Water in agarose gels studied by nuclear magnetic resonance relaxation in the rotating frame.

The dependence of the spin-lattice relaxation time in the rotating frame (T1rho) on radio frequency (RF) field strength and temperature has been studied for agarose gels in order to investigate molecular motion. The results indicate the presence of slow motions with a correlation time of ca. 5-10(-6) s at room temperature. This interaction is responsible for the short spin-spin relaxation times (T2) for water protons in agarose gels and is ascribed to firmly bound water. The fraction of bound water is estimated to about 0.003 for a 7.3% agarose gel. The motion of the more mobile protons in agarose-water systems can not be characterized by single correlation time. This fraction is presumably composed of water in different motional states and some of the agarose hydroxyl protons. Higher mobilities are the most common.     

Water and Ions in Muscles and Model Systems

The nuclear magnetic reasonance (NMR) relaxation times of protons in toad muscle water have been measured at three frequencies: 2.3, 8.9, and 30 MHz. The results are analyzed in terms of a distribution of correlation times, and it is found that only a few percent of the observed protons have mobilities more than two orders of magnitude smaller than normal. Sodium and chloride ion chemical potentials in some hydrated materials with similar proton NMR characteristics to toad muscle have been found to be heightened, but not sufficiently to account for the distribution of sodium ions in muscle.     

NMR-relaxation in hydrated collagen from the spotted dogfish]

Collagen samples from dog-fish egg case at different water content were studied by the 1H NMR relaxation method. The dependences of the proton spin-lattice and spin-spin relaxation rates on the concentration of water in hydrated native collagen were measured. The fractions of water protons of different mobility and their corresponding spin-spin and spin-lattice relaxation rates were determined in a multi-phase model of water protons in natural biopolymer-water systems. The correlation times were calculated as the characteristics of molecular motion in hydrated collagens with different content of absorbed water. The results obtained were compared with literature data of pulse NMR studies of molecular mobility in other collagen fibers.     

1H-NMR relaxation studies of native and thermally denatured lysozyme solutions: an isotope dilution experiment

1H-NMR relaxation times are reported for native and thermally denatured lysozyme aqueous solutions measured as the function of the proton mole fraction in the sample. A two-exponential character of proton longitudinal relaxation function was observed for native lysozyme solutions: the fast component was attributed to the non-exchangeable protein protons, the slow one to water protons. Purely exponential decay of longitudinal magnetization was observed for the thermally denatured samples. This has been explained in terms of a fast spin exchange model. The contributions of the protein protons to the water proton relaxation rate in native and thermally denatured samples were determined, too.     

Nmr study of collagen-water interactions

A proton magnetic resonance study of different cross-linked collagens was performed as a function of water content and temperature. Collagens from three connective tissues (calf, steer, and cow) were chosen according to the different number of nonreducible multivalent cross-links, which increases during the life of animal. Samples were hydrated under five well-defined water activities (A_w) ranging from 0.44 to 0.85. The transverse and cross-relaxation times of water protons were studied as a function of temperature from ?20 up to 100°C. From the temperature dependence of relaxation rates, the dynamics of water molecules can be described according to different processes: exchange of protons at the higher temperatures and dipole-dipole interactions that prevail at the lower temperatures. The exchange processes are analyzed as a function of the residence lifetime of water molecules at the protein interface and of the transfer of spin energy from water protons to macromolecule protons. The proton dipole-dipole interactions are related to the relaxation parameters of protein and water protons. All the relaxation parameters showed specific behavior for the 0.44 water activity for every tissue. The collagen tissue from calf also showed distinct behavior in comparison with other tissues. © 1994 John Wiley & Sons, Inc.     

