Brain lateralization probed by water diffusion at the atomic to micrometric scale.

Combined neutron scattering and diffusion nuclear magnetic resonance experiments have been used to reveal significant interregional asymmetries (lateralization) in bovine brain hemispheres in terms of myelin arrangement and water dynamics at micron to atomic scales. Thicker myelin sheaths were found in the left hemisphere using neutron diffraction. 4.7 T dMRI and quasi-elastic neutron experiments highlighted significant differences in the properties of water dynamics in the two hemispheres. The results were interpreted in terms of hemisphere-dependent cellular composition (number of neurons, cell distribution, etc.) as well as specificity of neurological functions (such as preferential networking).

Anomalous water dynamics in brain: a combined diffusion magnetic resonance imaging and neutron scattering investigation.

Water diffusion is an optimal tool for investigating the architecture of brain tissue on which modern medical diagnostic imaging techniques rely. However, intrinsic tissue heterogeneity causes systematic deviations from pure free-water diffusion behaviour. To date, numerous theoretical and empirical approaches have been proposed to explain the non-Gaussian profile of this process. The aim of this work is to shed light on the physics piloting water diffusion in brain tissue at the micrometre-to-atomic scale. Combined diffusion magnetic resonance imaging and first pioneering neutron scattering experiments on bovine brain tissue have been performed in order to probe diffusion distances up to macromolecular separation. The coexistence of free-like and confined water populations in brain tissue extracted from a bovine right hemisphere has been revealed at the micrometre and atomic scale. The results are relevant for improving the modelling of the physics driving intra- and extracellular water diffusion in brain, with evident benefit for the diffusion magnetic resonance imaging technique, nowadays widely used to diagnose, at the micrometre scale, brain diseases such as ischemia and tumours.

Interfacial water structure controls protein conformation.

A phenomenological theory of salt-induced Hofmeister phenomena is presented, based on a relation between protein solubility in salt solutions and protein-water interfacial tension. As a generalization of previous treatments, it implies that both kosmotropic salting out and chaotropic salting in are manifested via salt-induced changes of the hydrophobic/hydrophilic properties of protein-water interfaces. The theory is applied to describe the salt-dependent free energy profiles of proteins as a function of their water-exposed surface area. On this basis, three classes of protein conformations have been distinguished, and their existence experimentally demonstrated using the examples of bacteriorhodopsin and myoglobin. The experimental results support the ability of the new formalism to account for the diverse manifestations of salt effects on protein conformation, dynamics, and stability, and to resolve the puzzle of chaotropes stabilizing certain proteins (and other anomalies). It is also shown that the relation between interfacial tension and protein structural stability is straightforwardly linked to protein conformational fluctuations, providing a keystone for the microscopic interpretation of Hofmeister effects. Implications of the results concerning the use of Hofmeister effects in the experimental study of protein function are discussed.

The interaction of sodium maleate with human haemoglobin.

We have studied the effect of sodium maleate on the reaction of haemoglobin with oxygen at various temperatures between 10 degrees C and 30 degrees C. At all the temperatures investigated, the presence of sodium maleate causes a significant increase of log p50. Analysis of the experimental data in terms of Wyman's linkage theory indicates that one oxygen-linked maleate molecule bound to the haemoglobin tetramer in the deoxy conformation is released when the tetramer is oxygenated. Further analysis within the framework of the Monod-Wyman-Changeux model, considering maleate as a classical allosteric inhibitor, enabled us to obtain the equilibrium constant for the binding of maleate to deoxyhaemoglobin at various temperatures and therefore the values of the standard binding entropy and enthalpy. These last values indicate that the binding of maleate to deoxyhaemoglobin is an exothermic enthalpy-driven process.

Effect of organic co-solvents on the dimer/tetramer equilibrium of human haemoglobin.

We have studied the effect of organic co-solvents (monohydric alcohols and formamide) on the dimer-tetramer equilibrium of human haemoglobin by measuring the dependence of oxygen affinity upon haemoglobin concentration over a 100-fold concentration range and analysing the data with a modified Monod-Wyman-Changeux model in which the equilibrium (tetramer) in equilibrium with (dimer) + (dimer) was taken into account. This procedure enabled us to obtain the dimer-tetramer equilibrium constant and to find its dependence upon co-solvent concentration. Then by following the procedure already reported for the tense----relaxed state transition of haemoglobin, we separated the co-solvent effects into bulk electrostatic and non-bulk electrostatic (hydrophobic) contributions. We believe that our results demonstrate that during haemoglobin dissociation, just as we have already shown for the tense to relaxed state transition, both charged groups and hydrophobic surfaces became exposed to the solvent.

