Met-myoglobin association in dilute solution during pressure-induced denaturation: an analysis at pH 4.5 by high-pressure small-angle X-ray scattering.

In this paper, we report on the original global fit procedure of synchrotron small-angle X-ray scattering (SAXS) data applied to a model protein, met-myoglobin, in dilute solution during temperature- and pressure-induced denaturation processes at pH 4.5. Starting from the thermodynamic description of the protein unfolding pathway developed by Hawley (Hawley, S. A. Biochemistry 1971, 10, 2436), we have developed a new method for analyzing the set of SAXS curves using a global fitting procedure, which allows us to derive the form factor of all the met-myoglobin species present in the solution, their aggregation state, and the set of thermodynamic parameters, with their p and T dependence. This method also overcomes a reasonably poor quality of the experimental data, and it is found to be very powerful in analyzing SAXS data. SAXS experiments were performed at four different temperatures from hydrostatic pressures up to about 2000 bar. As a result, the presence of an intermediate, partially unfolded, dimeric state of met-myoglobin that forms during denaturation has been evidenced. The obtained parameters were then used to derive the met-myoglobin p, T phase diagram that fully agrees with the corresponding phase diagram obtained by spectroscopic measurements.

Contribution of the copper ions in the dinuclear active site to the stability of Carcinus aestuarii hemocyanin.

We have investigated the effect of copper binding on the structural properties of hemocyanin (Hc). To this aim, we have studied the holo- and apo-form of the protein, both in the hexameric and in the monomeric state (CaeSS2 subunit), with experimental approaches that report on the protein aggregation and conformational stability. The results of gel-filtration chromatography and small angle X-ray scattering (SAXS) provide evidence that the hydrodynamic and gyration radius (R(g)) of Hc in the hexameric form only slightly increase upon copper removal, whereas a remarkable enhancement in the R(g) value is observed for the CaeSS2 monomer. CD measurements in the far- and near-UV region indicate that removal of copper only marginally affects the conformation of the hexameric Hc. Instead, copper depletion in the CaeSS2 strongly alters the tertiary structure of the monomer (near-UV CD), even though it is almost inconsequential on the secondary structure content (far-UV CD). These findings are fully consistent with the results of limited proteolysis experiments showing that the hexameric Hc is similarly resistant to proteolysis by trypsin both in the holo- and apo-form. Conversely, the apo-form of CaeSS2 monomer is much more susceptible to proteolytic attack by trypsin than the holo-form. Based on SAXS measurements, the concentration-dependent oligomerization process for apo-CaeSS2 has been analyzed on the basis of a thermodynamic model involving a concentration-dependent equilibrium between a monomer in a native-like and an hexameric aggregate of monomers.

Structural transformation induced by magnetic field and "colossal-like" magnetoresistance response above 313 K in MnAs.

MnAs exhibits a first-order phase transition from a ferromagnetic, high-spin metal hexagonal phase to a paramagnetic, lower-spin insulator orthorhombic phase at T(C)=313 K. Here, we report the results of neutron diffraction experiments showing that an external magnetic field, B, stabilizes the hexagonal phase above T(C). The phase transformation is reversible and constitutes the first demonstration of a bond-breaking transition induced by a magnetic field. The field-induced phase transition is accompanied by an enhanced magnetoresistance of about 17% at 310 K. The phenomenon appears to be similar to that of the colossal magnetoresistance response observed in the Mn [corrected] perovskite family.

Structural characterization of the pH-denatured states of ferricytochrome-c by synchrotron small angle X-ray scattering.

The ferricytochrome-c (cyt-c) shows a complex unfolding pathway characterized by a series of stable partially folded states. When titrated with HCl at low ionic strength, two transitions are detected. At pH 2, cyt-c assumes the U1 unfolded state, whereas the successive addition of Cl(-) ion from either HCl or NaCl induces the recompaction to a molten globule conformation (A1 and A2 states, respectively). A second unfolded state (U2) is also observed at pH 12. Recent data evidence different features for the local structure of the heme in the different states. To derive relationships between local and overall conformations, we analyzed the structural characteristics of the different states by synchrotron small angle X-ray scattering. The results show that in the acidic-unfolded U1 form the protein assumes a worm-like conformation, whereas in the alkaline-unfolded U2 state, the cyt-c is globular. Moreover, the molten globule states induced by adding HCl or NaCl to U1 appear structurally different: in the A1 state cyt-c is dimeric and less compact, whereas in the A2 form the protein reverts to a globular-like conformation. According to the local heme structure, a molecular model for the different forms is derived.

Ligand-induced conformational changes in tissue transglutaminase: Monte Carlo analysis of small-angle scattering data.