1H NMR studies: dynamics of water in gelatin

 Proton magnetic resonance was used to characterize the dynamics of water in gelatin. Both sol and gel states were investigated. Transverse relaxation rates (R ₂) were dependent on the proton frequency measurement. (R ₂) measured with the Carr-Purcell-Meiboom-Gill pulse sequence was dependent on pulse spacing. These observations were interpreted in terms of chemical exchanges between water protons and those of the macromolecules in the sol state, whereas in the gel state the contribution of diffusion through microheterogeneities in the sample seems to provide an additional transverse relaxation mechanism. Received: 10 May 1999 / Revised version: 13 December 1999 / Accepted: 25 January 2000     

Network analysis of a proposed exit pathway for protons to the P-side of cytochrome c oxidase

Cytochrome c Oxidase (CcO) reduces O₂, the terminal electron acceptor, to water in the aerobic, respiratory electron transport chain. The energy released by O₂ reductions is stored by removing eight protons from the high pH, N-side, of the membrane with four used for chemistry in the active site and four pumped to the low pH, P-side. The proton transfers must occur along controllable proton pathways that prevent energy dissipating movement towards the N-side. The CcO N-side has well established D- and K-channels to deliver protons to the protein interior. The P-side has a buried core of hydrogen-bonded protonatable residues designated the Proton Loading Site cluster (PLS cluster) and many protonatable residues on the P-side surface, providing no obvious unique exit. Hydrogen bond pathways were identified in Molecular Dynamics (MD) trajectories of Rb. sphaeroides CcO prepared in the P_R state with the heme a₃ propionate and Glu286 in different protonation states. Grand Canonical Monte Carlo sampling of water locations, polar proton positions and residue protonation states in trajectory snapshots identify a limited number of water mediated, proton paths from PLS cluster to the surface via a (P-exit) cluster of residues. Key P-exit residues include His93, Ser168, Thr100 and Asn96. The hydrogen bonds between PLS cluster and P-exit clusters are mediated by a water wire in a cavity centered near Thr100, whose hydration can be interrupted by a hydrophobic pair, Leu255B (near Cu_A) and Ile99. Connections between the D channel and PLS via Glu286 are controlled by a second, variably hydrated cavity.

Self-association of oxyhaemoglobin. A nuclear magnetic relaxation study in H2O/D2O solutions

The proton and deuterium longitudinal relaxation rates were Studied at room temperature up to the highest protein concentrations in oxyhaemoglobin solutions of different H₂O/D₂O composition. The deuterium relaxation rates followed the experimentally well known single linear dependence on protein concentration, the slopes being little influenced by solvent (D₂O/H₂O) composition. The proton ralaxation rates show two different liner dependences on haemoglobin concentration. The entire concentration range is described by two straight lines with the threshold concentration about 11 mM (in haem), The ratio of the slopes is 1.6 (high-to-low Hb-conc.). Only in the higher concentration range two T₁'s were observed if the solvent contained more than half of D₂O. The slow relaxation phase of protons has T₁'s similar to those measured in solutions with less than half of D₂O. The relaxation of the other phase was ten times faster. The ratio of the proton populations in these two phases was equal to 2 (slow-to-fast) and independent of protein concentration. The fast relaxing protons are attributed to water molecules encaged within two or more haemoglobin molecules which associate for times long enough on the PMR time-scale.     

The State of Water in Muscle Tissue as Determined by Proton Nuclear Magnetic Resonance

The nuclear magnetic resonance (NMR) of water protons in live and glycerinated muscle, suspensions of glycerinated myofibrils, and solutions of several muscle proteins has been studied. T₁ and T₂, measured on partially hydrated proteins by pulsed spin-echo techniques, decreased as the ratio of water to protein decreased, showing that the water which is tightly bound by the protein has short relaxation times. In live muscle fibers the pulse techniques showed that, after either a 180 or a 90° pulse, the relaxation of the magnetization is described by a single exponential. This is direct evidence that a fast exchange of protons occurs among the phases of the intracellular water. The data can be fitted with a model in which the bulk of the muscle water is in a phase which has properties similar to those of a dilute salt solution, while less than 4-5% of the total water is bound to the protein surface and has short relaxation times. Measurements of T₁ and T₂ in protein solutions showed that no change in the proton relaxation times occurred when heavy meromyosin was bound to actin, when myofibrils were contracted with adenosine triphosphate (ATP), or when globular actin was polymerized.     

