Calcium binding to mixed cardiolipin-phosphatidylcholine bilayers as studied by deuterium nuclear magnetic resonance

Calcium binding to bilayer membranes containing cardiolipin (CDL) mixed with 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) was investigated by using phosphorus-31 and deuterium nuclear magnetic resonance (NMR) spectroscopy. The destabilizing effect of Ca2+ on CDL bilayers, including the formation of hexagonal H11 and isotropic phases, was eliminated when CDL was mixed with sufficiently large proportion of POPC. Thus, for the mixture CDL-POPC (1:9 M/M), 31P NMR spectra retained a line shape typical of fluid bilayer lipids even in the presence of 1.0 M Ca2+. Specifically head-group-deuteriated CDL or POPC showed in this mixture 2H NMR spectra indicating that both lipids remained in a fluidlike bilayer at Ca2+ concentrations up to 1.0 M. Any phase separation of Ca2-CDL clusters could be excluded. The residence time of Ca2+ at an individual head group binding site was shorter than 10(-6) s. The deuterium quadrupole splitting, delta nu Q, of POPC deuteriated at the alpha-methylene segment of the choline head group was found to be linearly related to the number of bound calcium ions, X2, for the CDL-POPC (1:9 M/M) mixture. The effective surface charge density, sigma, could be determined from the measured amount of bound Ca2+. Subsequently, the surface potential, psi 0, and the concentration of free Ca2+ ions at the plane of ion binding were calculated by employing the Gouy-Chapman theory. Various possible models of the equilibrium binding of Ca2+ could then be tested.(ABSTRACT TRUNCATED AT 250 WORDS)     

Calcium binding to mixed phosphatidylglycerol-phosphatidylcholine bilayers as studied by deuterium nuclear magnetic resonance

The binding of calcium to bilayer membranes composed of mixtures, in various proportions, of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) plus 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoglycerol (POPG) was investigated by using atomic absorption spectroscopy and deuterium nuclear magnetic resonance. The number of bound calcium ions, X2, was determined in the low calcium concentration range (up to 100 mM) via atomic absorption spectroscopy. Simultaneous measurements of the deuterium magnetic resonance spectra of POPC, specifically deuteriated at the alpha-methylene segment of the choline head group, revealed a linear relationship between the quadrupole splitting, delta vQ, and X2 for each particular proportion of POPC-POPG. The amount of bound calcium was then determined at much greater calcium concentrations, where the atomic absorption spectroscopy measurements were unreliable, using deuterium magnetic resonance. At low Ca2+ concentrations, the amount of bound Ca2+ increased linearly with increasing proportion of POPG, demonstrating an electrostatic contribution to Ca2+ binding. At high Ca2+ concentrations, the calcium binding isotherms exhibited saturation behavior with a maximum binding capacity of 0.5 Ca2+ and 1.0 Ca2+ per phospholipid for pure POPC and mixtures of POPC-POPG, respectively. Simultaneous deuteriation of POPG and POPC showed that both lipids remained in a fluidlike lipid bilayer at all Ca2+ concentrations tested. Any phase separation of quasi-crystalline Ca2+-POPG clusters could be excluded. The residence time of Ca2+ at an individual head group binding site was shorter than 10(-6)-10(-5) s. Thus, Ca2+ ions accumulate near the negatively charged POPG-POPC membrane surface but move freely in a "trough" of the electrical potential. The effective surface charge density, sigma, could be determined from the measured amount of bound Ca2+. Subsequently, the surface potential, psi 0, and the concentration of free Ca2+ ions at the plane of ion binding could be calculated by employing the Gouy-Chapman theory. The availability of these parameters allowed a rigorous evaluation of various models for the chemical contribution to Ca2+ binding. For mixed POPC-POPG bilayers, a simple Langmuir adsorption model yielded the best fit to the experimental data, and the binding constants were 19.5 and 18.8 M-1 for POPG contents of 20 and 50 mol %, respectively. Sodium binding was comparatively weak with a binding constant of 0.6-0.85 M-1.(ABSTRACT TRUNCATED AT 400 WORDS)     

