Resonance raman studies of heme structural differences in subunits of deoxy hemoglobin

Low frequency resonance Raman (RR) spectra are reported for deoxy hemoglobin (Hb), its isolated subunits, its analogue bearing methine-deuterated hemes in all four subunits (Hb-d(4)), and the hybrids bearing the deuterated heme in only one type of subunit, which are [alpha(d4)beta(h4)](2) and [alpha(h4)beta(d4)](2). Analyzed collectively, the spectra reveal subunit-specific modes that conclusively document subtle differences in structure for the heme prosthetic groups in the two types of subunits within the intact tetramer. Not surprisingly, the most significant spectral differences are observed in the gamma(7) mode that has a major contribution from out of plane bending of the methine carbons, a distortion that is believed to relieve strain in the high-spin heme prosthetic groups. The results provide convincing evidence for the utility of selectively labeled hemoglobin hybrids in unraveling the separate subunit contributions to the RR spectra of Hb and its various derivatives and for thereby detecting slight structural differences in the subunits.     

The crystal structure of bar-headed goose hemoglobin in deoxy form: the allosteric mechanism of a hemoglobin species with high oxygen affinity

The crystal structure of a high oxygen affinity species of hemoglobin, bar-headed goose hemoglobin in deoxy form, has been determined to a resolution of 2.8 A. The R and R(free) factor of the model are 0.197 and 0.243, respectively. The structure reported here is a special deoxy state of hemoglobin and indicates the differences in allosteric mechanisms between the goose and human hemoglobins. The quaternary structure of the goose deoxy hemoglobin shows obvious differences from that of human deoxy hemoglobin. The rotation angle of one alphabeta dimer relative to its partner in a tetramer molecule from the goose oxy to deoxy hemoglobin is only 4.6 degrees, and the translation is only 0.3 A, which are much smaller than those in human hemoglobin. In the alpha(1)beta(2) switch region of the goose deoxy hemoglobin, the imidazole ring of His beta(2)97 does not span the side-chain of Thr alpha(1)41 relative to the oxy hemoglobin as in human hemoglobin. And the tertiary structure changes of heme pocket and FG corner are also smaller than that in human hemoglobin. A unique mutation among avian and mammalian Hbs of alpha119 from proline to alanine at the alpha(1)beta(1 )interface in bar-headed goose hemoglobin brings a gap between Ala alpha119 and Leu beta55, the minimum distance between the two residues is 4.66 A. At the entrance to the central cavity around the molecular dyad, some residues of two beta chains form a positively charged groove where the inositol pentaphosphate binds to the hemoglobin. The His beta146 is at the inositol pentaphosphate binding site and the salt-bridge between His beta146 and Asp beta94 does not exist in the deoxy hemoglobin, which brings the weak chloride-independent Bohr effect to bar-headed goose hemoglobin.     

A study on the quaternary structure change of hemoglobin in the ligation process

In order to inquire into the molecular mechanism underlying the cooperative ligand binding to hemoglobin (Hb), conformational interaction at the interfaces between subunits are investigated on the basis of the atomic coordinates of human deoxy and human carbonmonoxy Hbs. Hypothetical intermediate structures are used, each of which is obtained from the procedure where one or more subunits in deoxy Hb are replaced by the corresponding CO-liganded subunits in carbonmonoxy Hb using the method of superimposition of two sets of atomic coordinates. When either alpha or beta subunit is substituted with the corresponding subunit in carbonmonoxy Hb, serious steric hindrances are produced between alpha 1FG4(92)Arg and beta 2C3(37)Trp or between alpha 1C6(41)Thr and beta 2FG4(97)His, all of which belong to the allosteric core affected directly by ligand binding. These steric hindrances become more serious when both alpha 1(alpha 2) and beta 2(beta 1) subunits are substituted. Therefore the change in the relative distance between iron atom and porphyrin by ligation results in strain in the C-terminal residues as an effect of the steric hindrance between the FG and C segments. However, no steric hindrance can be seen between subunits when the subunits in carbonmonoxy Hb are substituted with the corresponding subunits in deoxy Hb. The nature of the quaternary structural change from liganded to deoxy Hb seems to be different from that from deoxy to liganded Hb.     