Small-angle neutron and x-ray scattering experiments have been performed on type 2 tissular transglutaminase to characterize the conformational changes that bring about Ca(2+) activation and guanosine triphosphate (GTP) inhibition. The native and a proteolyzed form of the enzyme, in the presence and in the absence of the two effectors, were considered. To describe the shape of transglutaminase in the different conformations, a Monte Carlo method for calculating small-angle neutron scattering profiles was developed by taking into account the computer-designed structure of the native transglutaminase, the results of the Guinier analysis, and the essential role played by the solvent-exposed peptide loop for the conformational changes of the protein after activation. Although the range of the neutron scattering data is rather limited, by using the Monte Carlo analysis, and because the structure of the native protein is available, the distribution of the protein conformations after ligand interaction was obtained. Calcium activation promotes a rotation of the C-terminal with respect to the N-terminal domain around the solvent-exposed peptide loop that connects the two regions. The psi angle between the longest axes of the two pairs of domains is found to be above 50 degrees, larger than the psi value of 35 degrees calculated for the native transglutaminase. On the other hand, the addition of GTP makes possible conformations characterized by psi angles lower than 34 degrees. These results are in good agreement with the proposed enzyme activity regulation: in the presence of GTP, the catalytic site is shielded by the more compact protein structure, while the conformational changes induced by Ca(2+) make the active site accessible to the substrate.

The structural basis for the regulation of tissue transglutaminase by calcium ions.

The role of calcium ions in the regulation of tissue transglutaminase is investigated by experimental approaches and computer modeling. A three-dimensional model of the transglutaminase is computed by homology building on crystallized human factor XIII and is used to interpret structural and functional results. The molecule is a prolate ellipsoid (6.2 x 4.2 x 11 nm) and comprises four domains, assembled pairwise into N-terminal and C-terminal regions. The active site is hidden in a cleft between these regions and is inaccessible to macromolecular substrates in the calcium-free form. Protein dynamics simulation indicates that these regions move apart upon addition of calcium ions, revealing the active site for catalysis. The protein dimensions are consistent with results obtained with small-angle neutron and X-ray scattering. The gyration radius of the protein (3 nm) increases in the presence of calcium ions (3.9 nm), but it is virtually unaffected in the presence of GTP, suggesting that only calcium ions can promote major structural changes in the native protein. Proteolysis of an exposed loop connecting the N-terminal and C-terminal regions is linearly correlated with enzyme inactivation and prevents the calcium-induced conformational changes.

Corresponding-states approach to small-angle scattering from polydisperse ionic colloidal fluids.

Approximate scattering functions for polydisperse ionic colloidal fluids are obtained by a corresponding-states approach. This assumes that all pair correlation functions g(alpha beta)(r) of a polydisperse fluid are conformal to those of an appropriate monodisperse binary fluid (reference system) and can be generated from them by scaling transformations. The correspondence law extends to ionic fluids a scaling approximation (SA) successfully proposed for nonionic colloids in a recent paper. For the primitive model of charged hard spheres in a continuum solvent, the partial structure factors of the monodisperse binary reference system are evaluated by solving the Orstein-Zernike (OZ) integral equations coupled with an approximate closure. The SA is first tested within the mean spherical approximation (MSA) closure, which allows analytical solutions. The results are found in good overall agreement with exact MSA predictions up to relevant polidispersity. The SA is shown to be an improvement over the "decoupling approximation" extended to the ionic case. The simplicity of the SA scheme allows its application also when the OZ equations can be solved only numerically. An example is then given by using the hypernetted chain closure. Shortcomings of the SA approach, its possible use in the analysis of experimental scattering data and other related points are also briefly addressed.

Structural organization of guanosine derivatives in dilute solutions: small angle neutron scattering analysis.

Guanosine derivatives, dissolved in water, can form cholesteric and hexagonal mesophases. The common structural unit is a chiral rod-shaped aggregate consisting of a stack of Hoogsten-bonded guanosine tetrameric disks. In order to elucidate the self-association process, we decided to investigate, by small-angle neutron scattering, the structural properties of d(pG), d(GpG), d(GpGpG), d(GpGpGpG) and d(GpGpGpG pGpG) derivatives in very dilute solutions. Under our experimental conditions only d(pG) seems not to form detectable particles. On the other hand, the results for the other derivatives indicate that cylindrical aggregates, having a 10 A cross-section gyration radius and a length of about 70 A, exist in the isotropic phase. According to the structure of the hexagonal and cholesteric phases, we fitted the experimental data by using a model of rod-shaped aggregates formed by stacking about 18 to 20 guanosine tetramers. Moreover, from the measurement of the concentration of scattering particles, we deduced that guanosine derivatives are only partially aggregated, depending on their ability to form mesophases.