Binding of thiocyanate and cyanide to manganese(III)-reconstituted horseradish peroxidase: a 15N nuclear magnetic resonance study

Binding of thiocyanate and cyanide ions to Mn(III) protoporphyrin-apohorseradish peroxidase complex [Mn(III)HRP] was investigated by relaxation rate measurements (at 50.68 MHz) of 15N resonance of SC15N- and C15N-. At pH = 4.0 the apparent dissociation constant (KD) for thiocyanate and cyanide binding to Mn(III)HRP was deduced to be 156 and 42 mM, respectively. The pH dependence of the 15N line width as well as apparent dissociation constant for thiocyanate and cyanide binding were quantitatively analyzed on the basis of a reaction scheme in which thiocyanate and cyanide in deprotonated form bind to the enzyme in a protonated form. The binding of thiocyanate and cyanide to Mn(III)HRP was found to be facilitated by protonation of an ionizable group on the enzyme [Mn(III)HRP] with a pKa = 4.0. From competitive binding studies it was shown that iodide, thiocyanate and cyanide bind to Mn(III)HRP at the same site; however, the binding site for resorcinol is different. The apparent dissociation constant for iodide binding deduced from competitive binding studies was found to be 117 mM, which agrees very well with the iodide binding to ferric HRP. The binding of thiocyanate and cyanide was shown to be away from the metal center and the distance of the 15N of thiocyanate and cyanide from the paramagnetic manganese ion in Mn(III)HRP was found to be 6.9 and 6.6 A, respectively. Except for cyanide binding, these observations parallel with the iodide and thiocyanate ion binding to native Fe(III)HRP. Water proton relaxivity measurements showed the presence of a coordinated water molecule to Mn(III)HRP with the distance of Mn-H2O being calculated to be 2.6 A. The slow reactivity of H2O2 towards Mn(III)HRP could be attributed to the presence of water at the sixth coordination position of the manganese ion.     

Binding of thiocyanate to lactoperoxidase: 1H and 15N nuclear magnetic resonance studies

The binding of thiocyanate to lactoperoxidase (LPO) has been investigated by 1H and 15N NMR spectroscopy. 1H NMR of LPO shows that the major broad heme methyl proton resonance at about 61 ppm is shifted upfield by addition of the thiocyanate, indicating binding of the thiocyanate to the enzyme. The pH dependence of line width of 15N resonance of SC15N- in the presence of the enzyme has revealed that the binding of the thiocyanate to the enzyme is facilitated by protonation of an ionizable group (with pKa of 6.4), which is presumably distal histidine. Dissociation constants (KD) of SC15N-/LPO, SC15N-/LPO/I-, and SC15N-/LPO/CN- equilibria have been determined by 15N T1 measurements and found to be 90 +/- 5, 173 +/- 20, and 83 +/- 6 mM, respectively. On the basis of these values of KD, it is suggested that the iodide ion inhibits the binding of the thiocyanate but cyanide ion does not. The thiocyanate is shown to bind at the same site of LPO as iodide does, but the binding is considerably weaker and is away from the ferric ion. The distance of 15N of the bound thiocyanate ion from the iron is determined to be 7.2 +/- 0.2 A from the 15N T1 measurements.     

Proton nuclear magnetic resonance studies on the iodide binding by horseradish peroxidase

Binding of an iodide ion to horseradish peroxidase was studied by following the hyperfine-shifted proton nuclear magnetic resonance signals of the enzyme. For the enzyme in an iodide-free solution, the spectra of hyperfine-shifted methyl region were only slightly affected by varying pH. In the presence of iodide (200 mM), however, both chemical shifts and line widths of the heme peripheral 1- and 8-methyl proton signals were markedly affected by the pH change from 7 to 4 and broadened at pH 4. From the change in peak heights of these signals at various concentrations of iodide, the dissociation constant of the iodide to the enzyme was calculated to be about 100 mM at pH 4.0. The peak derived from the proximal histidyl imidazole N epsilon-H proton was not perturbed by the addition of 200 mM iodide at pH 4.0 and 7.1. The rate of oxidation of iodide with hydrogen peroxide catalyzed by the enzyme was increased with decreasing pH, indicating the participation of an ionizable group with the pKa value of 4.0. Optical difference spectrum studies showed that iodide exerts no effect both at pH 4.0 and 7.4 on the binding affinity of resorcinol which is associated with the enzyme in the vicinity of the heme peripheral 8-CH3 group. These results suggest that an iodide ion binds to the enzyme at almost equal distance from the heme peripheral 1- and 8-methyl groups at the distal side of the heme and that the interaction becomes stronger in acidic medium with protonation of the ionizable group with the pKa value of 4.0.     

