Kinetic resolution of ligand binding to the alpha and beta chains within human hemoglobin.

Nitric oxide has been used as a chain-specific, spin label of unliganded heme groups present in kinetic mixtures of human hemoglobin and n-butyl isocyanide. In these experiments, deoxyhemoglobin was reacted with n-butyl isocyanide for a controlled time and then mixed rapidly with a high concentration of nitric oxide to fill residual, unoccupied heme sites. The final mixture was frozen immediately after formation to prevent any displacement of bound isonitrile. The EPR spectrum of the frozen sample was resolved into alpha and beta nitric oxide components; these reflect the relative proportions of alpha- and beta-heme sites which were unoccupied by n-butyl isocyanide. Individual time courses for the alpha and beta subunits were obtained by varying the time between the formation of the isonitrile/hemoglobin mixture and its reaction with nitric oxide. At pH 7.0 only the beta chain time course exhibits an initial rapid phase; the alpha chain time course is monophasic, exhibiting almost, exponential behavior. This result shows unequivocally that the beta-hemes within deoxyhemoglobin react much more rapidly with n-butyl isocyanide than the alpha hemes.     

Effect of inositol hexakisphosphate on the EPR properties of the nitric oxide derivative of ferrous dromedary (Camelus dromedarius) hemoglobin. Evidence for two polyanion binding sites

The effect of inositol hexakisphosphate on the EPR properties of the nitric oxide derivative of ferrous dromedary (Camelus dromedarius) hemoglobin has been investigated at 110 K. In the absence of inositol hexakisphosphate, the nitrosyl derivative of dromedary hemoglobin shows an EPR spectrum with a rhombic shape and a weak hyperfine splitting in the gz region, a feature that is generally taken as characteristic of the high-affinity state of tetrameric hemoproteins. On addition of 1 mole of inositol hexakisphosphate/tetramer, three new hyperfine lines (Az = 1.7 mT), centered at gz = 2.01, appear; this type of spectrum is indicative of the low-affinity state of hemoglobins. A further addition of inositol hexakisphosphate, corresponding to a 20-fold molar excess, completely reverses the polyphosphate-dependent transition, giving an EPR spectrum that is exactly superimposable to that observed in the absence of the allosteric effector, i.e., is typical of the high-affinity state of the macromolecule. Both in the absence and presence of inositol hexakisphosphate, the EPR spectra are virtually independent of pH in the range explored (from 5.5 to 7.5). These results, taken together with the behavior of the nitric oxide derivative of human hemoglobin, provide further evidence for the existance in dromedary hemoglobin of two polyanion binding sites that affect in an opposite way the conformational equilibrium of the macromolecule.     

Spectral transitions of nitrosyl hemes during ligand binding to hemoglobin.

Human deoxyhemoglobin has been titrated with nitric oxide at several pH values ranging from 6.0 to 9.0, in the presence and absence of the allosteric effector inositol hexaphosphate at 25 degrees C. Samples were frozen for EPR measurements or analyzed optically within 30 s after mixing to ensure a kinetic population of intermediates. Fractions of pentacoordinate alpha-NO heme groups were determined by fitting EPR and absorbance difference spectra in terms of linear combinations of standard signals. Equivalent results were obtained by these techniques. The fraction of alpha-NO heme exhibiting pentacoordinate character in Hb4NO increases from 0.07 to 0.73 in going from pH 9 to 6. The fraction of alpha hemes which are pentacoordinate in fully saturated nitrosyl hemoglobin, Hb4(NO), increases from 0.0 to 0.41 over the same pH range. Only in the presence of bound inositol-P6 are all 4 the alpha-NO hemes pentacoordinate. Thus, the expression of modified NO heme character is not simply a reflection of the formation of low affinity quaternary conformations. Rather, within this conformation the alpha chain iron atoms exhibit an equilibrium between hexa- and pentacoordinate structures which is perturbed markedly by both proton and phosphate binding. No intermediate coordination structure of the type suggested by Chevion et al. (Chevion, M., Stern, A., Peisach, J., Blumberg, W.E., and Simon, S. (1978) Biochemistry 17, 1745-1750) appears to occur since the observed alpha-NO heme spectra can always by represented quantitatively as a linear combination of the normal hexacoordinate and pentacoordinate signals. The formation of pentacoordinate alpha-NO causes this subunit to exhibit a higher affinity for nitric oxide. Thus on standing at low levels of saturation, there is a slow (t1/2 approximately equal to 8 min at pH 7, 25 degrees C) re-equilibration of ligand from beta to alpha subunits. The final ratio of alpha-NO to beta-NO is 2 to 1 in the absence of phosphates and greater than 10 to 1 in the presence of inositol hexaphosphate.     