Effects of organic co-solvents on the oxygen equilibrium of N-ethylmaleimide-treated human haemoglobin.

We have studied the effects of monohydric alcohols and formamide on the oxygen equilibrium of native and N-ethylmaleimide-treated human haemoglobin. Comparison of the results obtained for the two haemoglobins gives further and compelling evidence in favour of the model, proposed recently by our group, on the role played by the solvent in the conformational equilibria of haemoglobin; moreover the results provide direct functional evidence of the relevance of the electrostatic free energy of salt bridges to the T in equilibrium with R equilibrium of haemoglobin.

Oxygen affinity of bovine haemoglobin. Relevance of electrostatic and hydrophobic interactions.

We have studied the effects of organic cosolvents (monohydric alcohols and formamide) on the oxygen equilibrium of bovine haemoglobin and have compared them with the effects of the same cosolvents on the oxygen equilibrium of human haemoglobin. Our results indicate: (1) that in agreement with previous suggestions, the lower affinity of bovine haemoglobin for oxygen is not due to an increased number of salt bridges stabilizing the T structure; (2) that, following T----R transition, more hydrophobic surface is exposed to the solvent by bovine than by human haemoglobin. We suggest, therefore, that a relevant role in keeping the oxygen affinity of bovine haemoglobin lower than that of human haemoglobin is played by the higher free energy needed to expose this more hydrophobic surface to the solvent. We stress, however, that our analysis does not enable us to say which particular amino acid residues are concerned in these effects.

Interaction between external medium and haem pocket in myoglobin probed by low-temperature optical spectroscopy.

The visible absorption spectra of carbonmonoxymyoglobin in the temperature range 300 to 20 K are reported and compared with the analogous spectra of carbonomonoxyhaemoglobin. The temperature dependence of the zeroth, first and second moment of the observed bands is analysed to obtain information on the local dynamics in the proximity of the haem. Contrary to haemoglobin, the first moment of the observed bands in myoglobin is markedly affected by the solvent composition and its value saturates at temperatures at which the solvent undergoes the glass transition. These data indicate that solvent properties influence the haem pocket stereodynamics in myoglobin; moreover, the different behaviour between myoglobin and haemoglobin suggests that the process should involve the surfaces that are buried in the haemoglobin tetramer and exposed to the solvent in myoglobin, and/or the different protein compressibility.

Observing heme doming in myoglobin with femtosecond X-ray absorption spectroscopy.

We report time-resolved X-ray absorption measurements after photolysis of carbonmonoxy myoglobin performed at the LCLS X-ray free electron laser with nearly 100 fs (FWHM) time resolution. Data at the Fe K-edge reveal that the photoinduced structural changes at the heme occur in two steps, with a faster (∼70 fs) relaxation preceding a slower (∼400 fs) one. We tentatively attribute the first relaxation to a structural rearrangement induced by photolysis involving essentially only the heme chromophore and the second relaxation to a residual Fe motion out of the heme plane that is coupled to the displacement of myoglobin F-helix.

The effect of organic cosolvents on the oxygen affinity of fetal hemoglobin. Relevance of protein-solvent interactions to the functional properties.

We have studied the effects of organic cosolvents (monohydric alcohols and formamide) on the oxygen affinity of human fetal hemoglobin stripped of phosphates and have compared them with the effects of the same cosolvents on the oxygen affinity of human adult hemoglobin under the same experimental conditions. Our results confirm that, in fetal hemoglobin, the T in equilibrium R conformational equilibrium is more displaced toward the T conformation than in the adult form and indicate that increased electrostatic and hydrophobic protein-solvent interactions contribute to this effect. The data reported are discussed in terms of the known amino acid substitutions between the beta- and gamma-chains and an attempt is made to rationalize the results with a molecular mechanism based on the crystallographic structure of fetal deoxyhemoglobin.

Optical absorption spectra of azurin and stellacyanin in glycerol/water and ethylene glycol/water solutions in the temperature range 290-20 K.