Binding of aromatic donor molecules to lactoperoxidase: proton NMR and optical difference spectroscopic studies

The interaction of aromatic donor molecules with lactoperoxidase (LPO) was studied using 1H-NMR and optical difference spectroscopy techniques. pH dependence of substrate proton resonance line-widths indicated that the binding was facilitated by protonation of an amino acid residue (with pKa of 6.1) which is presumably a distal histidine. Dissociation constants evaluated from both optical difference spectroscopy and 1H-NMR relaxation measurements were found to be an order of magnitude larger than those for binding to horse radish peroxidase (HRP), indicating relatively weak binding of the donors to LPO. The dissociation constants evaluated in presence of excess of I- and SCN- showed a considerable increase in their values, indicating that the iodide and thiocyanate ions compete for binding at the same site. The dissociation constant of the substrate binding was, however, not affected by cyanide binding to the ferric centre of LPO. All these results indicate that the organic substrates bind to LPO away from the ferric center. Comparison of the dissociation constants between the different substrates suggested that hydrogen bonding of the donors with the distal histidine amino acid, and hydrophobic interaction between the donors and the active site contribute significantly towards the associating forces. Free energy, entropy and enthalpy changes associated with the LPO-substrate equilibrium have been evaluated. These thermodynamic parameters were found to be all negative and relatively low compared to those for binding to HRP. The distances of the substrate protons from the ferric center were found to be in the range 9.4-11.1 A which are 2-3 A larger than those reported for the HRP-substrate complexes. These structural informations suggest that the heme in LPO may be more deeply buried in the heme crevice than that in the HRP.     

Activation of lactoperoxidase by heme‐linked protonation and heme‐independent iodide binding

Lactoperoxidase (LPO), a mammalian secretory heme peroxidase, catalyzes the oxidation of thiocyanate by hydrogen peroxide to produce hypothiocyanate, an antibacterial agent. Although LPO is known to be activated at acidic pH and in the presence of iodide, the structural basis of the activation is not well understood. We have examined the effects of pH and iodide concentration on the catalytic activity and the structure of LPO. Electrochemical and colorimetric assays have shown that the catalytic activity is maximized at pH 4.5. The heme Soret absorption band exhibits a small red‐shift at pH 5.0 upon acidification, which is ascribable to a structural transition from a neutral to an acidic form. Resonance Raman spectra suggest that the heme porphyrin core is slightly contracted and the Fe‐His bond is strengthened in the acidic form compared to the neutral form. The structural change of LPO upon activation at acidic pH is similar to that observed for myeloperoxidase, another mammalian heme peroxidase, upon activation at neutral pH. Binding of iodide enhances the catalytic activity of LPO without affecting either the optimum pH of activity or the heme structure, implying that the iodide binding occurs at a protein site away from the heme‐linked protonation site. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 113–120, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Horseradish peroxidase catalyzed oxidation of thiocyanate by hydrogen peroxide: comparison with lactoperoxidase-catalysed oxidation and role of distal histidine

