Influence of paramagnetic ions bound to human serum albumin on water 1HNMR relaxation times

The extent to which various paramagnetic ions (Cu2+, Mn2+ and Gd3+) free and bound to human serum albumin alter the water proton relaxation times at two frequencies has been investigated. NMR relaxation parameters, T1 and T2, were measured at 5 and 10 MHz using a saturation recovery (90 degrees-tau-90 degrees) and a spin-echo (90 degrees-tau-180 degrees) sequence respectively. We found that all three ions enhance their effectiveness in inducing water proton magnetic relaxation when they are bound to human serum albumin and that Gd3+ is the most effective in pure water and Mn2+ in the presence of the protein. Cu2+ has a smaller effect, but it presents an interesting behaviour correlated with the existence of two different binding sites, which is also confirmed by electronic paramagnetic resonance spectra. The results indicate the potential usefulness of large molecular paramagnetic complexes as contrast agents in NMR Imaging.     

Binding ability of a HHP-tagged protein towards Ni2+ studied by paramagnetic NMR relaxation: The possibility of obtaining long-range structure information

The binding ability of a protein with a metal binding tag towards Ni(2+) was investigated by longitudinal paramagnetic NMR relaxation, and the possibility of obtaining long-range structure information from the paramagnetic relaxation was explored. A protein with a well-defined solution structure (Escherichia coli thioredoxin) was used as the model system, and the peptide His-His-Pro (HHP) fused to the N-terminus of the protein was used as the metal binding tag. It was found that the tag forms a stable dimer complex with the paramagnetic Ni(2+) ion, where each metal ion binds two HHP-tagged protein molecules. However, it was also found that additional sites in the protein compete with the HHP-tag for the binding of the metal ion. These binding sites were identified as the side chain carboxylate groups of the aspartic and glutamic acid residues. Yet, the carboxylate groups bind the Ni(2+) ions considerably weaker than the HHP-tag, and only protons spatially close to the carboxylate sites are affected by the Ni(2+) ions bound to these groups. As for the protons that are unaffected by the carboxylate-bound Ni(2+) ions, it was found that the long-range distances derived from the paramagnetic relaxation enhancements are in good agreement with the solution structure of thioredoxin. Specifically, the obtained long-range paramagnetic distance constraints revealed that the dimer complex is asymmetric with different orientations of the two protein molecules relative to the Ni(2+) ion.     

Inhibitory copper binding site on the spinach cytochrome b6f complex: implications for Qo site catalysis

The isolated cytochrome (cyt) b(6)f complex from spinach is inhibited by Cu(2+) with a K(D) of about 1 microM at pH 7.6 in the presence of 1.6 microM decyl-plastoquinol (C(10)-PQH(2)) as a substrate. Inhibition was competitive with respect to C(10)-PQH(2) but noncompetitive with respect to horse heart cyt c or plastocyanin (PC). Inhibition was also pH-sensitive, with an apparent pK at about 7, above which inhibition was stronger, suggesting that binding occurred at or near a protonatable amino acid residue. Equilibrium binding titrations revealed ca. 1.4 tight Cu(2+) binding sites with a K(D) of about 0.5 microM and multiple (>8) weak (K(D) > 50 microM) binding sites per complex. Pulsed electron paramagnetic resonance (EPR) techniques were used to identify probable binding sites for inhibitory Cu(2+). A distinct enhancement of the relaxation time constant for the EPR signal from bound Cu(2+) was observed when the cyt f was paramagnetic. The magnitude and temperature-dependence of this relaxation enhancement were consistent with a dipole interaction between Cu(2+) and the cyt f (Fe(3+)) heme at a distance of between 30 and 54 A, depending upon the relative orientations of Cu(2+) and cyt f heme g-tensors. Two-pulse electron spin-echo envelope modulation (ESEEM) and 4-pulse 2-dimensional hyperfine sublevel correlation (2D HYSCORE) measurements of Cu(2+) bound to isolated cyt b(6)f complex indicated the presence of a weakly coupled nitrogen nucleus. The nuclear quadrupole interaction (NQI) and the hyperfine interaction (HFI) parameters identified one Cu(2+) ligand as an imidazole nitrogen of a His residue, and electron-nuclear double resonance (ENDOR) confirmed the presence of a directly coordinated nitrogen. A model of the 3-dimensional structure of the cytochrome b(6)f complex was constructed on the basis of sequences and structural similarities with the mitochondrial cyt bc(1) complex, for which X-ray structures have been solved. This model indicated three possible His residues as ligands to inhibitory Cu(2+). Two of these are located on the "Rieske" iron-sulfur protein protein (ISP) while the third is found on the cyt f protein. None of these potential ligands appear to interact directly with the quinol oxidase (Q(o)) binding pocket. A model is thus proposed wherein Cu(2+) interferes with the interaction of the ISP protein with the Q(o) site, preventing the binding and subsequent oxidation of plastoquinonol. Implications for the involvement of ISP "domain movement" in Q(o) site catalysis are discussed.     