Effect of inositol hexakisphosphate on the spectroscopic properties of the nitric oxide derivative of ferrous naturally glycated human hemoglobin HbA1c

The effect of inositol hexakisphosphate (IHP) on the spectroscopic (EPR and absorbance) properties of the nitric oxide derivative of ferrous naturally glycated human hemoglobin HbA1c (HbA1cNO) has been investigated quantitatively. The results obtained show that 1) both in the absence and presence of IHP, the EPR and absorbance spectra of HbA1cNO show the same basic characteristics described for the nitrosyl derivative of ferrous HbA0, the nonglycated major component of human hemoglobin (HbA0NO); and 2) HbA1cNO binds IHP with an apparent dissociation equilibrium constant (upsilon = 1.8 x 10(-2) M), which is at least four orders of magnitude higher than that estimated for the polyphosphate interaction with HbA0NO (less than or equal to 3 x 10(-6) M). These data provide further independent evidence that interaction(s) of polyphosphates at the specific cleft between beta-chains along the dyad-axis is sterically hindered in HbA1c by the presence of the two glucose residues covalently bound to the N-termini of beta-chains, this finding being in agreement with the reduced effect of polyanions on HbA1c spectral and ligand-binding properties.     

Effect of removal of a salt-bridge on the oxygen binding properties and the electronic structure of heme in cobalt-iron hybrid hemoglobin.

In order to clarify the role of salt-bridges in hemoglobin, the oxygen equilibrium curves and electron paramagnetic resonance (EPR) spectra of cobalt-iron hybrid hemoglobins were determined. The EPR spectra of deoxy alpha(Co)2 beta(Fe)2 could be interpreted as a mixture of two distinct paramagnetic species: one showed a maximum of the first derivative spectrum at g = 2.39 and the other at g = 2.33. The oxygen equilibrium curves of the hybrid indicated that the former is assignable to the T structure and the latter to the R structure. The cooperativity of oxygen binding of alpha(Co)2 beta(Fe)2 exhibited a maximum at g = 2.33, which is characteristic of the R structure, regardless of the pH. Addition of inositol hexaphosphate (IHP) to des-Arg alpha(Co)2 beta(Fe)2 restored the cooperativity of oxygen binding, which implies that the deoxygenated form of des-Arg alpha(Co)2 beta(Fe)2 is converted to the T structure upon addition of IHP. However, the EPR signal at g = 2.39 was not restored upon conversion to the T structure by addition of IHP. It is therefore concluded that the EPR spectrum of the deoxy alpha(Co) subunit depends both on the quaternary structure and on the localized strain at the heme.     

Geminate reactions of oxygen and nitric oxide with the alpha and beta subunits of Fe-Co hybrid hemoglobins

The alpha and beta subunits in Fe-Co hybrid hemoglobins differ in their rapid reactions with dioxygen and nitric oxide after dissociation by a 25-ns photoflash. The alpha subunits show little recombination on a scale of tens of nanoseconds, whereas the beta subunits show extensive recombination on this time sale. The alpha-beta difference is more marked with Fe than with Co and greater with dioxygen as ligand than with nitric oxide, but is clearly evident in all combinations of ligand and metal. Addition of inositol hexaphosphate slows ligand binding and reduces the proportion of rapid recombination of dioxygen and nitric oxide to beta-Fe subunits. The behavior of alpha-Fe subunits is unaffected by this compound. These results permit the beta subunit to be identified as the T-state species which equilibrates rapidly with oxygen in the T-state, i.e. the reverse of the identification suggested on structural grounds.     