Horseradish peroxidase-catalysed oxidation of thiocyanate by hydrogen peroxide has been studied by 15N-NMR and optical spectroscopy at different concentrations of thiocyanate and hydrogen peroxide and at different pH values. The extent of the oxidation and the identity of the oxidized product of the thiocyanate has been investigated in the SCN-/H2O2/HRP system and compared with the corresponding data on the SCN-/H2O2/LPO system. The NMR studies show that (SCN)2 is the oxidation product of thiocyanate in the SCN-/H2O2/HRP system, and its formation is maximum at pH less than or equal to 4 and that the oxidation does not take place at pH greater than or equal to 6. Since thiocyanate does not bind to HRP at pH greater than or equal to 6 (Modi et al. (1989) J. Biol. Chem. 264, 19677-19684), the binding of thiocyanate to HRP is considered to be a prerequisite for the oxidation of thiocyanate. It is further observed that at [H2O2]/[SCN-] = 4, (SCN)2 decomposes very slowly back to thiocyanate. The oxidation product of thiocyanate in the SCN-/H2O2/LPO system has been shown to be HOSCN/OSCN- which shows maximum inhibition of uptake by Streptococcus cremoris 972 bacteria when hydrogen peroxide and thiocyanate are present in equimolar amounts (Modi et al. (1991) Biochemistry 30, 118-124). However, in case of HRP no inhibition of oxygen uptake by this bacteria was observed. Since thiocyanate binds to LPO at the distal histidine while to HRP near 1- and 8-CH3 heme groups, the role of distal histidine in the activity of SCN-/H2O2/(LPO, HRP) systems is indicated.     

Steroid hormonal regulation of calcium-binding protein regucalcin mRNA expression in the kidney cortex of rats

Ethylenediamine tetraacetate ( EDTA ) inhibits lactoperoxidase (LPO)-catalyzed rate of iodide oxidation in concentration and pH-dependent manner. A plot of log Ki_app values against various pH yields a sigmoidal curve from which an ionisable group of pK_a value 6.0 could be ascertained for controlling the inhibition of catalytically active LPO by EDTA. Kinetic studies indicate that EDTA competitively inhibits iodide oxidation by acting as an electron donor. EDTA al so reduces LPO-compound-11 to the native ferric state by one-electron transfer as evidenced by the spectral shift from 428 to 412 nm. Optical difference spectroscopic studies indicate that EDTA binds to LPO with the apparent equilibrium dissociation constant (KD) of 12 ± 2 mM at pH 6.5. A plot of log K_D values against various pH produces a sigmoidal curve from which an ionisable group of LPO having pk_a = 5.47 could be calculated, deprotonation of which favours EDTA binding. EDTA also binds to LPO-CN- complex indicating its binding site away from heme iron centre. The K_D of LPO-EDTA complex is significantly increased (62 ± 5 mM) by iodide suggesting that EDTA binds close to the iodide binding site. EDTA also increases the K_D value of LPO-hydroquinone complex from 62 ± 5 mM to 200 ± 21 mM indicating that EDTA and aromatic donor binding sites are also close. We suggest that EDTA inhibits iodide oxidation competitively as an electron donor by interacting at or near the iodide binding site and these sites are close to the aromatic donor binding site.     

Assignment of exchangeable proximal histidine resonances in high-spin ferric hemoproteins: substrate binding in horseradish peroxidase.

Single-proton, exchangeable resonances have been detected in the high spin ferric hemoproteins, met-aquo myoglobin and horseradish peroxidase, which can be assigned to the proximal histidyl imidazole by virtue of their very large hyperfine shifts. While this proton is relatively labile in myoglobin, it is exchangeable in HRP only at extreme pH values, indicating a buried heme pocket. The insensitivity of the imidazole peak of HRP to substrate binding argues against direct interaction of imidazole and substrate.     