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.     

X-ray diffraction studies of a partially liganded hemoglobin, [alpha(FeII-CO)beta(MnII)]2

We have applied single-crystal X-ray diffraction methods to analyze the structure of [alpha(FeII-CO)beta(MnII)]2, a mixed-metal hybrid hemoglobin that crystallizes in the deoxyhemoglobin quaternary structure (the T-state) even though it is half liganded. This study, carried out at a resolution of 3.0 A, shows that (1) the Mn(II)-substituted beta subunits are structurally isomorphous with normal deoxy beta subunits, and (2) CO binding to the alpha subunits induces small, localized changes in the T-state that lack the main directional component of the corresponding larger structural changes in subunit tertiary structure that accompany complete ligand binding to all four subunits and the deoxy to oxy quaternary structure change. Specifically, in the T-state, CO binding to the alpha heme group draws the iron atom toward the heme plane, and this in turn pulls the last turn of the F helix (residues 85 through 89) closer to the heme group. The direction of these small movements is almost perpendicular to the axis of the F helix. In contrast, when the structures of fully liganded and deoxyhemoglobin are compared, extensive structural changes occur throughout the F helix and FG corner, and the main component of the atomic movements in the F helix (in addition to the smaller component toward the heme) is in a direction parallel to the heme plane and toward the alpha 1 beta 2 interface. These findings are discussed in terms of the current stereochemical theories of co-operative ligand binding and the Bohr effect.     

Assessment of the alpha 1 beta 2 contact structure of valency hybrid hemoglobins by ultraviolet difference spectra

We have developed a rapid and useful method for purification of valency hybrid hemoglobins (alpha 2+ beta 2 and alpha 2 beta 2+: + denotes ferric heme) from a hemoglobin solution oxidized partially with ferricyanide by preparative high-performance liquid chromatography. This method does not involve the separation of hemoglobin subunits and the reconstitution of ferric and partner ferrous subunits. Using the valency hybrid hemoglobins thus prepared, the effect of the ferric spin state on the alpha 1 beta 2 subunit boundary structure was investigated by measuring the ultraviolet difference absorption spectra between the deoxy and the oxy valency hybrids associated with various ferric ligands (fluoride, aquo, azide and cyanide). All derivatives of both alpha 2+ beta 2 and alpha 2 beta 2+ showed the difference spectra characteristic of R-T quaternary structural transition. However, the magnitude of the difference spectral peak observed near 288 nm was larger for high-spin derivatives than for low-spin ones. The magnitude of the peak for the valency hybrid hemoglobin was closely correlated with the difference in the free energy of oxygen binding between the R and T states. Since the R state of high-spin hybrids is considered to be identical to that of low-spin hybrids, we concluded from these results that the alpha 1 beta 2 subunit boundary structure plays an important role in regulating the oxygen affinity of deoxy T state.     

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.     

Temperature dependent spectral changes of iron and nickel hemoglobins and their derivatives

Temperature dependent absolute and difference spectra for deoxy and oxy human hemoglobin, alpha and beta subunits, NiHbA, carboxypeptidase A treated deoxy HbA and NiHbA have been investigated. It is shown for the first time that the alpha subunits are mainly responsible for the temperature dependent spectral changes in the absorption spectra of Hb in the range from 0 degrees C to 40 degrees C. It has also been found that in the R state the spectral alterations caused by temperature variation are about 85% of those found for the T state of Hb. The value of following the temperature dependence of the porphyrin bands of hemoproteins, as a sensitive probe for subtle changes in the region of the heme, is demonstrated.     