We have measured the optical absorption spectra of azurin and stellacyanin in the wavelength range 1100-350 nm and in the temperature interval 290-20 K. Samples are protein aqueous solutions containing 65% (v/v) glycerol or ethylene glycol as cryoprotectants and remain homogeneous and transparent throughout the whole temperature range investigated. Spectra are deconvoluted into Gaussian components and the temperature dependence of the zeroth, first and second moments of the various bands is analyzed, within the harmonic Franck-Condon approximation, to obtain information on the stereodynamic properties of the active sites of these proteins. Sizable differences of the integrated intensities of all the bands with temperature are observed and are attributed to variations of the metal-ligand relative positions (i.e., deformations of the active site) that occur as the temperature is lowered. The mean effective frequency of the nuclear vibrations coupled to all the observed bands is about 150 cm(-1) for both proteins in both solvents used; this indicates that the electronic transitions from which the optical spectrum originates are substantially coupled with low-frequency vibrational modes, likely ligand-metal-ligand deformations. The relevance of the stereodynamic properties of azurin and stellacyanin, investigated in this work, to their functional behavior is also suggested.

Strong vibronic coupling in heme proteins.

We report the near infrared absorption spectra of cyanomethemoglobin and cyanometmyoglobin in two different solvents (deuterated solutions containing 65% v/v glycerol(OD)3 or 65% v/v ethylene glycol(OD)2). At 25 K the spectra show a clearly resolved fine structure that can be accounted for by considering a strong coupling of the porphyrin-to-iron charge transfer transitions with a single vibrational mode at 365 cm-1. The coupling constants depend on both the specific electronic transition and the protein surrounding the chromophore, indicating once more the specificity of heme globin interactions.

Optical absorption spectra of deoxy- and oxyhemoglobin in the temperature range 300-20 K. Relation with protein dynamics.

We have studied the optical absorption spectra of human deoxy- and oxyhemoglobin in the temperature range 300-20 K and in the wavelength range 350-1350 nm. By lowering the temperature, a narrowing and a shift of all bands were observed together with a sizeable increase of the integrated intensities of the charge-transfer bands of deoxyhemoglobin. At all temperatures the spectra are in full agreement with the band assignment previously suggested in the literature and no new relevant bands have been detected for both deoxy- and oxyhemoglobin. Analysis of the first and second moment of the bands, within the framework of the harmonic Franck-Condon approximation, gave information on the dynamic properties of the heme in the heme pocket.

Oxygen binding to partially oxidized hemoglobin. Analysis in terms of an allosteric model.

We report on oxygen binding to partially oxidized (aquomet) hemoglobin. The fractional saturation with oxygen is evaluated by deconvoluting the optical absorption spectra, in the 500-700 nm wavelength region, in terms of oxyhemoglobin, deoxyhemoglobin and methemoglobin spectral components. Experiments have been performed with auto-oxidized samples and with samples obtained by mixing ferrous hemoglobin with fully oxidized hemoglobin (mixed samples). An increase in oxygen affinity and a decrease in cooperativity are observed on increasing the amount of ferric hemoglobin in the sample. A high cooperativity (nH approximately 2) is maintained even in the presence of 50-60% ferric hemes. Moreover, for equal amounts of methemoglobin the oxygen affinity is lower and the cooperativity higher for mixed samples than for those auto-oxidized. The results are analyzed within the framework of a modified Monod-Wyman-Changeux allosteric model taking into account the effects brought about by the presence of oxidized hemes and of alpha betta dimers. The distribution of ferric subunits within the tetramers in fully deoxygenated and fully oxygenated samples, as derived from the model, provides details on the cooperative behavior of partially oxidized hemoglobin.

Local dynamic properties of the heme pocket in native and solvent-induced molten-globule-like states of cytochrome c.

We report the Soret absorption band, down to cryogenic temperature, of native and molten-globule-like state of horse heart cytochrome c. The band profile is analyzed in terms of vibronic coupling of the heme normal modes to the electronic transition in the framework of the Franck-Condon approximation. From the temperature dependence of the Gaussian broadening and of the peak position, we obtain information on the 'bath' of low frequency harmonic motions of the heme group within the heme pocket. The reported data indicate that, compared to the native state, the less rigid tertiary structure of the molten globule is reflected in a higher flexibility of the heme pocket and in greater conformational disorder, allowing the transduction of large-amplitude motion of the protein to the dynamics of the heme pocket.