NMR studies on Cu(II)-peptide complexes: exchange kinetics and determination of structures in solution

The interaction of copper(II) with histidine containing peptides has recently acquired renewed interest following the established link between abnormal protein behaviour in neurodegenerative processes and unpaired copper homeostasis. Five peptide sequences taken from the amyloid precursor protein and the prion protein were considered. Addition of paramagnetic Cu(II) ions to solutions of such peptides was not found to severely affect the appearance of NMR spectra, thus limiting the usual approach for structural determination. Exchange kinetics was shown to play a major role in determining the observed paramagnetic spin-lattice relaxation rates. Two independent methods were suggested for evaluating the exchange rates of His-containing peptides from the copper-coordination sphere and to calculate copper-proton distances. In such a way NMR was demonstrated to have the potential of providing detailed structures of the Cu(II)-peptide complexes in solution.     

Cu2+ site in photosynthetic bacterial reaction centers from Rhodobacter sphaeroides, Rhodobacter capsulatus, and Rhodopseudomonas viridis

The interaction of metal ions with isolated photosynthetic reaction centers (RCs) from the purple bacteria Rhodobacter sphaeroides, Rhodobacter capsulatus, and Rhodopseudomonas viridis has been investigated with transient optical and magnetic resonance techniques. In RCs from all species, the electrochromic response of the bacteriopheophytin cofactors associated with Q(A)(-)Q(B) --> Q(A)Q(B)(-) electron transfer is slowed in the presence of Cu(2+). This slowing is similar to the metal ion effect observed for RCs from Rb. sphaeroides where Zn(2+) was bound to a specific site on the surface of the RC [Utschig et al. (1998) Biochemistry 37, 8278]. The coordination environments of the Cu(2+) sites were probed with electron paramagnetic resonance (EPR) spectroscopy, providing the first direct spectroscopic evidence for the existence of a second metal site in RCs from Rb. capsulatus and Rps. viridis. In the dark, RCs with Cu(2+) bound to the surface exhibit axially symmetric EPR spectra. Electron spin echo envelope modulation (ESEEM) spectral results indicate multiple weakly hyperfine coupled (14)N nuclei in close proximity to Cu(2+). These ESEEM spectra resemble those observed for Cu(2+) RCs from Rb. sphaeroides [Utschig et al. (2000) Biochemistry 39, 2961] and indicate that two or more histidines ligate the Cu(2+) at the surface site in each RC. Thus, RCs from Rb. sphaeroides, Rb. capsulatus, and Rps. viridis each have a structurally analogous Cu(2+) binding site that is involved in modulating the Q(A)(-)Q(B) --> Q(A)Q(B)(-) electron-transfer process. Inspection of the Rps. viridis crystal structure reveals four potential histidine ligands from three different subunits (M16, H178, H72, and L211) located beneath the Q(B) binding pocket. The location of these histidines is surprisingly similar to the grouping of four histidine residues (H68, H126, H128, and L211) observed in the Rb. sphaeroides RC crystal structure. Further elucidation of these Cu(2+) sites will provide a means to investigate localized proton entry into the RCs of Rb. capsulatus and Rps. viridis as well as locate a site of protein motions coupled with electron transfer.     