Pulsed NMR studies on water in striated muscle III. The effects of water content

Pulsed NMR is used to study the kinetics of dehydration of frog gastrocnemius muscle. In addition, measurements are reported of the variation of the spin-lattice (T₁) and transverse (T₂) nuclear magnetic relaxation times of the water protons as a function of water content. The proton transverse relaxation and freezing properties of the water in muscles which had been dehydrated and then rehydrated are also investigated. Correlation of the double-exponential dehydration kinetics with the transverse relaxation at various water contents provides strong evidence for the evidence of a fraction of muscle water (10–20%) which is sufficiently strongly held to the solid substance of the muscle to make it relatively slowly removed under conditions of zero relative humidity but which is still dynamically very mobile on average. This is supported by the dependence of T₁ on water content. The relaxation times are interpreted qualitatively in terms of a number of possible effects which are at present not distinguishable. The properties of the dehydrated-rehydrated muscles indicated changes in the muscle proteins which affect the transverse relaxation of the water protons and the freezing properties of the muscle water.     

Nuclear magnetic resonance relaxation in cross-linked lysozyme crystals: an isotope dilution experiment.

Nuclear magnetic resonance (nmr) relaxation times are measured for water protons in cross-linked lysozyme crystals below the freezing event as a function of the mole fraction of protons in the water phase. Proton longitudinal nmr relaxation in these samples is nonexponential and the slow longitudinal relaxation component becomes slower linearly with decreasing proton mole fraction in the water. The data are analyzed using a cross relaxation model that eliminates the necessity of postulating long residence times for water molecules in the domain of the protein. The observed isotope dilution behavior is consistent with the cross relaxation model. The deuterium nmr relaxation is also reported for deuterium oxide in the cross-linked protein crystal sample below the freezing event and the relaxation is shown to be accurately exponential.     

Water Mobility and Distribution in Green Coffee Probed by Time-Domain Nuclear Magnetic Resonance

Water distribution in green coffee was studied by means of pulsed nuclear magnetic resonance (NMR). Hydration experiments for relaxometry measurements were performed by adding either H₂O or D₂O to dried green coffee beans up to 35% (dry basis) or, alternatively, by moisture absorption in a controlled humidity environment. The CPMG experimental relaxation decay curves were acquired using a benchtop time-domain NMR analyzer at each hydration level and as a function of time. All NMR data were fitted according to the Laplace inversion approach to obtain the proton mobility distributions of water in the hydrated beans. By comparing the T ₂ relaxograms of the hydrated beans with the ones observed in the untreated raw beans, it was found that up to ??10% water exhibits a rather restricted proton mobility. Hydration experiments carried out with D₂O highlighted the contribution of the chemical exchange between the water protons and those of the solid matrix to the overall NMR signal. A possible interpretation of the data in terms of the antiplasticizer and plasticizer effect of water is offered.     

Diffusive properties of water in Artemia cysts as determined from quasi-elastic neutron scattering spectra.

Results have been obtained on the quasi-elastic spectra of neutrons scattered from pure water, a 20% agarose gel (hydration four grams H2O per gram of dry solid) and cysts of the brine shrimp Artemia for hydrations between 0.10 and 1.2 grams H2O per gram of dry solids. The spectra were interpreted using a two-component model that included contributions from the covalently bonded protons and the hydration water, and a mobile water fraction. The mobile fraction was described by a jump-diffusion correlation function for the translation motion and a simple diffusive orientational correlation function. The results for the line widths gamma (Q2) for pure water were in good agreement with previous measurements. The agarose results were consistent with NMR measurements that show a slightly reduced translational diffusion for the mobile water fraction. The Artemia results show that the translational diffusion coefficient of the mobile water fraction was greatly reduced from that of pure water. The line width was determined mainly by the rotational motion, which was also substantially reduced from the pure water value as determined from dielectric relaxation studies. The translational and rotational diffusion parameters were consistent with the NMR measurements of diffusion and relaxation. Values for the hydration fraction and the mean square thermal displacement [u2] as determined from the Q-dependence of the line areas were also obtained.     

