Kinetics of monensin complexation with sodium ions by 23Na NMR spectroscopy

The kinetics of the sodium binding to the ionophore monensin (Mon) in methanol has been studied by ²³Na NMR spectroscopy. Fast quadrupole relaxation of the bound sodium affected the relaxation rate of the free sodium through an exchange process between these two species. The exchange was found to be dominated by the reaction: Na⁺ + Mon^? ? MonNa. The dissociation rate constant at 25°C is 63 s^?1, with an activation enthalpy of 10.3 $\text{kcal}\text{mol}$ and activation entropy of ?15.8 $\text{cal}\text{mol}$ deg. These results indicate that the specificity of the binding of sodium ions to monensin is reflected in the relatively slow dissociation process. The entropy changes indicate that the activated monensin-sodium complex undergoes a conformational change, but the existence of a conformational change in monensin anion prior to complexation is excluded.     

23Na NMR study of intracellular sodium ions in Dictyostelium discoideum amoeba

The intracellular sodium concentration in the amoebae from the slime mold Dictyostelium discoideum has been studied using 23Na NMR. The 23Na resonances from intracellular and extracellular compartments could be observed separately in the presence of the anionic shift reagent Dy(PPPi)7-2 which does not enter into the amoebae and thus selectively affects Na+ in the extracellular space. 31P NMR was used to control the absence of cellular toxicity of the shift reagent. The intracellular Na+ content was calculated by comparison of the intensities of the two distinct peaks arising from the intra- and extracellular spaces. It remained low (0.6 to 3 mM) in the presence of external Na+ (20 to 70 mM), and a large Na+ gradient (20- to 40-fold) was maintained. A rapid reloading of cells previously depleted of Na+ was readily measured by 23Na NMR. Nystatin, an antibiotic known to perturb the ion permeability of membranes, increased the intracellular Na+ concentration. The time dependence of the 23Na and 31P NMR spectra showed a rapid degradation of Dy(PPPi)7-2 which may be catalyzed by an acid phosphatase.     

Stereospecific complexation of uranyl ion with tartaric acids studied by NMR spectroscopy

A full pH range ¹H and ¹³C NMR study was performed on the complexation of UO₂²⁺ with (D,L)- and meso-tartaric acids, for variable concentrations and molar ratios, in comparison with (D)-tartaric acid. The main result is that, in spite of the already high number of complexes formed with the active ligand, an additional species occurs with the racemic mixture for which experimental evidence indicates a cyclic trimer structure. A smaller number of complexes is formed with meso-tartaric acid. Information on the conformation of bound ligand is also obtained.     

Studies of the complexation of sugars by diffusion-ordered NMR spectroscopy

In the presence of lanthanide cations, some sugars with a special relationship between their hydroxyl groups are able to form complexes in water. Diffusion-ordered NMR spectroscopy (DOSY) can be used as a tool to distinguish between the complexed and noncomplexed forms in a mixture due to the differences in their relative diffusion coefficient values. The lowest diffusion was attributed to the complexed species because of the increase in both size and molecular weight when compared with the noncomplexed forms. Mixtures of sugars of the same molecular weight and also the isomers of a single monosaccharide can be 'separated' by DOSY on the basis of their different tendencies to form complexes with different diffusion coefficient values.     

Kinetics of enzyme-coenzyme interactions by NMR spectroscopy.

The kinetics for the binding of coenzymes to H4 and M4 lactate dehydrogenase from chicken were investigated by nuclear magnetic resonance spectroscopy. With detailed computer analysis, some kinetic parameters were extracted from the chemical shifts and the linewidth of the observed coenzyme resonances at various enzyme/coenzyme ratios and temperatures. The results of the analysis indicated that the dissociation rates of coenzymes from the enzyme/coenzyme complexes are slower with the H4 isozyme than those involving the M4 isozyme. The lifetimes for the NAD+-enzyme complexes are on the order of 1 msec while those for the NADH-enzyme complexes are on the order of 10 ms (at room temperature). Much shorter transverse relaxation times of the coenzyme resonances were observed in NADH-enzyme complexes than those in the NAD+-enzyme complexes. The calculated kinetic constants are in good agreement with the previous studies by stopped-flow and temperature jump methods. A generalized NMR kinetic treatment for the binding of small molecules to a macromolecule is presented.     