Metal binding sites in proteins: identification and characterization by paramagnetic NMR relaxation

A method is presented that allows the identification and quantitative characterization of metal binding sites in proteins using paramagnetic nuclear magnetic resonance spectroscopy. The method relies on the nonselective longitudinal relaxation rates of the amide protons and their dependence on the paramagnetic metal ion concentration and the pH, and on the three-dimensional structure of the protein. The method is demonstrated using Escherichia coli thioredoxin as a model protein and Ni(2+) as the paramagnetic metal ion. Through a least-squares analysis of the relaxation rates, it is found that Ni(2+) binds to a series of specific sites on the surface of thioredoxin. The strongest binding site is found near the N-terminus of the protein, where the metal ion is coordinated to the free NH(2) group of the N-terminal serine residue and the side chain carboxylate group of the aspartic acid residue in position 2. In addition, Ni(2+) binds specifically but more weakly to the surface-exposed side chain carboxylate groups of residues D10, D20, D47, and E85.     

Characteristics of azurin from Pseudomonas aeruginosa via 270-MHz 1H nuclear magnetic resonance spectroscopy.

Assignments of resonances in the 1H nmr spectra of Cu(I) azurin to proton groups in the protein are discussed in detail. Comparisons are drawn between Cu(I), Cu(II), apo, Hg(II), and Co(II) azurin samples. Redox titration of Cu(I) azurin with K3Fe(CN)6, is used to correlate Cu(I) and Cu(II) 1H nmr spectral features, and observed line broadenings deriving from Cu(II) paramagnetic effects are used to deduce the distances of assigned proton groups from the copper center. Histidine residues are characterized in terms of pK values, rates of acid-base exchange near the the pK, and rates of C2H exchange with solvent deuterium. The possibility of histidine involvement in the azurincytochrome 551 electron exchange mechanism is discussed. A small number of NH protons observed to be distinctively inert to 2H exchange with solvent 2H2O, in the Cu(I) protein, are found to show increased lability on removal of the metal.     

Site-specific Labelling with a Metal Chelator for Protein-structure Refinement

A single free Cys sidechain in the N-terminal domain of the E. coli arginine repressor was covalently derivatized with S-cysteaminyl-EDTA for site-specific attachment of paramagnetic metal ions. The effects of chelated metal ions were monitored with (15)N-HSQC spectra. Complexation of Co(2+), which has a fast relaxing electron spin, resulted in significant pseudocontact shifts, but also in peak doubling which was attributed to the possibility of forming two different stereoisomers of the EDTA-Co(2+) complex. In contrast, complexation of Cu(2+) or Mn(2+), which have slowly relaxing electron spins, did not produce chemical shift changes and yielded self-consistent sets of paramagnetic relaxation enhancements of the amide protons. T (1) relaxation enhancements with Cu(2+) combined with T (2) relaxation enhancements with Mn(2+) are shown to provide accurate distance restraints ranging from 9 to 25 A. These long-range distance restraints can be used for structural studies inaccessible to NOEs. As an example, the structure of a solvent-exposed loop in the N-terminal domain of the E. coli arginine repressor was refined by paramagnetic restraints. Electronic correlation times of Cu(2+) and Mn(2+) were determined from a comparison of T (1) and T (2) relaxation enhancements.     