1H-nmr study of water dynamics in hydrated collagen: transverse relaxation-time and diffusion analysis

Water proton transverse relaxation times (T2) and self-diffusion coefficients (D) were measured in randomly oriented hydrated collagen fibers. Three T2 relaxation times were discerned indicating the presence of at least three water fractions in the collagen sample. The D values associated with each water fraction were determined. The diffusion time dependence of D suggests water motion is restricted by macromolecular structure. The experimental results are discussed with reference to the structural properties of hydrated collagen fibers.     

Effect of Partial H2O-D2O Replacement on the Anisotropy of Transverse Proton Spin Relaxation in Bovine Articular Cartilage

Anisotropy of transverse proton spin relaxation in collagen-rich tissues like cartilage and tendon is a well-known phenomenon that manifests itself as the “magic-angle” effect in magnetic resonance images of these tissues. It is usually attributed to the non-zero averaging of intra-molecular dipolar interactions in water molecules bound to oriented collagen fibers. One way to manipulate the contributions of these interactions to spin relaxation is by partially replacing the water in the cartilage sample with deuterium oxide. It is known that dipolar interactions in deuterated solutions are weaker, resulting in a decrease in proton relaxation rates. In this work, we investigate the effects of deuteration on the longitudinal and the isotropic and anisotropic contributions to transverse relaxation of water protons in bovine articular cartilage. We demonstrate that the anisotropy of transverse proton spin relaxation in articular cartilage is independent of the degree of deuteration, bringing into question some of the assumptions currently held over the origins of relaxation anisotropy in oriented tissues.     

Identifying the proton loading site cluster in the ba3 cytochrome c oxidase that loads and traps protons

Cytochrome c Oxidase (CcO) is the terminal electron acceptor in aerobic respiratory chain, reducing O₂ to water. The released free energy is stored by pumping protons through the protein, maintaining the transmembrane electrochemical gradient. Protons are held transiently in a proton loading site (PLS) that binds and releases protons driven by the electron transfer reaction cycle. Multi-Conformation Continuum Electrostatics (MCCE) was applied to crystal structures and Molecular Dynamics snapshots of the B-type Thermus thermophilus CcO. Six residues are identified as the PLS, binding and releasing protons as the charges on heme b and the binuclear center are changed: the heme a₃ propionic acids, Asp287, Asp372, His376 and Glu126B. The unloaded state has one proton and the loaded state two protons on these six residues. Different input structures, modifying the PLS conformation, show different proton distributions and result in different proton pumping behaviors. One loaded and one unloaded protonation states have the loaded/unloaded states close in energy so the PLS binds and releases a proton through the reaction cycle. The alternative proton distributions have state energies too far apart to be shifted by the electron transfers so are locked in loaded or unloaded states. Here the protein can use active states to load and unload protons, but has nearby trapped states, which stabilize PLS protonation state, providing new ideas about the CcO proton pumping mechanism. The distance between the PLS residues Asp287 and His376 correlates with the energy difference between loaded and unloaded states.     

The state of water in muscle as studied by pulsed NMR

Spin-lattice relaxation times for the water protons in rat gastronemius muscle are reported over the temperature range +37 to −70°C at six resonance frequencies ranging from 4.5 to 60.0 MHz. From −8 to −70°C, the bulk of the muscle water is frozen. The unfrozen part is termed the hydrated layer and amounts to 7–12% of the total water content. Its correlation time takes teh form of a log-Gaussaian distribution function. From +37 to −8°C, the spin-lattice relaxation time is explained by the exchange of water between the hydration layer and the rest of the water, which behaves like ordinary liquid water. The fact that the observed T₂ values are smaller than the calculated values is attributed to the inner field inhomogeneity of the heterogenous system and/or the modification of T₂ due to non-zero dipolar interaction.In the presence of perdeuterated dimethylsulfoxide, the freezing point of water decreases and the amount of non-freezable water increases. T₁ of water protons for muscle containing 10, 20, and 40% dimethylsulfoxide was calculated.     