Heme geometry in the 10 K photoproduct from sperm whale carbonmonoxymyoglobin.

We have measured the Soret band of the photoproduct obtained by complete photolysis of sperm whale carbonmonoxymyoglobin at 10 K. The experimental spectrum has been modeled with an analytical expression that takes into account the homogeneous bandwidth, the coupling of the electronic transition with both high and low frequency vibrational modes, and the effects of static conformational heterogeneity. The comparison with deoxymyoglobin at low temperature reveals three main differences. In the photoproduct, the Soret band is shifted to red. The band is less asymmetric, and an enhanced coupling to the heme vibrational mode at 674 cm-1 is observed. These differences reflect incomplete relaxation of the active site after ligand dissociation. The smaller band asymmetry of the photoproduct can be explained by a smaller displacement of the iron atom from the mean porphyrin plane, in quantitative agreement with the X-ray structure analysis. The enhanced vibrational coupling is attributed to a subtle heme distortion from the planar geometry that is barely detectable in the X-ray structure.

Structure and dynamics of water confined in silica hydrogels: X-ray scattering and dielectric spectroscopy studies.

We have used a sol-gel technique to obtain optically transparent hydrogels in which water is confined within a 3D silica matrix. In this work we report X-ray scattering and dielectric spectroscopy measurements on samples having different aging times and compare them with previously obtained results with near-infrared (NIR) absorption spectroscopy. X-ray scattering at room temperature enables to characterize the structure and size of the matrix pores and the non-uniform distribution of water inside the hydrogel. Broad band dielectric spectroscopy in the temperature range 130-280 K enables to study water dynamics. In aged hydrogels two relaxations are clearly evident and show characteristic temperature dependence. The faster relaxation has an Arrhenius behavior in the whole temperature range investigated with an activation enthalpy of approximately 50 kJ/mol; it is attributed to water molecules strongly interacting with the silica matrix. The slower relaxation has a markedly non-Arrhenius behavior which can be fitted with a Vogel-Fulcher-Tamman (VFT) relation with critical temperature of approximately 100 K and activation enthalpies of 35 and 95 kJ/mol at 300 and 170 K respectively; it is attributed to water molecules within the pores that do not interact strongly with the matrix and behave collectively. The VFT temperature dependence of the dielectric relaxation time suggests that this water does not crystallize, in agreement with previous results from NIR spectroscopy.

The boson peak of amyloid fibrils: probing the softness of protein aggregates by inelastic neutron scattering.

Proteins and polypeptides are characterized by low-frequency vibrations in the terahertz regime responsible for the so-called "boson peak". The shape and position of this peak are related to the mechanical properties of peptide chains. Amyloid fibrils are ordered macromolecular assemblies, spontaneously formed in nature, characterized by unique biological and nanomechanical properties. In this work, we investigate the effects of the amyloid state and its polymorphism on the boson peak. We used inelastic neutron scattering to probe low-frequency vibrations of the glucagon polypeptide in the native state and in two different amyloid morphologies in both dry and hydrated sample states. The data show that amyloid fibril formation and hydration state affect the softness of the polypeptide not only by changing the distribution of vibrational modes but also, and most significantly, the dissipative mechanisms of collective low-frequency vibrations provided by water-protein and protein-protein interactions. We show how the morphology of the fibril is able to tune these effects. Atomic fluctuations were also measured by elastic neutron scattering. The data confirm that any effect of protein aggregation on fluctuation amplitudes is essentially due to changes in surface exposure to hydration water. The results demonstrate the importance of protein-protein and protein-water interactions in the dynamics and mechanics of amyloid fibrils.

Unveiling the timescale of the R-T transition in human hemoglobin.

Time-resolved wide-angle X-ray scattering, a recently developed technique allowing to probe global structural changes of proteins in solution, was used to investigate the kinetics of R-T quaternary transition in human hemoglobin and to systematically compare it to that obtained with time-resolved optical spectroscopy under nearly identical experimental conditions. Our data reveal that the main structural rearrangement associated with the R-T transition takes place approximately 2 mus after the photolysis of hemoglobin at room temperature and neutral pH. This finding suggests that the 20-mus step observed with time-resolved optical spectroscopy corresponds to a small and localized structural change.