Studies on cobalt myoglobins and hemoglobins. Preparation of isolated chains containing cobaltous protoporphyrin IX and characterization of their equilibrium and kinetic properties of oxygenation and EPR spectra.

Human hemoglobin containing cobalt protoporphyrin IX or cobalt hemoglobin has been separated into two functionally active alpha and beta subunits using a new method of subunit separation, in which the -SH groups of the isolated subunits were successfully regenerated by treatment with dithiothreitol in the presence of catalase. Oxygen equilibria of the isolated subunit chains were examined over a wide range of temperature using Imai's polarographic method (Imai, K., Morimoto, H., Kotani, M., Watari, H., and Kuroda, M. (1970) Biochim. Biophys. Acta 200, 189-196). Kinetic properties of their reversible oxygenation were investigated by the temperature jump relaxation method at 16 degrees. Electron paramagnetic resonance characteristics of the molecules in both deoxy and oxy states were studies at 77K. The oxygen affinity of the individual regenerated chains was higher than that of the tetrameric cobalt hemoglobin and was independent of pH. The enthalpy changes of the oxygenation have been determined as -13.8 kcal/mol and -16.8 kcal/mol for the alpha and beta chains, respectively. The rates of oxygenation were similar to those reported for iron hemoglobin chains, whereas those of deoxygenation were about 10(2) times larger. The effects of metal substitution on oxygenation properties of the isolated chains were correlated with the results obtained previously on cobalt hemoglobin and cobalt myoglobin. The EPR spectrum of the oxy alpha chain showed a distinctly narrowed hyperfine structure in comparison with that of the oxy beta chain, indicating that the environment around the paramagnetic center (the bound oxygen) is different between these chains. In the deoxy form, EPR spectra of alpha and beta chains were indistinguishable. These observations suggest that one of the inequivalences between alpha and beta chains might exist near the distal histidine group.     

Nonequivalence of subunits in [15N]nitrosylhemoglobin Kansas. A single crystal electron paramagnetic resonance investigation.

EPR spectra of Hb15NO crystals of mutant Kansas (Asn G4(102) beta leads to Thr) have been recorded at every 5' intervals and in three orthogonal planes. The nitrosylhemes are nonequivalent for the alpha and beta subunits, their assignments are made possible by comparison with the powder EPR specrtra of Hb15NO of mutant Iwate (His F8(87)alpha leads to Tyr) (Trittelvitz, E., Gersonde, K., and Winterhalter, K.H. (1975) Eur. J. Biochem. 51, 33-42). The EPR parameters for the beta-nitrosylhemes of Hb Kansas are: gxx=2.094 gyy=2.031, gzz=2.00, Azetazeta=11 G, Azetazeta=32.5 G, Aetaeta=12.5 G; the Fe-N-O bond angle is about 105 degrees. The paramters for the alpha-nitrosyl hemes are: gxx=2.058, gyy=2.021, gzz=1.977, Azetazeta=24.5 G, Azetazeta less than or equal to 5G, Aetaeta=23 G; the Fe-N-O bond angle is about 167 degrees. Hyperfine splittings of 7 to 8 gauss with 14Nepsilon atom of His(F8) were observed for the beta-nitrosylhemes; none was resolved for the alpha-nitrosylhemes. The results were interpreted to mean that the tension on the iron of the beta subunits is not large in the unliganded state and this tension was not greatly increased by the binding of nitric oxide in the strongly bent configuration. The tension at the iron in the deoxyhemoglobin is dominant at the alpha subunits. Binding of nitric oxide in this case causing either the breaking or great weakening of the Fe-His(F8) bond. The nitrosyl is in a nearly linear configuration. The unpaired electron densities at the nitrogen atom of the bound nitric oxide is about 63% for the beta-nitrosylheme and 37% for the alpha-nitrosylhemes.     