Interaction of aromatic donor molecules with manganese(III) reconstituted horseradish peroxidase: proton nuclear magnetic resonance and optical difference spectroscopic studies

The interaction of aromatic donor molecules with manganese(III) protoporphyrin-apohorseradish peroxidase complex [Mn(III)HRP] was investigated by optical difference spectroscopy and relaxation rate measurements of 1H resonances of aromatic donor molecules (at 500 MHz). pH dependence of substrate proton resonance line-widths indicated that the binding was facilitated by protonation of an amino acid residue (with a pKa of 6.1), which is presumably distal histidine. Dissociation constants were evaluated from both optical difference spectroscopy and 1H-NMR relaxation measurements (pH 6.1). The dissociation constants of aromatic donor molecules were not affected by the presence of excess of I-, CN- and SCN-. From competitive binding studies it was shown that all these aromatic donor molecules bind to Mn(III)HRP at the same site, which is different from the binding site of I-, CN- and SCN-. Comparison of the dissociation constants between the different substrates suggests that hydrogen bonding of the donors with distal histidyl amino acid and hydrophobic interaction between the donors and active site contribute significantly towards the associating forces. Free energy, entropy and enthalpy changes associated with the Mn(III)HRP-substrate equilibrium have been evaluated. These thermodynamic parameters were found to be all negative. Distances of the substrate protons from the paramagnetic manganese ion of Mn(III)HRP were found to be in the range of 7.7 to 9.4 A. The Kd values, the thermodynamic parameters and the distances of the bound aromatic donor protons from metal center in the case of Mn(III)HRP were found to be very similar as in the case of native Fe(III)HRP.     

The effect of cytochrome P-450cam on the NMR relaxation rate of water protons.

Cytochrome P-450cam in the native, substrate-free state (Fe3+, S = 1/2) substantially reduces the NMR relaxation times, T1 and T2, of water protons. Temperature and frequency dependences of T1 and T2 were measured; they are consistent with a model of one or two protons exchanging between a binding site on a heme ligand and bulk water. The relevant parameters of this model have been deduced from the data. The spin relaxation time of the heme iron, tau S similar to 0.5 ns at 25 degrees C, is unusually long for a low spin ferric heme protein but is compatible with the line widths measured for paramagnetically shifted heme resonances. The proton residence time on the ligand, tau M similar to 1 microsecond at 25 degrees C, follows an Arrhenius law with activation energy EM similar to 15 kcal/mol. A scalar hyperfine interaction A/h = 2.2 MHz (3.1 MHz for one-proton exchange) of the found proton(s) with the heme iron is deduced from the difference between T1 and T2 observed in the fast exchange limit. The iron-proton distance is found to be 2.9 A (2.6 A for one-proton exchange). Variation of pH between pH 6.4 and 8.6 does not affect T1. The bearing of these results on the question of the axial heme ligand is discussed.     

Molecular basis for the anti-sickling activity of aromatic amino acids and related compounds: a proton nuclear magnetic resonance investigation

High-resolution proton nuclear magnetic resonance spectroscopy and relaxation techniques have been used to investigate the interactions of sickle cell hemoglobin (Hb S) and human normal adult hemoglobin (Hb A) with p-bromobenzyl alcohol, L-phenylalanine, L-tryptophan, and L-valine. With the exception of valine, all these compounds inhibit the polymerization of deoxy-Hb S [Noguchi, C. T., & Schechter, A. N. (1978) Biochemistry 17, 5455)). Using transferred nuclear Overhauser effects among the proton resonances of the compound of interest and the corresponding longitudinal relaxation rates (T1(-1], we have shown that the binding of each of the compounds investigated to deoxy-Hb S is comparable to that to deoxy-Hb A. Intermolecular transferred nuclear Overhauser effects have been observed between proton resonances of the anti-sickling compounds and specific protons situated in the heme pockets of Hb. On the basis of these results, we suggest that one binding site, common to all compounds with anti-sickling activity, is at or near the heme pockets in the alpha and beta chains of both deoxy-HB S and deoxy-Hb A. The proton T1(-1) values of the histidyl residues situated over the surface of the hemoglobin molecule indicate that a second binding site is located at or near the beta 6 position, containing the mutation in Hb S (beta 6Glu----Val). The binding of the compounds investigated to the latter site induces conformational changes in the amino-terminal domains of the beta chains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preparation and characterization of a uniformly 2 H/ 15 N-labeled RNA oligonucleotide for NMR studies.

