Dynamics of wild-type HiPIPs: a Cys77Ser mutant and a partially unfolded HiPIP

The temperature dependence of the mean square displacement of the (57)Fe nuclei due to motion faster than 100 ns are measured by temperature-dependent M?ssbauer spectroscopy for oxidized and reduced HiPIPs from Ectothiorhodospira halophila, Chromatium vinosum WT and a Cys77Ser mutant. The behaviour is interpretable in the frame of the general model of protein dynamics distinguishing two temperature intervals. The character of harmonic and quasi-diffusional modes in HiPIPs is discussed. Dynamic information obtained from M?ssbauer spectroscopy and Fe K-edge EXAFS are compared. Structure dynamics of the iron-sulfur cluster in the partially unfolded reduced HiPIP from C. vinosum was investigated by M?ssbauer spectroscopy and EXAFS, indicating an intact metal centre and a protein backbone with a largely collapsed secondary structure. The role of the cofactor during protein folding is discussed. Differences in the dynamics between the native protein and the molten globule are found at physiological temperatures only. The structure and dynamic behaviour of the [Fe(4)S(4)]Cys(3)Ser cluster in the Cys77Ser mutant of the HiPIP from C. vinosum are analysed. The temperature dependence of electron relaxation in oxidized HiPIPs is investigated by M?ssbauer spectroscopy and analysed theoretically, considering spin-spin and spin-lattice relaxation. The latter consists of contributions from direct phonon bottleneck and Orbach mechanisms. The data agree with former pulsed EPR results. Orbach relaxation is interpreted as due to transitions between electronic isomers of oxidized HiPIPs. With this interpretation, the energetic difference between both isomers equals the energy gap estimated from the temperature dependence of the Orbach relaxation.     

Mechanism of Cu(A) assembly

Copper is essential for proper functioning of cytochrome c oxidases, and therefore for cellular respiration in eukaryotes and many bacteria. Here we show that a new periplasmic protein (PCu(A)C) selectively inserts Cu(I) ions into subunit II of Thermus thermophilus ba(3) oxidase to generate a native Cu(A) site. The purported metallochaperone Sco1 is unable to deliver copper ions; instead, it works as a thiol-disulfide reductase to maintain the correct oxidation state of the Cu(A) cysteine ligands.     

A 15N NMR mobility study on the dicalcium P43M calbindin D9k and its mono-La3+-substituted form

Calbindin D(9k) is a dicalcium binding protein consisting of two helix-loop-helix EF-hand motifs joined together by a flexible linker region where one metal ion can bind to each of the two loops. A proline residue at position 43 in the linker region displays cis-trans isomerism in the wild-type (WT) protein. Such isomerism appeared to be removed by substituting the proline with a glycine or a methionine in the P43G or P43M mutant. We have extended the available mobility studies on the P43M mutant through amide (15)N R(1), R(2), and R(1)(rho)() measurements. This has revealed unexpected conformational equilibria on the millisecond time scale involving residues 38, 42-44, and 46 in the linker region and residues 18 and 19 in calcium binding site I with similar energy barriers. These data are discussed in comparison with those available for the WT, as well as the apo-, mono-, and disubstituted P43G mutant. Quantification of water-amide proton exchange rates using saturation transfer and qualitative application of (15)N-(CLEANEX-PM)-FHSQC shows the values are in agreement with high mobility for the above-mentioned residues. Cross correlation between N-H dipole-dipole relaxation and (15)N CSA relaxation indicates that some of these mobility differences may extend to the sub-nanosecond time scale. Similar data were also obtained for the derivative where the calcium ion in the C-terminal loop was replaced with lanthanum. The results presented here show that, contrary to expectations, there are significant differences in dynamics between the dicalcium state of P43G and P43M and that these differences are not confined to the flexible linker region containing the point mutation. They also demonstrate that substitution of a lanthanide ion for calcium, which is a common procedure, does not significantly alter the mobility of the native protein.     

Cross correlation rates between Curie spin and dipole-dipole relaxation in paramagnetic proteins: the case of cerium substituted calbindin D9k

Cross correlation rates between Curie spin relaxation and H-N dipole-dipole coupling (^CS,DD _HM,HN) have been determined for a calcium binding protein, Calbindin D_9k, in which one of the two calcium ions is substituted with cerium(III). ^CS,DD _HM,HNvalues depend on both the metal-to-proton distances and the M-H-N angles and can be used as an additional constraint in order to refine the solution structure of paramagnetic metalloproteins. For this purpose, we have implemented a new module (CCR-DYANA) in a version of the program DYANA (PARAMAGNETIC-DYANA), which can be used together with other paramagnetism-based constraints such as pseudocontact shifts, residual dipolar couplings and hyperfine based Karplus relationships. This integrated structure calculation protocol has the advantage that different paramagnetic-based constraints are treated by the same algorithm in a way that the efficiency of each class of constraints can be analyzed and compared.     