Properties of chemically modified Ni(II)-Fe(II) hybrid hemoglobins. Ni(II) protoporphyrin IX as a model for a permanent deoxy-heme

Chemical modifications, NES-Cys(beta 93), des-Arg(alpha 141), and both modifications on the same molecule, were made to Ni-Fe hybrid hemoglobins, and their effect on individual subunits was investigated by measuring oxygen equilibrium curves, the Fe(II)-N epsilon (His F8) stretching Raman lines, and light-absorption spectra. The oxygen equilibrium properties indicated that modified Ni-Fe hybrid hemoglobins remain good models for the corresponding deoxy ferrous hemoglobins, although K1, the dissociation equilibrium constant for the first oxygen to bind to hemoglobin, was decreased by the chemical modifications. Resonance Raman spectra of deoxy alpha 2 (Fe) beta 2 (Ni) and light-absorption spectra of deoxy alpha 2 (Ni) beta 2 (Fe), revealed that the state of alpha hemes in both hybrid hemoglobins underwent a transition from a deoxy-like state to an oxy-like state caused by these chemical modifications when K1 was about 3 mm Hg (1 mm Hg approximately 133.3 Pa). On the other hand, the state of beta hemes in hybrid hemoglobins was little affected, when K1 was larger than 1 mm Hg. Modified alpha 2 (Fe) beta 2 (Ni) gave a Hill coefficient greater than unity with a maximum of 1.4 when K1 was about 4 mm Hg. The two-state model predicts that the K1 value at the maximum Hill coefficient should be much larger than this value. For oxygen binding to unmodified alpha 2 (Ni) beta 2 (Fe), oxygen equilibrium data suggested no structural change, while the spectral data showed a structural change around Ni(II) protoporphyrin IX in the alpha subunits. A similar situation was encountered with modified alpha 2 (Ni) beta 2 (Fe), although K1 was decreased as a result of the structural changes induced by the modifications.     

Cobalt-substituted hemoglobin Zürich (alpha 2 beta 263His leads Arg). Oxygen equilibria and EPR spectra.

Cobalt hemoglobin Zürich (alpha 2 beta 263His leads to Arg) has been successfully reconstituted from the apohemoglobin Zürich and cobaltous protoporphyrin IX. The oxygen affinity of cobalt hemoglobin Zurich, as well as that of iron hemoglobin Zürich, were measured in the absence and presence of organic phosphate and Cl-. The overall oxygen affinity of cobalt hemoglobin Zürich was found to be higher and the cooperativity as measured by the n value was smaller than those of cobalt hemoglobin A. Organic phosphate and Cl- affect the oxygen equilibrium properties of cobalt hemoglobin Zürich in a manner similar to that of cobalt hemoglobin A, but to a lesser extant than cobalt hemoglobin A. The EPR spectrum of oxy cobalt hemoglobin Zürich is less sensitive to the replacement of the buffer system from H2O to 2H2O, indicating that the hydrogen bond between the distal amino acid residue and the bound oxygen is not formed in the abnormal beta subunits. The deoxy EPR spectrum of cobalt hemoglobin Zürich is similar to that of deoxy cobalt hemoglobin A, suggesting that the deoxy cobalt hemoglobin Zürich is predominantly in the deoxy quaternary structure (T state).     

Correlation between quaternary structure and ligand dissociation kinetics for fully liganded hemoglobin.

The quaternary structures of fully liganded adult hemoglobin and hemoglobin Kansas (alpha2beta2 102 Asn-thr) bound by carbon monoxide or nitric oxide were spectroscopically characterized using high-resolution nuclear magnetic resonance (NMR) and ultraviolet circular dichroism (CD). The spectral markers used for the quarternary transition were the line in the NMR spectrum in H2O-14 ppm downfield from 2,2-dimethyl-2-silapentane-5-sulfonate and the negative peak at 285 nm in the ultraviolet CD spectrum. In the nitrosyl derivatives, these two structural markers were compared with the electron paramagnetic resonance (EPR) spectrum at room temperature for the purpose of correlating structural changes in the protein with changes at the heme...     