Identification of the Cu2+ binding sites in the N-terminal domain of the prion protein by EPR and CD spectroscopy

Recent evidence indicates that the prion protein (PrP) plays a role in copper metabolism in the central nervous system. The N-terminal region of human PrP contains four sequential copies of the highly conserved octarepeat sequence PHGGGWGQ spanning residues 60-91. This region selectively binds divalent copper ions (Cu(2+)) in vivo. To elucidate the specific mode and site of binding, we have studied a series of Cu(2+)-peptide complexes composed of 1-, 2-, and 4-octarepeats and several sub-octarepeat peptides, by electron paramagnetic resonance (EPR, conventional X-band and low-frequency S-band) and circular dichroism (CD) spectroscopy. At pH 7.45, two EPR active binding modes are observed where the dominant mode appears to involve coordination of three nitrogens and one oxygen to the copper ion, while in the minor mode two nitrogens and two oxygens coordinate. ESEEM spectra demonstrate that the histidine imidazole contributes one of these nitrogens. The truncated sequence HGGGW gives EPR and CD that are indistinguishable from the dominant binding mode observed for the multi-octarepeat sequences and may therefore comprise the fundamental Cu(2+) binding unit. Both EPR and CD titration experiments demonstrate rigorously a 1:1 Cu(2+)/octarepeat binding stoichiometry regardless of the number of octarepeats in a given peptide sequence. Detailed spin integration of the EPR signals demonstrates that all of the bound Cu(2+) is detected thereby ruling out strong exchange coupling that is often found when there is imidazolate bridging between paramagnetic metal centers. A model consistent with these data is proposed in which Cu(2+) is bound to the nitrogen of the histidine imidazole side chain and to two nitrogens from sequential glycine backbone amides.     

The pentaammineruthenium(III)histidine complex in ribonuclease A: application to the assignment of histidine proton resonances

The assignment of two histidine proton resonances in the proton NMR spectrum of ribonuclease A has been made by forming a paramagnetic complex between pentaammineruthenium(III) and the N-3 nitrogen of a single histidine residue. Reaction of chloropentaammineruthenium(III)dichloride with ribonuclease A in 0.1 m Tris-HCl, pH 7.0, 25°C yields a variety of products in which various histidine residues have been labeled. Cation-exchange chromatography affords the isolation of a specific derivative, labeled at a single histidine residue, that retains 66% of the activity toward the hydrolysis of 2′,3′-cyclic CMP. The site of labeling was determined by peptide mapping to be histidine 105. The binding of ruthenium results in the disappearance of both a histidine C-2 and a C-4 proton resonance from the downfield region of the proton NMR spectrum, as expected from model compound studies. The assignment of these two resonances to histidine 105 is in agreement with a previous assignment (J. L. Markley, 1975, Biochemistry, 14, 3546–3554), thereby demonstrating the potential utility of this ruthenium reagent in the assignment of histidine resonances in the proton NMR spectra of other proteins.     

Derivation of structural restraints using a thiol-reactive chelator

Recognition and identification of protein folds is a prerequisite for high-throughput structural genomics. Here we demonstrate a simple protocol for covalent attachment of a short and more rigid metal-chelating tag, thiol-reactive EDTA, by chemical modification of the single cysteine residue in barnase(H102C). Conjugation of the metal-chelating tag provides the advantage of allowing a greater range of paramagnetic metal substitutions. Substitution of Yb(3+), Mn(2+), and Co(2+) permitted measurement of metal-amide proton distances, dipolar shifts, and residual dipolar couplings. Paramagnetic-derived restraints are advantageous in the NMR structure elucidation of large protein complexes and are shown sufficient for validation of homology-based fold predictions.     

Structural characteristics of paramagnetic analogs of enzyme-substrate complexes of phosphorylation coupling factors

Mn2+-ion is linked to isolated chloroplast coupling factor CF-1 via the ATP bridge in the catalytically competent ternary complex as deduced from water proton relaxation rate measurements. Two essential SH-groups in CF-1 protein were modified with nitroxyl mercuric derivative as spin label. The substrate complex Ca2+-ATP is shown to induce the structural transition near the active site to the state with a stronger immobilized spin label. The distances between the paramagnetic metal ions and nitroxyl bound to the protein SH-group were evaluated as being in the range of 5-8,5 A for Cu2+ and 14-22 A for Mn2+.     

Studies of individual carbon sites of azurin from Pseudomonas aeruginosa by natural-abundance carbon-13 nuclear magnetic resonance spectroscopy.

