaction may be facilitated by Ca2+ ions, both by neutralizing the anionic charges and by favoring association with the membrane head groups. Interestingly, our findings differ from two recent articles in which the aqueous conformation of Ca2+-free daptomycin is reported to lack a well-defined conformation (D. Jung, A. Rozek, M. Okron, and R. E. W. Hancock, Chemistry & Biology, 2004, Vol. 11, pp. 949-957) or is suggested to populate an alternate conformation (L.-J. Ball, C. M. Goult, J. A. Donarski, J. Micklefield, and V. Ramesh, Organic & Biomolecular Chemistry, 2004, Vol. 2, pp. 1872-1878).     

Fluorescence study of the macrolide pentaene antibiotic filipin in aqueous solution and in a model system of membranes.

The polyene antibiotic filipin (a pentaene) has been studied using photophysical techniques. The polyene self-aggregates in water with a critical micellar concentration of 2 microM. Two approaches were used to evaluate the aggregate dimensions: (a) a lower limit of 10 nm for the aggregate radius was obtained from energy transfer experiments; (b) a formula for rationalizing the turbidity spectrum was derived, and from its application a spherical shape of radius about 50 nm was deduced. The low value for the fluorescence anisotropy of the aggregate (r = 0.02) is compatible with a very loose structure, i.e. the chromophore has very efficient depolarization dynamics that is not controlled by the aggregate size. The Stern-Volmer plot of aggregated filipin fluorescence quenching by iodide is non-linear, presenting a downward curvature. A model was used for the interpretation of these data, along with a study of the quenching in transient state; it was concluded that all the components of the decay are affected by the quencher, i.e. the aggregate has a very open structure with respect to the iodide ion. The partition constants of the polyene, Kp, between a model system of membranes (small unilamellar vesicles of dipalmitoylglycerophosphocholine) and the aqueous phase were determined from anisotropy measurements; the values obtained were Kp (gel phase) = (3.4 +/- 0.8) x 10(3) and Kp (liquid crystal phase) = (7.7 +/- 2.2) x 10(2). The observation that the polyene incorporation is efficient is at variance with the belief that the presence of sterols are essential for the interaction of polyene antibiotics with membranes [for review see Bolard, J. (1986) Biochim. Biophys. Acta 864, 257-304].     

NMR study of complex formation of aromatic ligands with heptadeoxynucleotide 5'-d(GCGAAGC) forming stable hairpin structure in aqueous solution

Complex formation of hairpin-producing heptadeoxynucleotide 5'-d(GCGAAGC) with aromatic molecules: acridine dye proflavine and anthracycline antibiotic daunomycin was studied by one-dimensional 1H NMR and two-dimensional correlation 1H-1H (2M-TOCSY, 2M-NOESY), 1H-31P (2M-HMBC) NMR spectroscopy (500 and 600 MHz) in aqueous solution. Concentration and temperature dependences for the chemical shifts of ligand protons were measured, molecular models of equilibrium in solution were developed, and equilibrium thermodynamic parameters for the formation of intercalation complexes were calculated. Spatial structures of dye and antibiotic complexes with the heptamer hairpin were constructed on the basis of 2M-NOE data and the calculated values of limiting chemical shifts of ligand protons.     

Heparin-polypeptide interactions in aqueous solution

Circular dichroism spectroscopy has been used to study the interactions between heparin and cationic polypeptides in dilute aqueous solution at neutral pH. The results indicate that poly(l-lysine), poly(l-arginine), and poly(l-ornithine) adopt the α-helical conformation in the presence of heparin, rather than the “charged coil” form observed for the polypeptide alone under the same conditions. Maximum interaction for the poly(l-lysine) and poly(l-ornithine) systems occur at an amino acid: disaccharide residue ratio of 2.3 ± 0.1:1, which correlates with the analytical data of 2.3 sulfates per heparin disaccharide. For poly(l-arginine), maximum interaction occurs at a residue ratio of 3.3 ± 0.1:1, and indicates that all the anionic groups (sulfate and carboxyl) of the heparin are involved in this case.The interactions of heparin are analogous to those observed previously for six connective tissue mucopolysaccharides, except that none of the latter had any effect on the conformation of poly(l-ornithine). The poly(l-ornithine)-heparin system shows a thermal “melting” transition at T_m = 56.0 ± 1.0 °C, at which point the polypeptide reverts to the “charged coil” form; the interactions with poly(l-lysine) and poly(l-arginine) are stable up to temperatures > 90 °C. The high thermal stability of these conformation-directing effects indicate a stronger interaction for heparin than the other mucopolysaccharides, which is probably due to the high sulfate content.     