Oxygen equilibrium study and light absorption spectra of Ni(II)-Fe(II) hybrid hemoglobins

Ni(II)-Fe(II) hybrid hemoglobins, in which hemes in either the alpha or beta subunit are substituted with Ni(II) protoporphyrin IX, have been prepared and characterized. Since Ni(II) protoporphyrin IX binds neither oxygen nor carbon monoxide, the oxygen equilibrium properties of the Fe subunit in these hybrid hemoglobins were specifically determined. K1 values, namely the equilibrium constants for the first oxygen molecule to bind to hemoglobin, agreed well for these hybrid hemoglobins with the K1 value of native hemoglobin A in various conditions. Therefore, Ni(II) protoporphyrin IX in these hybrid hemoglobins behaves like a permanently deoxygenated heme. Both Ne-Fe hybrid hemoglobins bound oxygen non-co-operatively at low pH values. When the pH was raised, alpha 2 (Fe) beta 2 (Ni) showed co-operativity, but the complementary hybrid, alpha 2 (Ni) beta 2 (Fe), did not show co-operativity even at pH 8.5. The light absorption spectra of Ni(II)-Fe(II) hybrid hemoglobins indicated that the coordination states of Ni(II) protoporphyrin IX in the alpha subunits responded to the structure of the hybrid, whereas those in the beta subunits were hardly changed. In a deoxy-like structure (the structure that looks like that observed in deoxyhemoglobin), four-co-ordinated Ni(II) protoporphyrin IX was dominant in the alpha (Ni) subunits, while under the conditions that stabilized an oxy-like structure (the structure that looks like that observed in oxyhemoglobin), five-co-ordinated Ni(II) protoporphyrin IX increased. The small change observed in the absorption spectrum of the beta (Ni) subunits is not related to the change of the co-ordination number of Ni(II) protoporphyrin IX. Non-co-operative binding of oxygen to the beta subunits in alpha 2 (Ni) beta 2 (Fe) accompanied the change of absorption spectrum in the alpha (Ni) subunits. We propose a possible interpretation of this unique feature.     

Use of heme spin-labeling to probe heme environments of alpha and beta chains of hemoglobin.

A spin label attached to a propionic acid group of the heme has been used to probe the heme environment of the alpha and beta chains of hemoglobin in both the subunit and tetrameric forms. The electron paramagnetic resonance (EPR) studies of hemoglobin hybrids in which the spin label is attached to either the alpha- or beta-heme (alpha2SLbeta 2 or alpha2beta2SL) and spin-labeled isolated chains (alphaSL and betaSL) show that: 1) alpha- and beta-hemes have different environments in the tetrameric forms of oxy-, deoxy-, and methemoglobins as well as in isolated single chains; 2) when isolated subunits associate to form hemoglobin tetramers, the environment of the alpha-heme changes more drastically than that of the beta-heme; 3) upon deoxygenation of hemoglobin, the structure in the vicinity of the alpha-heme changes more drastically than that of the beta-heme; and 4) upon the addition of organic phosphates to methemoglobin, the change in the spin state of the heme irons mainly arises from beta-heme. The results demonstrate conclusively that the alpha and the beta subunits of hemoglobin are structurally nonequivalent as are their structural changes as the result of ligation. The relationship of EPR spectrum and structure of hemoglobin is discussed.     

Oxygen binding by alpha(Fe2+)2beta(Ni2+)2 hemoglobin crystals

Oxygen binding by hemoglobin fixed in the T state either by crystallization or by encapsulation in silica gels is apparently noncooperative. However, cooperativity might be masked by different oxygen affinities of alpha and beta subunits. Metal hybrid hemoglobins, where the noniron metal does not bind oxygen, provide the opportunity to determine the oxygen affinities of alpha and beta hemes separately. Previous studies have characterized the oxygen binding by alpha(Ni2+)2beta(Fe2+)2 crystals. Here, we have determined the three-dimensional (3D) structure and oxygen binding of alpha(Fe2+)2beta(Ni2+)2 crystals grown from polyethylene glycol solutions. Polarized absorption spectra were recorded at different oxygen pressures with light polarized parallel either to the b or c crystal axis by single crystal microspectrophotometry. The oxygen pressures at 50% saturation (p50s) are 95 +/- 3 and 87 +/- 4 Torr along the b and c crystal axes, respectively, and the corresponding Hill coefficients are 0.96 +/- 0.06 and 0.90 +/- 0.03. Analysis of the binding curves, taking into account the different projections of the alpha hemes along the optical directions, indicates that the oxygen affinity of alpha1 hemes is 1.3-fold lower than alpha2 hemes. Inspection of the 3D structure suggests that this inequivalence may arise from packing interactions of the Hb tetramer within the monoclinic crystal lattice. A similar inequivalence was found for the beta subunits of alpha(Ni2+)2beta(Fe2+)2 crystals. The average oxygen affinity of the alpha subunits (p50 = 91 Torr) is about 1.2-fold higher than the beta subunits (p50 = 110 Torr). In the absence of cooperativity, this heterogeneity yields an oxygen binding curve of Hb A with a Hill coefficient of 0.999. Since the binding curves of Hb A crystals exhibit a Hill coefficient very close to unity, these findings indicate that oxygen binding by T-state hemoglobin is noncooperative, in keeping with the Monod, Wyman, and Changeux model.     