The environments of the aromatic residues (and of the single arginine residue) of azurin from Pseudomonas aeruginosa are investigated by means of natural-abundance 13C Fourier transform NMR spectroscopy. In the case of the diamagnetic Cu(I) azurin, all 17 nonprotonated aromatic carbons (and Czota of Arg-79) yield narrow resonances. Furthermore, a single-carbon amide carbonyl resonance with an unusual chemical shift (peak chi) is observed. The pH dependence of chemical shifts is used to identify the resonances of Cgamma of titrating histidines, and of Cgamma and Czota of the two tyrosines. The resonances of Cgamma and Cdelta2 of the single tryptophan residue (and Czota of Arg-79) are also identified. The pKa values of the two tyrosines are different from each other and higher than typical values of "solvent-exposed" tyrosine residues. Two of the four histidine residues do not titrate (in the pH range 4 to 11). The resonance of Cgamma of one histidine exhibits a pH titration with fast proton exchange behavior and a pKa of 7.5 +/- 0.2. The direction of the titration shift indicates that the imidazole form of this histidine is the Ndelta1-H tautomer. The Cgamma resonance of the other titrating histidine exhibits slow exchange behavior with a pKa of about 7. The imidazole form of this histidine is the Nepsilon2-H tautomer. When going to the paramagnetic Cu(II) protein, only 11 of the 19 carbons mentioned above yield resonances that are narrow enough to be detected. Also, some of the observed resonances exhibit significant paramagnetic broadening. A comparison of spectra of fully reduced azurin, mixtures of reduced and oxidized azurin, and fully oxidized azurin yields the following information. (i) Peak chi arises from an amide group that probably is coordinated to the copper. (ii) The two nontitrating histidine residues are probably copper ligands, with Ndelta1 coordinated to the metal. (iii) The side chains of Arg-79 and the two tyrosine residues are not coordinated to the copper, and Trp-48 is probably not a ligand either. (iv) The gamma carbons of Trp-48, the tyrosine with the lower pKa, the titrating histidine with slow exchange behavior, and three or four of the six phenylalanine residues are sufficiently close to the copper to undergo significant paramagnetic broadening in the spectrum of oxidized azurin.     

Protein mobility and self-association by deuterium nuclear magnetic resonance.

Hen egg white lysozyme has been prepared in which the C epsilon position of the single histidine residue is substituted by a deuterium atom as a nondisturbing stable isotope probe. The deuterium nuclear magnetic resonance (2H NMR) spectrum in H2O shows a broad resonance (500--1000 Hz) due to the histidine deuteron and a sharp signal from residual HOD. The line width of the deuterium signal increases with pH, reflecting the self-association of lysozyme which is known to involve this histidine [shindo, H., Cohen, J.S., & Rupley, J. A. (1977) Biochemistry 16, 3879]. Correlation times calculated from spin-spin relaxation times (T2) derived from the 2H widths indicate that His-15 is restricted in motion and that lysozyme is predominantly dimerized at pH 7.5. Controls carried out with [epsilon-2H]imidazole showed a small pH dependence of the spin-lattice relaxation time (T1), which parallels the 2H chemical shift change upon ionization of the imidazole. Similar results cannot generally be observed by proton nuclear magnetic resonance (1H NMR) because of paramagnetic relaxation due to trace metal ion impurities. The pH dependence of the 2H T1 values indicates a change in the 2H quadrupole coupling constant upon protonation of the imidazole ring.     