Trehalose-protein interaction in aqueous solution

A variety of sugars are known to enhance the stability of biomaterials. Trehalose, a nonreducing disaccharide composed of two alpha, alpha(1 --> 1)-linked D-glucopyranose units, appears to be one of the most effective protectants. Both in vivo and in vitro, trehalose protects biostructures such as proteins and membranes from damage due to dehydration, heat, or cold. However, despite the significant amount of experimental data on this disaccharide, no clear picture of the molecular mechanism responsible for its stabilizing properties has emerged yet. Three major hypotheses (water-trehalose hydrogen-bond replacement, coating by a trapped water layer, and mechanical inhibition of the conformational fluctuations) have been proposed to explain the stabilizing effect of trehalose on proteins. To investigate the nature of protein-trehalose-water interactions in solution at the molecular level, two molecular dynamics simulations of the protein lysozyme in solution at room temperature have been carried out, one in the presence (about 0.5 M) and one in the absence of trehalose. The results show that the trehalose molecules cluster and move toward the protein, but neither completely expel water from the protein surface nor form hydrogen bonds with the protein. Furthermore, the coating by trehalose does not significantly reduce the conformational fluctuations of the protein compared to the trehalose-free system. Based on these observations, a model is proposed for the interaction of trehalose molecules with a protein in moderately concentrated solutions, at room temperature and on the nanosecond timescale.     

Conformation of allantoicase in aqueous solution

1. The separation of 0.9-S and 10.8-S allantoicase with the aid of a 2H2O-H2O gradient was described. The resulting preparations were subjected to sedimentation equilibrium, optical rotatory dispersion (ORD), circular dichroism (CD) and infrared studies. 2. The molecular weight of 0.9-S allantoicase was determined to be about 1.1 x 10(4) g/mole in studies on the sedimentation behavior, the metal content and amino acid composition. The molecular weight of 10.8-S allantoicase was about 15.4 x 10(4) g/mole. 3. Optical rotatory dispersion, circular dichroism and infrared studies indicated that both molecules contain alpha-helix, beta conformation and random coil. A Cotton effect at 418 nm was ascribed to the asymmetric binding of Mn2+ to the enzyme. Competitive inhibitors decreased the absorption and circular dichroism bands at about 280 nm and 418 nm. These phenomena suggested that the aromatic groups may play an essential role in the binding of substrates and inhibitors by the Mn(2+)-enzyme complex. 4. Comparison of alpha-helical contents of metalloallantoicases showed that the enzymes with low helical contents exhibited high enzymic activities. 5. The nearly identical physicochemical behavior and specific enzymic activity of 0.9-S and 10.8-S allantoicase indicated that they are very similar in structure and conformation.     

Equilibria of polyoxometalates in aqueous solution

In most aqueous polyoxometalate systems, numerous, often highly negatively charged species, are formed. To establish the speciation in such complex polyanion systems, many experimental methods and techniques must be used. Moreover, it is of vital importance that the experimental data are of the highest accuracy and that the data collected from different methods are treated simultaneously with an appropriate computer program. In systems containing one or more sensitive NMR nuclei, a combined EMF-NMR method has been shown to be extremely powerful.This article firstly gives some general comments on equilibria in aqueous polyoxometalate systems including ionic medium effects, and then describes an equilibrium EMF-NMR (³¹P and⁵¹V) study of the five component system H⁺-Mo(VI)-V(V)-P(V)-e^–. The study has been focused on so-called Keggin ratio solutions, Mo+V):P=12:1, since these are commonly used in selective oxidation processes. Special attention has been given to Mo₁₀V₂P and Mo₉V₃P solutions, where positional isomers occur. We have been able to identify and characterize all the five possible isomers of -Mo₁₀V₂PO ₄₀ ^5– at 25 and 90 °C. Besides the results from the five component system, some interesting findings from the binary, ternary and quarternary sybsystems are also reported.     

Conformation of poly-L-tyrosine in aqueous solution

The conformational transition of poly-L -tyrosine in 0.1M KCl was investigated by ORD and infrared spectroscopy, potentiometric titration, and sedimentation velocity experiments. It is shown that the fully ordered conformer is obtained by slow titration of the random coil with 0.1N HCl at 25°C. The charge-induced transition, at variance with other poly-α-amino acids, is completed in a narrow range of α. An aggregation process was detected both by potentiometric titration and sedimentation velocity. The polyamino acid aggregates around α = 0.7 at 25°C when the conformational transition is almost complete. Infrared spectra, in the region of the amide I band (1650 cm^?1) showed that the transition is a random coil → antiparallel β one. Evidence exists that the form is of the intramolecular type. The foregoing interpretations of ORD and CD spectra in terms of the α-helix conformation are discussed.