Functional properties of the glycosylated minor hemoglobins A1a-1,A1a-2 and A1b. EPR evidence for increased stability of the low affinity quaternary structure and decreased susceptibility to organic phosphate

Electron paramagnetic resonance (EPR) spectra of the glycosylated minor hemoglobins A1a-1, A1a-2, A1b and A1c and the major hemoglobin A0 in the nitrosyl form have been obtained in the absence and presence of inositol hexaphosphate. In the absence of inositol hexaphosphate, nitrosyl hemoglobins A1a-1, A1a-2 and A1b exhibited a triplet hyperfine structure centered at g = 2.009 which has been shown to be diagnostic of the low affinity (T) quaternary structure. Addition of inositol hexaphosphate to nitrosyl hemoglobins A0, A1c, A1b and A1a-2 developed a triplet hyperfine structure of the EPR spectra but the magnitude of the hyperfine was decreased in the order of hemoglobins A0, A1c, A1b and A1a-2. However, inositol hexaphosphate had essentially no effect on the EPR spectrum of nitrosyl hemoglobin A1a-1. The present results account qualitatively for the oxygen binding properties of these glycosylated minor hemoglobins in the framework of a two-state allosteric model.     

Chain equivalence in reaction of nitric oxide with hemoglobin.

Mixtures of nitric oxide and hemoglobin were prepared in a rapid freeze apparatus and analyzed by EPR spectroscopy. Spectra from samples at various degrees of saturation showed that the two subunits bound NO at equal rates. Identical results were observed in 0.1 M phosphate at pH 6.5 and 0.1 M 2,2'-bis(hydroxymethyl)-2,2',2'-nitrilotriethanol, 0.1 M NaCl at pH 7.0, both in the presence and absence of inositol hexaphosphate at either buffer condition. At subsaturating levels of NO (less than 60%), or at all levels of saturation in the presence of inositol hexaphosphate, it was found that the EPR spectrum of nitrosylhemoglobin varied with the length of time before freezing. This change was characterized by the development of a hyperfine structure at g = 2.01 which appeared with a half-time of approximately 0.4 s. Maxwell and Caughey (Maxwell, J. C., and Caughey, W. S. (1976) Biochemistry 15, 388-395) have attributed this three-line EPR hyperfine structure to the formation of a pentacoordinate ferroheme-NO complex. Corresponding slow changes were observed in the visible absorption spectrum following the binding of low levels of NO to deoxyhemoglobin or inositol hexaphosphate to fully saturated nitrosylhemoglobin. Thus it appears that NO binding to the alpha and beta subunits of deoxyhemoglobin takes place at equal rates and, under conditions favoring the T quaternary state (low saturation, presence of inositol hexaphosphate), a further slow structural change takes place, resulting in the cleavage of the iron--proximal histidine bond.     

Xenopus laevis hemoglobin and its hybrids with hemoglobin A+

Isolated alpha and beta chains from Xenopus laevis hemoglobin have been purified. The isolation procedure yields native alpha chains whose functional behavior has been characterized and compared with that of human alpha chains. Isolated beta chains in the presence of oxygen are characterized by low stability, and hence their functional characterization was limited to the CO binding kinetics. When stoichiometric amounts of the isolated alpha and beta chains are mixed, a tetramer characterized by heme-heme interactions and oxygen affinity comparable to that of the native molecule is readily reconstituted. Moreover, both chains, under appropriate conditions, form stable hybrid tetramers with the partner subunits from human hemoglobin; results on the functional properties of these hybrid hemoglobins are presented and discussed in relation to the stereochemical model of the Root effect.     