An RNA oligonucleotide that contains the binding site for Escherichia coli ribosomal protein S8 was prepared with uniform 15N isotopic enrichment and uniform deuterium enrichment at all non-exchangeable sites using enzymatic methods. The RNA binding site, which contains 44 nt, forms a hairpin in solution and requires Mg2+for proper folding. The longitudinal magnetization recovery rates of the exchangeable protons were compared for the [2H,15N]-enriched RNA molecule and for the corresponding fully [2H,15N]-enriched RNA hairpin. It was found that 1H-1H dipolar relaxation significantly contributes to the recovery of exchangeable proton longitudinal magnetization. The exchangeable proton resonance line widths were less affected by deuteration, indicating that chemical exchange with H2O remains the dominant mechanism of transverse magnetization relaxation. Nevertheless, deuteration of this RNA hairpin was found to enhance the sensitivity of NOE-based experiments relative to the fully protonated hairpin and to simplify 2D NMR spectra. The increased signal-to-noise ratio facilitated the assignment of the cytidine amino resonances and several of the purine nucleotide amino resonances and permitted the identification of NOE crosspeaks that could not be observed in spectra of the fully protonated RNA hairpin.     

Reaction of horseradish peroxidase with azide and some implications for the heme environmental structure. NMR and kinetic studies.

The azide complex of horseradish peroxidase was studied by high resolution 1H and 15N NMR spectroscopy and by the temperature-jump method. The heme peripheral methyl proton peaks and the ligand 15N resonance were resolved to show that binding of azide by horseradish peroxidase occurs only in acidic solution below pH 6.5. It was also found that the chemical exchange rate of azide with the ferric enzyme was much faster on the 1H and 15N NMR time scale. This was further substantiated by kinetics of azide binding by horseradish peroxidase where the chemical exchange rate was confirmed to be in the microseconds range at pH 5.0 and 23 degrees C. This rate is salient in usual ligand exchange reactions in hemoproteins so far reported. pH dependences of the first order association and dissociation rate constants were also studied by the temperature-jump method to suggest a strong linkage of the azide binding with a proton uptake of an amino acid residue on the enzyme. These results were compared with the case of horse metmyoglobin and were interpreted to indicate that a heme-linked ionizable group on the enzyme facilitates the fast entry of the ligand to the coordination site. A histidyl residue is a possible candidate for the ionizable group of the enzyme.     

Characterization of pH-dependent conformational heterogeneity in Rhodospirillum rubrum cytochrome c2 using 15N and 1H NMR

The 15N-enriched ferricytochrome c2 from Rhodospirillum rubrum has been studied by 15N and 1H NMR spectroscopy as a function of pH. The 15N resonances of the heme and ligand tau nitrogen are broadened beyond detection because of paramagnetic relaxation. The 15N resonance of the ligand histidine phi nitrogen was unambiguously identified at 184 ppm (pH 5.6). The 15N resonances of the single nonligand histidine are observed only at low pH, as in the ferrocytochrome because of the severe broadening caused by tautomerization. The dependence of the 15N and 1H spectra of the ferricytochrome on pH indicated that the ligand histidine tau NH does not dissociate in the neutral pH range and is involved in a hydrogen bond, similar to that in the reduced state. Because neither deprotonated nor non-hydrogen-bonded forms of the ligand histidine are observed in the spectra of either oxidation state, the participation of such forms in producing heterogeneous populations having different electronic g tensors is ruled out. Transitions having pKa's of 6.2, 8.6, and 9.2 are observed in the ferricytochrome. The localized conformational change around the omega loops is observed in the neutral pH range, as in the ferrocytochrome. Structural heterogeneity leads to multiple resonances of the heme ring methyl at position 8. The exchange rate between the conformations is temperature dependent. The transition with a pKa of 6.2 is assigned to the His-42 imidazole group. The displacement of the ligand methionine, which occurs with a pKa of 9.2, causes gross conformational change near the heme center.(ABSTRACT TRUNCATED AT 250 WORDS)     

Coordination geometry of heme in lactoperoxidase: pH-dependent 1H relaxivity and optical spectral studies