Theoretical and experimental study of the complexation of valinomycin with ammonium cation

The interactions of valinomycin, macrocyclic depsipeptide antibiotic ionophore, with ammonium cation NH4+ have been investigated. Using quantum mechanical density functional theory (DFT) calculations, the most probable structure of the valinomycin-NH4+ complex species was predicted. In this complex, the ammonium cation is bound partly by three strong hydrogen bonds to three ester carbonyl oxygen atoms of valinomycin and partly by somewhat weaker hydrogen bonds to the remaining three ester carbonyl groups of the valinomycin ligand. The strength of the valinomycin-NH4+ complex was evaluated experimentally by capillary affinity electrophoresis. From the dependence of valinomycin effective electrophoretic mobility on the ammonium ion concentration in the background electrolyte, the apparent binding (association, stability) constant (Kb) of the valinomycin-NH4+ complex in methanol was evaluated as log Kb = 1.52 +/- 0.22.     

Ring current effects in Adriamycin-flavin mononucleotide complexation as observed by 1H FT NMR spectroscopy

The addition of Adriamycin to a solution containing flavin mononucleotide (FMN) resulted in an upfield shift in the signals of the aromatic ring protons H(6,9) and the 8α, 7α methyl protons of FMN. The chemical shift of the H(6,9) and of the 8α and 7α methyl proton signals of FMN decreased from 7.92, 2.56 and 2.46 ppm, respectively, in the absence of Adriamycin to 7.61, 2.42 and 2.36 ppm, respectively, at 3 mM Adriamycin. Concomitant increases in the linewidth of aromatic and methyl proton siqnals of FMN were also observed. Variable temperature studies over the range of 5 to 43° showed an increase in the chemical shift of both the aromatic and aliphatic proton signals with increasing temperatures. These results suggest that FMN and Adriamycin form a complex via ring-ring stacking.     

Interactions of sodium,calcium, and lanthanum ions with methyl glycofuranosides in methanol

The ¹³C-n.m.r. spectra have been recorded and assigned for the xylo- and cello-oligosaccharides, the former up to xylopentaose, and the latter up to cello-tetraose. A spectrum of a low-d.p. cellulose in dimethyl sulfoxide-d₆ was also assigned. In every instance, the spectra of the higher oligosaccharides closely parallel those of the corresponding disaccharides. Variations in line intensities permitted assignment of peaks to both terminal groups and internal residues. A particularly important difference was observed between the chemical shifts at the internal C-4 atoms for the two series of oligomers. This difference has been interpreted as evidence for significant differences in average linkage-orientation or solvation, which is related to the absence of C-6 in the xylo-oligosaccharides.     

Kinetics of drug release from a hyaluronan-steroid conjugate investigated by NMR spectroscopy

The methylprednisolone steroid ester of hyaluronan was hydrolyzed under physiological conditions in vitro, and the kinetics of drug release was investigated by NMR spectroscopy. Transverse relaxation times are correlated with the molecular rotational freedom, which undergoes large changes for methylprednisolone when released. Multi-exponential decays were observed, which together with the corresponding population gave valuable insights into the conformational changes that occur in the biopolymer during hydrolysis. The biomaterial exists in aqueous solution in two conformations, ‘collapsed’ and ‘water-exposed’, in equilibrium. Under physiological conditions, the methylprednisolone is completely released within 48 h. Transverse relaxation times proved to be an appropriate tool for monitoring the drug release in vitro.     

NMR studies of intracellular sodium ions in mammalian cardiac myocytes

The unambiguous measurement of intracellular sodium ion [Na+]i by the noninvasive NMR technique offers a new opportunity to monitor precisely the maintenance and fluctuations of [Na+]i levels in intact cells and tissues. The anionic frequency shift reagent, dysprosium (III) tripolyphosphate, which does not permeate intact cells, when added to suspensions of intact adult rat cardiac myocytes, alters the NMR frequency of extracellular sodium ions, [Na+]o, leaving that of intracellular ions, [Na+]i, unaffected. Using 23Na NMR in conjunction with this shift reagent, we have determined NMR-visible intracellular Na+ ion concentration in a suspension of isolated cardiac myocytes under standard conditions with insulin and Ca2+ in the extracellular medium to be 8.8 +/- 1.2 mmol/liter of cells (n = 4). This value is comparable to that measured by intracellular ion-selective microelectrodes in heart tissue. Cardiac myocytes incubated for several hours in insulin-deficient, Ca2+-containing medium prior to NMR measurement exhibited a somewhat lower [Na+]i value of 6.9 +/- 0.5 mmol/liter of cells (n = 3). Reversible Na+ loading of the cells by manipulation of extracellular calcium levels is readily measured by the NMR technique. Incubation of myocytes in a Ca2+-free, insulin-containing medium causes a 3-fold increase in [Na+]i to a level of 22.8 +/- 2.6 mmol/liter of cells (n = 10). In contrast to cells with insulin, insulin-deficient myocytes exhibit a markedly lower level of [Na+]i of only 14.6 +/- 2.0 mmol/liter of cells (n = 4) in Ca2+-free medium. These observations suggest that insulin may stimulate a pathway for Na+ influx in heart cells.     