Kinetic and thermodynamic parameters for oxygen binding to the allosteric states of Panulirus interruptus hemocyanin

The temperature dependence of the oxygen binding equilibria and kinetics of Panulirus interruptus hemocyanin has been analyzed within the context of the two-state allosteric model. Oxygenation of the T-state is characterized by a more negative value of DeltaH than that of the R-state; therefore, cooperative effects in oxygen binding to P. interruptus hemocyanin are thermodynamically governed by favorable entropy changes. The allosteric transition in the unliganded derivative shows an enthalpy-entropy compensation effect. The activation enthalpies for oxygenation and deoxygenation of the T-state are larger than those for the R-state, while the activation entropies are favorable for the T-state and unfavorable for the R-state. Thus, the activation free energies for oxygen binding to the T- and R-states are similar, while for the deoxygenation reaction DeltaG++ is smaller for the T-state. The analysis reported confirms the applicability of the Monod-Wyman-Changeux two-state allosteric model to P. interruptus hemocyanin and yields a complete thermodynamic characterization of oxygen binding under both equilibrium and dynamic regimes.     

Sodium binding sites of gramicidin A: sodium-23 nuclear magnetic resonance study.

In ethanol-water mixtures (90:10), the gramicidin dimer binds Na+ cations at well-defined sites, with a binding constant K = 4 M-1. Partial desolvation of Na+ occurs upon binding, as judged from the magnitude of the quadrupolar coupling constant (1.7 MHz) for bound sodium. The binding sites are identified with the outer sites flanking the channel entrances. The rate constants for binding and release are k+ less than or equal to 2.2 X 10(9) M-1 s-1 and k- less than or equal to 5.5 X 10(8) s-1, respectively.     

Specific aggregations of alanine tetrapeptide derivatives as studied by nuclear magnetic resonance.

By use of high resolution nuclear magnetic resonance and infrared spectroscopy, we have found evidence for specific folded forms for the methoxyethoxyethoxyacetyl-blocked alanine tetramer ethyl ester. It appears that this tetrapeptide derivative exists in a folded form which is in rapid equilibrium with an extended structure (i.e., below 1% w/v). At high concentrations (i.e., above 1% w/v in chloroform) the folded form is stabilized by an association of the alanine tetrapeptide derivative into a side-by-side dimer which contains specific hydrogen bonds between the amine terminal regions of the two folded structures.     

Conformation of cobrotoxin in aqueous solution as studied by nuclear magnetic resonance.

The 270-MHz proton NMR spectra of cobrotoxin from Naja naja atra were observed in 2H2O solution. The pKa value (5.93) of His-32 is slightly lower than the pKa value (6.65) of the reference model of N-acetylhistidine methylamide, because of the electrostatic interaction with Arg-33 and Asp-31. The pKa value (5.3--5.4) of His-4 is appreciably low, because of the interaction with the positively charged guanidino group possibly of Arg-59. The hydrogen-deuterium exchange rates in 2H2O solution were measured of cobrotoxin and imidazole-bearing models. The second-order rate constants of N-acetylhistidine methylamide, N-acetylhistidine and imidazole acetic acid satisfy the Br?nsted relation. With reference to this Br?nsted relation, the imidazole ring of His-32 is confirmed to be exposed. The imidazole ring of His-4 is also exposed and the exchange rate is excessively promoted by the presence possibly of Arg-59 in the proximity. All the methyl proton resonances are assigned to amino-acid types, by conventional double-resonance method and more effectively by the spin-echo double-resonance method. Eight methyl proton resonances are identified as due to the gamma and/or delta-methyl groups of Val-46, Leu-1, Ile-50 and Ile-52 residues. The proximity of aromatic ring protons and methyl protons is elucidated by the analyses of nulcear Overhauser effect enhancements. The aromatic proton resonances of Trp-29 are affected by the ionizable groups of Asp-31, His-32 and Tyr-35. The methyl groups of Ile-50 are in the proximity to the aromatic ring of Trp-29 and the methyl groups of Ile-52 are in the proximity to Tyr-25. The highest-field methyl proton resonance is due to a threonine residue in the proximity to His-4. The appreciable temperature-dependent chemical shift of this methyl proton resonance suggests a temperature-dependent local conformational equilibrium around the His-4 residue of the first loop of the cobrotoxin molecule.     