EPR investigation of Cu2+-substituted photosynthetic bacterial reaction centers: evidence for histidine ligation at the surface metal site

The coordination environments of two distinct metal sites on the bacterial photosynthetic reaction center (RC) protein were probed with pulsed electron paramagnetic resonance (EPR) spectroscopy. For these studies, Cu2+ was bound specifically to a surface site on native Fe2+-containing RCs from Rhodobacter sphaeroides R-26 and to the native non-heme Fe site in biochemically Fe-removed RCs. The cw and pulsed EPR results clearly indicate two spectroscopically different Cu2+ environments. In the dark, the RCs with Cu2+ bound to the surface site exhibit an axially symmetric EPR spectrum with g(parallel) = 2.24, A(parallel) = 160 G, g(perpendicular) = 2.06, whereas the values g(parallel) = 2.31, A(parallel) = 143 G, and g(perpendicular) = 2.07 were observed when Cu(2+) was substituted in the Fe site. Examination of the light-induced spectral changes indicate that the surface Cu2+ is at least 23 A removed from the primary donor (P+) and reduced quinone acceptor (QA-). Electron spin-echo envelope modulation (ESEEM) spectra of these Cu-RC proteins have been obtained and provide the first direct solution structural information about the ligands in the surface metal site. From these pulsed EPR experiments, modulations were observed that are consistent with multiple weakly hyperfine coupled 14N nuclei in close proximity to Cu2+, indicating that two or more histidines ligate the Cu2+ at the surface site. Thus, metal and EPR analyses confirm that we have developed reliable methods for stoichiometrically and specifically binding Cu2+ to a surface site that is distinct from the well characterized Fe site and support the view that Cu2+ is bound at or near the Zn site that modulates electron transfer between the quinones QA and QB (QA-QB --> QAQB-) (Utschig, L. M., Ohigashi, Y., Thurnauer, M. C., and Tiede, D. M (1998) Biochemistry 37, 8278-8281) and proton uptake by QB- (Paddock, M. L., Graige, M. S., Feher, G., and Okamura, M. Y. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 6183-6188). Detailed EPR spectroscopic characterization of these Cu2+-RCs will provide a means to investigate the role of local protein environments in modulating electron and proton transfer.     

Suitability of immobilized metal affinity chromatography for protein purification from canola

This work demonstrates that proper selection of a metal ion and chelating ligand enables recovery of a his(6)-tagged protein from canola (Brassica napus) extracts by immobilized metal affinity chromatography (IMAC). When using Co(2+) with iminodiacetate (IDA) as the chelating ligand, beta-glucuronidase-his(6) (GUSH6) can be purified from canola protein extract with almost homogeneous purity in a single chromatographic step. The discrimination with which metal ions bound native canola proteins followed the order Cu(2+) < Ni(2+) < Zn(2+) < Co(2+) in regard to elimination of proteins coeluted with the fusion protein. IDA- and nitrilotriacetate (NTA)-immobilized metal ions showed different binding patterns, whose cause is attributed to a more rigid binding orientation of the his(6) in forming a tridentate with Me(2+)-IDA than in forming a bidentate with Me(2+)-NTA. The more flexible binding allows for multisite interactions over the protein.     

Metal-protein interactions: structure information from Ni(2+)-induced pseudocontact shifts in a native nonmetalloprotein

Information about the structure of a native nonmetalloprotein was obtained from the pseudocontact shifts induced by a paramagnetic metal ion bound to the protein. The approach exploits the presence of metal binding sites on the surface of the protein. Using Escherichia coli thioredoxin as a model protein, we show that potential binding sites can be identified using the Cu(2+) ion, and that pseudocontact shifts induced by a Ni(2+) ion bound to one of these sites can provide valuable long-range structure information about the protein.     

Electron paramagnetic resonance evidence for binding of Cu(2+) to the C-terminal domain of the murine prion protein.