A quantitative study of the complexation of cadmium in hemolyzed human erythrocytes by 1H NMR spectroscopy

The stability of complexes formed by Cd2+ in hemolyzed human erythrocytes was studied by spin-echo 1H NMR spectroscopy. Changes in resonances for the carbon-bonded protons of glutathione (GSH) upon addition of the ethylenediaminetetraacetic acid complex of Cd2+ (Cd(EDTA)2-) and the appearance of resonances for Mg(EDTA)2- indicate that the Cd(EDTA)2- complex dissociates in hemolyzed erythrocytes with the formation of Cd(GSH)x and Mg(EDTA)2- complexes. A semiquantitative estimate of the overall stability constant for the complexation of Cd2+ in hemolyzed erythrocytes was obtained from spin-echo 1H NMR data. The stability constant is consistent with the majority of the Cd2+ in erythrocytes present as Cd(SG)2(2-). A conditional equilibrium constant was also determined for the complexation of Mg2+ by ligands in hemolyzed human erythrocytes.     

Cation binding in Na,K-ATPase, investigated by 205Tl solid-state NMR spectroscopy

Cation binding to Na,K-ATPase is characterized in native membranes at room temperature by solid-state NMR spectroscopy using the K(+) congener (205)Tl. It has been demonstrated that the signals from occluded Tl(+) and nonspecifically bound Tl(+) can be detected and distinguished by NMR. Effects of dipole-dipole coupling between (1)H and (205)Tl in the occlusion sites show that the ions are rigidly bound, rather than just occluded. Furthermore, a low chemical shift suggests occlusion site geometries with a relatively small contribution from carboxylate and hydroxyl groups. Nonspecific binding of Tl(+) is characterized by rapid chemical exchange, in agreement with the observed low binding affinity.     

Phosphate-dependent sodium transport in S. faecalis investigated by 23Na and 31P NMR

Na+ movements in S. faecalis were studied by 23Na NMR. They proved to be dependent on phosphate concentration in the buffer during the de-energization step. K+ and H+ were also studied respectively by potentiometry and 31P NMR and were shown not to be implicated. For de-energized cells the internal phosphate concentration, on the contrary, was directly linked to the external phosphate contained in the buffer. The experiments showed a Na+/Pi dependence in this prokaryote so far known only in eukaryotes.     

Stability of sodium and potassium complexes of valinomycin

Stability constants of sodium and potassium complexes of valinomycin in some alcohols and water—organic solvent mixtures have been determined by titration, using circular dichroism to monitor complex formation. Constants range from 10¹ to 10⁶ M⁻¹. Stability of the potassium and sodium complexes increases with decreasing dielectric constant, but the ratio of the constants remains about 10³–10⁴. As others have shown, a similar selectivity for K⁺ is observed in a number of other types of measurements involving valinomycin. These include the permeability and conductance ratios which characterize the selectivity of cation transport through membranes and the ratio of salt extraction equilibrium constants. On the basis of data presented here, and elsewhere, it is suggested that conformational constraints within the depsipeptide part of the complexes aid ion selectivity and that differences in cation solvation and carbonyl ligand binding energies make an important, roughly equal, contribution.     

The monensin-mediated transport of sodium ions through phospholipid bilayers studied by 23Na-NMR spectroscopy

The monensin-mediated transport of sodium ions through the walls of large unilamellar vesicles of egg phosphatidylcholine was studied using 23Na-NMR and aqueous shift reagents. The transport is dynamic on the NMR time-scale and is strictly first order in monensin over the concentration ranges studied indicating that transport occurs by a 1:1 Na+-ionophore complex. Transport appears to be inhibited by increasing concentrations of Na+.     

NMR spectroscopy of Group 13 metal ions: biologically relevant aspects

In spite of the fact that Group 13 metal ions (Al(3+), Ga(3+), In(3+) and Tl(+/3+)) show no main biological role, they are NMR-active nuclides which can be used in magnetic resonance spectroscopy of biologically relevant systems. The fact that these metal ions are quadrupolar (with the exception of thallium) means that they are particularly sensitive to ligand type and coordination geometry. The line width of the NMR signals of their complexes shows a strong dependence on the symmetry of coordination, which constitutes an effective tool in the elucidation of structures. Here we report published NMR studies of this family of elements, applied to systems of biological importance. Special emphasis is given to binding studies of these cations to biological molecules, such as proteins, and to chelating agents of radiopharmaceutical interest. The possibility of in vivo NMR studies is also stressed, with extension to (27)Al-based MRI (magnetic resonance imaging) experiments.