Structure and dynamics of copper-free SOD: The protein before binding copper

The solution structure of the copper-free state of a monomeric form of superoxide dismutase (153 amino acids) was determined through (13)C and (15)N labeling. The protein contained two mutations at the native subunit-subunit interface (F50E and G51E) to obtain a soluble monomeric species and a mutation in the active site channel (E133Q). About 93% of carbon atoms, 95% of nitrogen atoms, and 96% of the protons were assigned. A total of 2467 meaningful NOEs and 170 dihedral angles provided a family of 35 conformers with RMSD values of 0.76 +/- 0.09 A for the backbone and 1.22 +/- 0.13 A for all heavy atoms. The secondary structure elements, connected by loops, produce the typical superoxide dismutase Greek key fold, formed by an eight-stranded beta-barrel. The comparison with the copper-bound monomeric and dimeric structures shows that the metal ligands have a conformation very close to that of the copper-bound forms. This feature indicates that the copper-binding site is preorganized and well ordered also in the absence of the copper ion. The active-site channel shows a sizable increase in width, achieving a suitable conformation to receive the copper ion. The histidines ring NH resonances that bind the copper ion and the region around the active-site channel experience, as found from (15)N relaxation studies, conformational exchange processes. The increased width of the channel and the higher mobility of the histidine rings of the copper site in the copper-free form with respect to the holoprotein is discussed in terms of the process of copper insertion.     

Paramagnetism-Based Restraints for Xplor-NIH

Modules that use paramagnetism-based NMR restraints have been developed and integrated in the well known program for solution structure determination Xplor-NIH; the complete set of such modules is called PARArestraints for Xplor-NIH. Paramagnetism-based restraints are paramagnetic relaxation enhancements, pseudocontact shifts, residual dipolar couplings due to metal and overall magnetic anisotropy, and cross correlation between Curie relaxation and nuclear-nuclear dipolar relaxation. The complete program has been tested by back-calculating NOEs and paramagnetism-based restraints from the X-ray structure of cytochrome c (553) from B. pasteurii. Furthermore, the same experimental restraints previously used to determine the solution structure of cytochrome c (553) itself, of cytochrome b (5), and of calbindin D(9k) with the program PARAMAGNETIC DYANA, have been used for structure calculations by using PARArestraints for Xplor-NIH. The agreement between the two programs is quite satisfactory and validates both protocols.     

Structure and dynamics of reduced Bacillus pasteurii cytochrome c: oxidation state dependent properties and implications for electron transfer processes

The solution structure of reduced Bacillus pasteurii cytochrome c, which has only 71 amino acids, has been determined by NMR to an RMSD of 0.46 +/- 0.08 A for all backbone atoms and 0.79 +/- 0.08 A for all heavy atoms and refined through restrained energy minimization. The target function out of 1645 constraints is 0.52 +/- 0.11 A(2), and the penalty function is 66 +/- 12 kJ mol(-)(1). The structure appears very similar to that in the oxidized state, only Trp87 and the propionates showing significant differences. The mobility was investigated through (15)N R(1) and R(2) relaxation rates, (15)N-(1)H NOE, and (1)H/(2)H exchange. It is found that the oxidized form is generally more mobile than the reduced one. By comparing the redox-state dependence of the structural/dynamic properties of Fe-S proteins, cytochrome c, and blue copper proteins, hints are provided for a better comprehension of the electron transfer processes.     

Tuning the affinity for lanthanides of calcium binding proteins

The possibility of selectively substituting one or more lanthanides into the four canonical calcium binding sites of calcium-loaded vertebrate calmodulin (CaM) was investigated by monitoring changes in the (1)H-(15)N HSQC NMR spectra of the (15)N-enriched protein upon titration with Yb(3+). The affinity of lanthanides for both N-terminal sites I and II is only moderately higher than that of calcium, and comparable with that of calcium for the two C-terminal sites. This situation induces binding of lanthanides to other noncanonical sites located at the interdomain linker, the N- and C-terminal ends, and at the inter-EF-hand linkers. Therefore, mutants were designed to alter the metal binding properties of calcium sites I (D22N, D24E), II (D58N, N60D, D58N-N60D), III (N97D), II-III (N60D-N97D), and IV (D129N), as well as of the inter-EF-hand linker of the N-terminal domain (N42K, T44K). The most striking effects were obtained for the N60D mutant at site II, as selective lanthanide binding is achieved even in the presence of excess calcium, and little or no population of the noncanonical sites occurs. Similar although less pronounced effects were observed for the N97D mutant. These findings allow us to better define some of the determinants of the relative affinities of calcium and lanthanides in CaM and, by extension, in other calcium binding proteins. Finally, by using CaM samples containing only three of the four calcium ions, it was possible to prepare well-defined Ca(3)Ln-CaM derivatives (Ln = Tb, Dy, Tm, and Yb), with interesting properties as NMR probes.     

Understanding copper trafficking in bacteria: interaction between the copper transport protein CopZ and the N-terminal domain of the copper ATPase CopA from Bacillus subtilis

In this paper the interaction of cytoplasmic CopZ and the N-terminal domain of the CopA ATPase from Bacillus subtilis has been studied by NMR through (15)N-(1)H HSQC experiments in order to understand the role of the two proteins in the whole copper trafficking mechanism of the bacteria. It appears that the two proteins interact in a fashion similar to that of the yeast homologue proteins [Arnesano, F., Banci, L., Bertini, I., Cantini, F., Ciofi-Baffoni, S., Huffman, D. L., and O'Halloran, T. V. (2001) J. Biol. Chem. 276, 41365-41376], although the surface potentials are reversed. A structural model for the interaction is proposed. (15)N mobility studies on the free proteins and on their complex are also reported. From these data, it appears that copper is largely transferred from CopZ to CopA, thus suggesting their possible involvement in a detoxification process. Comparing functional data of homologous proteins of other bacteria, it can be concluded that this class of proteins is involved in copper homeostasis but the specific roles are species dependent.