Water and Backbone Dynamics in a Hydrated Protein

Rotational immobilization of proteins permits characterization of the internal peptide and water molecule dynamics by magnetic relaxation dispersion spectroscopy. Using different experimental approaches, we have extended measurements of the magnetic field dependence of the proton-spin-lattice-relaxation rate by one decade from 0.01 to 300 MHz for ¹H and showed that the underlying dynamics driving the protein ¹H spin-lattice relaxation is preserved over 4.5 decades in frequency. This extension is critical to understanding the role of ¹H₂O in the total proton-spin-relaxation process. The fact that the protein-proton-relaxation-dispersion profile is a power law in frequency with constant coefficient and exponent over nearly 5 decades indicates that the characteristics of the native protein structural fluctuations that cause proton nuclear spin-lattice relaxation are remarkably constant over this wide frequency and length-scale interval. Comparison of protein-proton-spin-lattice-relaxation rate constants in protein gels equilibrated with ²H₂O rather than ¹H₂O shows that water protons make an important contribution to the total spin-lattice relaxation in the middle of this frequency range for hydrated proteins because of water molecule dynamics in the time range of tens of ns. This water contribution is with the motion of relatively rare, long-lived, and perhaps buried water molecules constrained by the confinement. The presence of water molecule reorientational dynamics in the tens of ns range that are sufficient to affect the spin-lattice relaxation driven by ¹H dipole-dipole fluctuations should make the local dielectric properties in the protein frequency dependent in a regime relevant to catalytically important kinetic barriers to conformational rearrangements.     

Mixed micelle formation between gramicidin-S and a nonionic detergent: a nuclear magnetic resonance model study of peptide/detergent aggregation

The interaction of the cyclic decapeptide antibiotic gramicidin-S (GrS) with the nonionic detergent octaethylene glycol mono-n-dodecyl ether was studied by NMR spectroscopy. Detergent binding led to a slightly altered average conformation in the d-Phe side chains of the peptide. The changing diamagnetic shielding of nearby protons resulted in chemical shift variations, the largest effect being observed for the d-Phe C _α proton. The continuous upfield shift of this proton resonance, indicating rapid exchange of the peptide between detergent-associated and unassociated states, was employed for an evaluation of the detergent/peptide aggregation equilibria. The nonlinear binding plot thus obtained was attributed to essentially different aggregational states, depending on the detergent/peptide ratio. The almost linear dependence of the spin-lattice relaxation rate and of the hydrogen-deuterium exchange rate on the fraction of detergent-associated GrS could be reconciled with a simple model, comprising binding of detergent monomers and cooperative binding of micelles at low and high detergent/peptide molar ratios, respectively. Thus, GrS provides a useful model for a study of backbone dynamics and water penetration in detergent- and membrane-bound peptides and proteins. The results will also be discussed with reference to the interaction of GrS with biological membranes. Received: 22 June 1998 / Revised version: 5 October 1998 / Accepted: 9 October 1998     

Broadline proton magnetic resonance study of cellulose,pectin, and bean cell walls

We have used broadline proton magnetic resonance to study molecular motion in cellulose, a sodium pectate solution, a calcium pectate gel, and isolated bean cell walls. All samples were prepared in D₂O to minimize the contribution of water to the observed signals. For each sample, a free induction decay was obtained, and the second moment, spin-lattice relaxation, and dipolar relaxation were measured. Our results show that the large majority of protons in cellulose are immobile. Rigid and mobile domains were also observed in the pectate samples. We have shown that gelation induces large-scale changes in the free induction decay, the second moment, and the relaxation behavior of the pectate. As with the other samples, rigid and more mobile domains were found in bean cell walls. The fraction in the rigid domains is much larger than the fraction of cellulose in the sample, suggesting that the noncellulosic wall components are also organized into rigid and mobile domains.