Molar relaxivity of water proton in lactoperoxidase solution was studied as a function of pH in the range of 2-13 by spin-lattice relaxation time measurements on a Bruker AM 500 MHz nuclear magnetic resonance (NMR) spectrometer. It was shown by comparison with the molar relaxivities of met myoglobin (Mb) and horseradish peroxidase (HRP) solutions that the sixth coordination position of the heme pocket in lactoperoxidase (LPO) is vacant. Distance of the water proton in the heme pocket from ferric ion was deduced to be 2.7, 3.6 and 4.3 A for Mb, HRP, and LPO, respectively. Acid-alkaline transition for met myoglobin, horseradish peroxidase, and lactoperoxidase determined from the pH dependence of changes in the Soret absorptions were found to be characterized by pK of 8.8, 10.9, and 12.1, respectively. Proton NMR of LPO at pH = 12.2 was found to have single broad resonance considerably upfield shifted as compared to that of LPO at neutral pH. By comparison with the proton NMR of HRP and Mb at pH greater than their respective pK of acid-alkaline transition, the upfield shifted proton resonance of LPO at pH = 12.2 was assigned to be due to low-spin LPO.     

Structural characterization of nitrimyoglobin

Nitrimyoglobin was formed in greater than 94% yield by a simple reaction between excess nitrite and horse heart metmyoglobin at pH 5.5. This dark green pigment was shown by 1H NMR spectroscopy to be a single, pure product with a well defined tertiary structure that is highly similar to the starting myoglobin. Electronic spin states parallel those of myoglobin, although the relaxation times differ. Ligand binding reactions of nitrimyoglobin parallel those of normal myoglobin, but lead to a unique series of UV-visible spectra. In the ferrous state, nitrimyoglobin reversibly binds O2 with half-saturation of sites at an O2 partial pressure of 10.4 +/- 1.4 mm Hg. 1H NMR data indicate that the altered heme of nitrimyoglobin has not undergone reaction at any meso proton position, nor has it been partially saturated to the level of a chlorin. 15N NMR spectra indicate that only a single nitrogen was added to the protein as a nitro group. Extraction of the modified heme from nitrimyoglobin and spectroscopic characterization of the nitriheme by infrared spectroscopy and of the free base porphyrin methyl ester derived from nitriheme by 1H NMR indicate that the modification is regiospecific. The heme in nitrimyoglobin is 3-(trans-2-nitrovinyl)-2,7,12,18-tetramethyl-8-vinylporphyrin-13,1 7-dipropionic acid. In the Fisher nomenclature scheme, the 2-vinyl substituent is the site of modification and has been converted to a nitrovinyl group by substitution of a proton by -NO2.     

Assignments of 15N and 1H NMR resonances and a neutral pH ionization in Rhodospirillum rubrum cytochrome c2

The phi NH proton and 15N resonances of the ligand histidine of Rhodospirillum rubrum fericytochrome c2 are found at 14.7 and 184 ppm, respectively, contradicting the proposal that this proton is absent in the R. rubrum ferricytochrome. Substitution of the deuterium atom for this proton causes small upfield shifts of the phi nitrogen in both oxidation states, indicating that the phi NH-peptide carboxyl hydrogen bond is not substantially weakened by the substitution. The proton and 15N resonances of the indolic NH group of the invariant tryptophan-62 and numerous proton resonances of the heme and extraheme ligands in the spectrum of the ferricytochrome are also assigned. An ionization in the ferrocytochrome occurring at neutral pH is assigned to the single nonligand histidine. This attribution is supported by the direct measurement of the ionization by NOE difference spectroscopy and by comparative structural arguments involving closely related cytochromes and chemically modified cytochromes.     