Direct measurement of carbon monoxide bound to different subunits of hemoglobin A in solution and in red cells by infrared spectroscopy

Infrared spectra for carbon monoxide bound to alpha and beta subunits of human hemoglobin A have subunit differences near 1950 cm-1 and indicate that 92% of the alpha subunits exist in one conformer and 5% in a second conformer under conditions where 99% of the beta subunit is in only one conformation. The sum of the separated subunit spectra is equivalent to the alpha 2 beta 2 tetramer spectrum. CO infrared spectra indicate that CO displaces O2 from HbO2 in red cells or in solution preferentially at the beta subunits. The measurement of C-O stretch bands provides a direct method for characterization of ligand binding sites within intact cells.     

The interaction of nitric oxide with ascorbate oxidase.

1. The reaction of nitric oxide with oxidized and reduced ascorbate oxidase (L-ascorbate: oxygen oxidoreductase, EC 1.10.3.3) has been investigated by optical absorption measurements and electron paramagnetic resonance, and the results are compared with those of ceruloplasmin. 2. Upon anaerobic incubation of oxidized ascorbate oxidase with nitric oxide a decrease of the absorbance at 610 nm is found, which is due to an electron transfer from nitric oxide to Type-1 copper. 3. In the presence of nitric oxide the EPR absorbance of ascorbate oxidase decreases and shows predominatly a signal with characteristics of Type-2 copper (g parallel = 2.248; A parallel = 188 G), whereas the type-1 copper signal has vanished. 4. Comparison of the intensities of the EPR signals before and after NO-treatment points to the presence of one Type-2 and three Type-1 copper atoms per molecule of ascorbate oxidase. 5. It is shown that the changes in the optical and the EPR spectrum of ascorbate oxidase induced by nitric oxide are reversible. No difference in enzymic activity is found between the native enzyme and the NO-treated enzyme after removal of nitric oxide.     

Spin label studies on conformational changes of aphohemoglobin due to heme binding.

Human apohemoglobin (globin) was spin-labeled at the beta-93 sulfhydryl groups with 2,2,5,5-tetramethyl-3-aminopyrrolidine-I-oxyl. Spin-labeled globin exhibited an EPR spectra that is less immobilized than that of spin-labeled hemoglobin, indicating the conformational difference in the vicinity of the label between hemoglobin and globin. Spectrophotometric titration of spin-labeled globin with protohemin showed that 1 mol of globin (on the tetramer basis) combines with 4 mol of hemin, producing a holomethemoglobin spectrophotometrically indistinguishable from native methemoglobin. The EPR spectrum was also changed strikingly upon the addition of protohemin. This change, however, was not proportional to the amount of hemin added, but marked changes occurred after 3 to 4 mol of hemin were mixed with 1 mol of spin-labeled globin. The EPR spectrum of spin-labeled hemoglobin thus prepared was identical with that prepared by direct spin labeling to methemoglobin. These results suggest the preferential binding of hemin to alpha-globin chains in the course of heme binding by globin. This assumption was further confirmed by preparing spin-labeled semihemoglobin in which only one kind of chain contained hemin (alpha h betaO SL and alpha O beta h SL). The EPR spectrum of the alpha h beta O SL molecule showed a slightly immobilized EPR spectrum, similar to that of spin-labeled globin mixed with 50% of the stoichiometric amount of hemin. On the other hand, the alpha O beta h SL molecule showed a distinctly different EPR signal from that of globin half-saturated with hemin, and showed an intermediate spectrum between those of beta h SL and alpha h beta h SL. These results indicate that heme binding to globin chains brings about a major conformational change in the protein moiety and that chain-chain association plays a secondary role. We conclude that hemin binds preferentially to alpha-globin chains and that the conformation of globin changes rapidly to that of methemoglobin after all four hemes are attached to globin heme pockets.