Molecular conformation and function of erabutoxins as studied by nuclear magnetic resonance

The 270-MHz proton NMR spectra of erabutoxins a, b and c from Laticauda semifasciata in 2H2O solution were observed together with [15-N6-acetyllysine]erabutoxin b, [27-N6-acetyllysine]-erabutoxin b and [47-N6-acetyllysine]erabutoxin b. The lysine epsilon-methylene proton resonances of erabutoxin b are assigned to individual residues. The epsilon-methylene proton resonance of Lys-27 is significantly broad, indicating that the mobility of this residue is restricted. Upon acetylation of Lys-27 of erabutoxin b, the pKa values of three other lysine residues are lowered by about 0.2, indicating long-range interactions among lysine residues. All the methyl proton resonances are assigned to amino acid types, primarily by the spin-echo double-resonance method. The pH dependences of proton chemical shifts were analyzed by the nonlinear least-square method, for obtaining pKa values and protonation shifts. The interproton nuclear Overhauser effect enhancements were measured for elucidating the spatial proximity of methyl-bearing residues and aromatic residues. On the basis of these NMR data and with the crystal structures by Low et al. and by Petsko et al., the methyl proton resonances of all the valine, leucine, and isoleucine residues and Thr-45 have been identified. The microenvironments of Tyr-25, His-26, Trp-29, four lysines and eight methyl-bearing residues have been elucidated. The addition of the paramagnetic hexacyanochromate ion causes broadening of the proton resonances of Thr-45, Lys-47, Ile-50, Trp-29 and Ile-36 residues located on one end of the molecule of erabutoxin b. The positively charged invariant residues of Lys-47 and Arg-33 at this part of the molecule are probably involved in the binding to the receptor protein.     

Lecithin translational diffusion studied by pulsed nuclear magnetic resonance.

The translational diffusion coefficient of egg yolk and dilauroyl lecithin in optically isotropic phases containing sodium cholate has been measured using the pulsed NMR magnetic field gradient method. After a correction for geometrical factors the measured diffusion coefficient is found to agree well with previous determinations in phospholipid systems. The experimental data imply that the cubic mesophase of the lecithin-sodium cholate-water system contains continuous lipid aggregates. A possible model of the arrangement of the different amphiphile molecules in the cubic phase is discussed.     

Ion binding to cytochrome c studied by nuclear magnetic quadrupole relaxation.

The enhancement of the 35Cl- transverse relaxation rate on binding of chloride ions to oxidized and reduced cytochrome c has been studied under conditions of variable sodium chloride concentration, temperature, pH, sodium phosphate, iron hexacyanide, and sodium cyanide concentration. The results revealed the presence of a strong binding site(s) for chloride in both oxidized and reduced cyt c, with a higher affinity in ferrocytochrome c. Competition experiments suggest that these sites also bind iron hexacyanide and phosphate. Cyanide binding to the iron in ferricytochrome c at alkaline and neutral pH was shown to decrease the binding of chloride. The pH dependence of the 35Cl- relaxation rate has been fitted by using literature pK values for ionizable groups. No indications of Na+ binding to oxidized and reduced cytochrome c have been observed by using 23Na+ NMR. Our results suggest that chloride is bound near the exposed heme edge and that the surface structure or dynamics in this region are different in the two oxidation states.     