An NMR and circular dichroism study of the interaction of thiocyanate with human and cross-linked hemoglobin: identification of Lys-alpha-99 as a possible dissociation linked binding site

The interaction of thiocyanate with human native and cross-linked oxyhemoglobin (oxyHb), and methemoglobin (metHb) has been investigated by optical spectroscopy, circular dichroism (CD) and nuclear spin lattice relaxation rate measurements. The interaction of thiocyanate anion with human hemoglobin has been investigated by NMR measurements of the nuclear spin lattice relaxation rate of N(15) labeled thiocyanate in the presence of cyanomethemoglobin and cross-linked cyanomethemoglobin. Results show that thiocyanate is located approximately 8.9 and 6.2 A away from the heme group in cyanomethemoglobin and cross-linked cyanomethemoblobin, respectively. These results are consistent with the binding of SCN(-) at the lys-alpha-99 in the unmodified hemoglobin. Since this site is blocked in the cross-linked hemoglobin, the binding site is different. Results show that one mole of SCN(-) is binding to one mole of oxyhemoglobin suggesting that binding at the lys-alpha-99 is linked to dissociation of the hemoglobin tetramer into dimers due to its location at the alpha(1)beta(2) interface. Circular dichroism studies show that the interaction of thiocyanate with oxyHb decreases the optical rotation at 240 nm indicating a conformational change of the protein, which influences the electronic transitions of a number of peptide bonds or (and) a few aromatic side chains.     

Binding of oxytocin and 8-arginine-vasopressin to neurophysin studied by 15N NMR using magnetization transfer and indirect detection via protons

NMR was used to monitor the binding to neurophysin of oxytocin and 8-arginine-vasopressin, 15N labeling being used to identify specific backbone 15N and 1H signals. The most significant effects of binding were large downfield shifts in the amino nitrogen resonance of Phe-3 of vasopressin and in its associated proton, providing evidence that the peptide bond between residues 2 and 3 of the hormones is hydrogen-bonded to the protein within hormone-neurophysin complexes. Suggestive evidence of hydrogen bonding of the amino nitrogen of Tyr-2 was also obtained in the form of decreased proton exchange rates on binding; however, the chemical shift changes of this nitrogen and its associated proton indicated that such hydrogen bonding, if present, is probably weak. Shifts in the amino nitrogen of Asn-5 and in the -NH protons of both Asn-5 and Cys-6 demonstrated that these residues are significantly perturbed by binding, suggesting conformational changes of the ring on binding and/or the presence of binding sites on the hormone outside the 1-3 region. No support was obtained for the thesis that there is a significant second binding site for vasopressin on each neurophysin chain. The behavior of both oxytocin and vasopressin on binding was consistent with formation of 1:1 complexes in slow exchange with the free state under most pH conditions. At low pH there was evidence of an increased exchange rate. Additionally, broadening of 15N resonances in the bound state at low pH occurred without a corresponding change in the resonances of equilibrating free hormone.(ABSTRACT TRUNCATED AT 250 WORDS)     

1H-NMR study of heme propanoate mobility in the active site of myoglobin from Galeorhinus japonicus

Time-dependent NOE studies of the C13(1) and C17(1) methylene proton resonances of the heme peripheral propanoate groups have elucidated their mobility in the active site of the ferric high-spin form of Galeorhinus japonicus myoglobin. A large difference in the chemical shift due to the non-equivalence of the heme C13(1) and C17(1) methylene proton resonances allows selective irradiation of a given proton resonance by a high-power selective decoupler pulse in spite of their fast relaxation rates. NOE accumulation of the resonance of one methylene proton after saturation of the resonance of the other proton essentially follows the theoretical prediction derived using the two-spin approximation, and the cross-relaxation rates for the heme C13(1) and C17(1) methylene proton spin systems were quantitatively determined. The correlation time for the mobility of the internuclear vector connecting the heme C13(1) or C17(1) methylene protons was then calculated from the cross-relaxation rate and values of approximately 11 ns were obtained for both C13(1) and C17(1) methylene groups in 2 mM Galeorhinus japonicus myoglobin at 35 degrees C. The immobile C13(1) and C17(1) methylenes of the heme propanoate groups, together with a large difference in chemical shift between the methylene proton resonances, dictate their fixed orientation with respect to the protein moiety as well as the heme plane, and are therefore consistent with the immobile heme in the active site of myoglobin.