Transmissible spongiform encephalopathies in mammals are believed to be caused by scrapie form of prion protein (PrP(Sc)), an abnormal, oligomeric isoform of the monomeric cellular prion protein (PrP(C)). One of the proposed functions of PrP(C) in vivo is a Cu(II) binding activity. Previous studies revealed that Cu(2+) binds to the unstructured N-terminal PrP(C) segment (residues 23-120) through conserved histidine residues. Here we analyzed the Cu(II) binding properties of full-length murine PrP(C) (mPrP), of its isolated C-terminal domain mPrP(121-231) and of the N-terminal fragment mPrP(58-91) in the range of pH 3-8 with electron paramagnetic resonance spectroscopy. We find that the C-terminal domain, both in its isolated form and in the context of the full-length protein, is capable of interacting with Cu(2+). Three Cu(II) coordination types are observed for the C-terminal domain. The N-terminal segment mPrP(58-91) binds Cu(2+) only at pH values above 5.0, whereas both mPrP(121-231) and mPrP(23-231) already show identical Cu(II) coordination in the pH range 3-5. As the Cu(2+)-binding N-terminal segment 58-91 is not required for prion propagation, our results open the possibility that Cu(2+) ions bound to the C-terminal domain are involved in the replication of prions, and provide the basis for further analytical studies on the specificity of Cu(II) binding by PrP.     

Proton longitudinal relaxation investigation of histidyl residues in human normal adult hemoglobin.

The longitudinal relaxation of the C2 protons of surface histidyl residues as well as other aromatic protons of human normal adult deoxyhemoglobin investigated at 360 MHz is discussed in terms of the theory proposed by Kalk and Berendsen for the proton longitudinal relaxation in proteins (Kalk, A., and H.J.C. Berendsen. 1976. J. Magn. Reson. 24:343-366). The role of the four paramagnetic iron atoms of deoxyhemoglobin as fast-relaxing sinks for the overall proton longitudinal relaxation is evaluated according to the model proposed by Bloembergen for the relaxation of nuclei in crystals containing paramagnetic centers (Bloembergen, N. 1949. Physica. 15:386-426). The results suggest that the effectiveness of the paramagnetic iron atoms of deoxyhemoglobin for the overall proton longitudinal relaxation is reduced as a result of slower spin diffusion and wide distribution of methyl groups within the hemoglobin molecule. Thus, deoxyhemoglobin provides a good model for investigating the influence of cross relaxation on proton longitudinal relaxation in proteins at the slow motion limit and in the presence of paramagnetic centers. For the C2 protons of surface histidyl residues, we show that the cross relaxation resulting from the interresidue dipolar interaction makes an important contribution to their longitudinal relaxation.     

Guanyl-specific ribonuclease from the fungus Penicillium chrysogenum strain 152 and its complex with guanosine 3'-phosphate studied by nuclear magnetic resonance

The method of proton magnetic resonance was used to obtain information on the active site of the guanyl-specific ribonuclease from Penicillium chrysogenum, strain 152A. Four pH-dependent signals in the aromatic region of the proton NMR spectrum of the enzyme were assigned to the C-2 and C-4 protons of the two histidine residues. To determine the pK values and the environment of the histidine residues the pH dependence of their chemical shifts was studied and experimental curves thus obtained were analyzed taking into account the effect of other dissociating groups of the enzyme. The pK values of the histidine residues were found to be equal to 7.92 +/- 0.04 and 7.86 +/- 0.09. The results of the calculations indicate that each histidine residue should interact with an acidic group (carboxylic) of the protein (pK 4.33 and 3.48) and the distance between two histidine residues does not exceed 0.85 nm. The rate constants for the quasi-first order reaction of deuterium exchange of the histidine residues (11.2 s-1 and 3.7 x-1) suggest that both residues are accessible, though to a different degree to solvent. Formation of a complex between the enzyme and guanosine 3'-phosphate (Guo3'P) is accompanied by the shift of the histidine pK toward the alkaline region by 0.5. The existence of the complex is controlled by dissociation of a histidine residue with pK 8.7 in alkaline medium and by protonation of the N-7 of Guo3'P (pK 2.4) in acid medium. Nuclear Overhauser effect measurements were used to determine the glycosidic torsion angle for the Guo3'P in the complex and to estimate the distances between the histidine residues of the enzyme and ribose ring of Guo-3'P. The results obtained suggest that the nucleotide in the complex has an anti conformation and the least exposed histidine is spaced not more than 0.5 nm from the C-1' proton of the nucleotide ribose ring. A model for the enzyme-nucleotide complex is presented.