Binding modes of inhibitors to ribonuclease T1 as studied by nuclear magnetic resonance

The binding modes of inhibitors to ribonuclease T1 (RNase T1) were studied by the analyses of 270-MHz proton NMR spectra. The chemical shift changes upon binding of phosphate, guanosine, 2'-GMP, 3'-GMP, 5'-GMP, and guanosine 3',5'-bis(phosphate) were observed as high field shifted methyl proton resonances of RNase T1. One methyl resonance was shifted upon binding of phosphate and guanosine nucleotides but not upon binding of guanosine. Four other methyl resonances were shifted upon binding of guanosine and guanosine nucleotides but not upon binding of phosphate. From the analyses of nuclear Overhauser effects for the pair of H8 and H1' protons, together with the vicinal coupling constants for the pair of H1' and H2' protons, the conformation of the guanosine moiety as bound to RNase T1 is found to be C3'-endo-syn for 2'-GMP and 3'-GMP and C3'-endo-anti for 5'-GMP and guanosine 3',5'-bis(phosphate). These observations suggest that RNase T1 probably has specific binding sites for the guanine base and 3'-phosphate group (P1 site) but not for the 5'-phosphate group (PO site) or the ribose ring. The weak binding of guanosine 3',5'-bis(phosphate) and 5'-GMP to RNase T1 is achieved by taking the anti form about the glycosyl bond. The productive binding to RNase T1 probably requires the syn form of the guanosine moiety of RNA substrates.     

Molecular conformation of alpha-bungarotoxin as studied by nuclear magnetic resonance and circular dichroism

We have examined the circular dichroism and nuclear magnetic resonance spectra of a long neurotoxin, alpha-bungarotoxin, over a wide range of pH values and temperatures, and under high salt conditions. The observations are interpreted partly in terms of the known crystal structure of this polypeptide. We support earlier findings of a greater degree of beta-sheet structure in solution than has been reported by X-ray crystallography and, importantly, the invariant residue associated with neurotoxicity, Trp29, is shown to be in a similar environment to that found in alpha-cobratoxin and LS III from Laticauda semifasciata. The implications of this observation for structure/function relationships are outlined.     

Pulsed nuclear magnetic resonance studies on 23 Na, 7 Li and 35 Cl binding to human oxy- and carbon monoxyhaemoglobin

Pulsed nuclear magnetic resonance studies of the longitudinal (T₁) and transverse (T₂) quadrupolar relaxation times of ⁷Li, ²³Na, ³⁵Cl ions in the absence and presence of human oxy- and carbon monoxyhaemoglobin have been used to investigate the interaction of the ions and the macromolecule.The relaxation data show that Cl^? interacts strongly with the haemoglobin but provide no evidence for binding of Na⁺ up to concentrations of 0.5 m. In the case of Li⁺, evidence for interaction is obtained at concentrations of about 0.1 m.The dependence of relaxation rate on frequency was followed over a limited frequency range in an attempt to separate the effects of correlation times and exchange rates of the bonded ions on the relaxation. In the case of Cl^?, an upper limit for the mean lifetime divided by the number of sites can be set at about 1 × 10^?6 second, and a lower limit at about 1 × 10^?8 second.     

Sodium binding in Halobacterium halobium measured by the nuclear magnetic resonance technique

Relaxation time measurements T₁ and T₂ of sodium in Halobacterium halobium pellets were carried out at two frequencies. From those measurements, combined with intensity measurements of the sodium in the system, estimation of the properties of the sodium ions in the system was carried out. It is suggested that three types of sodium ions are present in the bacterial pellet. (A) The extracellular sodium with properties of free solution and (B) sodium which is in the pericellular volume between the cell wall and the cell membrane. There is an exchange between type A and type B sodium. The type B sodium has (e²qQ)/h = 3.7 · 10⁷ rad/s, τ_cB = 5.2 · 10⁻⁶ s and τ_B = 1 · 10⁻³ s. The sodium of type C is bound inside the cell and undetected. It's concentration inside the cell is assumed to be 1.9 M.