Nuclear magnetic resonance study of the isotope exchange of the proximal histidyl ring labile protons in hemoglobin A. The exchange rates and mechanisms of individual subunits in deoxy and oxy-hemoglobin

Proton nuclear magnetic resonance spectroscopy has been used to investigate the rates and mechanism of exchange with deuterium of the proximal histidyl imidazole labile ring proton in deoxy and oxy-hemoglobin A. The resolved signals for the two subunits indicate dynamic heterogeneity, with the exchange rate always faster in the alpha than the beta subunits, suggesting a lower dynamic stability for the alpha subunit. The activation energy for the exchange in both subunits (approximately 25 kcal; 1 cal = 4.184 J) indicates that exchange proceeds via an intermediate far from denaturation or global unfolding. The pH profiles for both hemoglobin states reflect the EX2 mechanism for both subunits. While the base catalysis expected for an iron-bound imidazole is observed in all cases, there are important differences in both rates and mechanisms between the subunits. In deoxy-hemoglobin, both base-catalyzed and water-assisted exchange contribute to the alpha subunit, but only the former to the beta subunit. For oxy-hemoglobin, the base-catalysis is retained for both subunits, but the slope is considerably less for the alpha relative to the beta subunit. Thus the two subunits in the two states of hemoglobin differ both in mechanisms and in the inherent dynamic stability reflected in any one mechanism. The relationships of the proximal histidyl ring NH exchange rates to previously characterized subsets of allosterically responsive protons in hemoglobin A is briefly discussed.     

Proton nuclear magnetic resonance and biochemical studies of oxygenation of human adult hemoglobin in deuterium oxide.

The proton nuclear magnetic resonance spectrum of human adult deoxyhemoglobin in D2O in the region from 6 to 20 ppm downfield from the proton resonance of residual water shows a number of hyperfine shifted proton resonances that are due to groups on or near the alpha and beta hemes. The sensitivity of these resonances to the ligation of the heme groups and the assignment of these resonances to the alpha and beta chains provide an opportunity to investigate the cooperative oxygenation of an intact hemoglobin molecule in solution. By use of the nuclear magnetic resonance correlation spectroscopy technique, at least two resonances, one at approximately 18 ppm downfield from HDO due to the beta chain and the other at approximately 12 ppm due to the alpha chain, can be used to study the binding of oxygen to the alpha and beta chains of hemoglobin. The present results using approximately 12% hemoglobin concentration in 0.1 M Bistris buffer at pD 7 and 27 degrees C with and without organic phosphate show that there is no significant line broadening on oxygenation (from 0 to 50% saturation) to affect the determination of the intensities or areas of these resonances. It is found that the ratio of the intensity of the alpha-heme resonance at 12 ppm to that of the beta-heme resonance at 18 ppm is constant on oxygenation in the absence of organic phosphate but decreases in the presence of 2,3-diphosphoglycerate or inositol hexaphosphate, with the effect of the latter being the stronger. On oxygenation, the intensities of the alpha-heme resonance at 12 ppm and of the beta-heme resonance at 18 ppm decreases more than the total number of deoxy chains available as measured by the degree of O2 saturation of hemoglobin. This shows the sensitivity of these resonances to structural changes which are believed to occur in the unligated subunits upon the ligation of their neighbors in an intact tetrameric hemoglobin molecule. A comparison of the nuclear magnetic resonance data with the populations of the partially saturated hemoglobin tetramers (i.e., hemoglobin with one, two, or three oxygen molecules bound) leads to the conclusion that in the presence of organic phosphate the hemoglobin molecule with one oxygen bound maintains the beta-heme resonance at 18 ppm but not the alpha-heme resonance at 12 ppm. These resluts suggest that some cooperativity must exist in the deoxy quaternary structure of the hemoglobin molecule during the oxygenation process. Hence, these results are not consistent with the requirements of two-state concerted models for the oxygenation of hemoglobin. In addition, we have investigated the effect of D2O on the oxygenation of hemoglobin by measuring the oxygen dissociation curves of normal adult hemoglobin as a function of pH in D2O andH2O media. We have found that (1) the pH dependence of the oxygen equilibrium of hemoglobin (the Bohr effect) in higher pH in comparison to that in H2O medium and (2) the Hill coefficients are essentially the same in D2O and H2O media over the pH range from 6.0 to 8.2...     

High pressure NMR studies of hemoproteins. The effect of pressure on the tertiary and quaternary structures of human adult ferrous hemoglobin

The effect of pressure on the tertiary and quaternary structures of human oxy, carbonmonoxy, and deoxyhemoglobin was examined by high pressure NMR spectroscopy at 300 MHz. The increased pressure displaced the ring current-shifted gamma 1-methyl resonance of beta E11 valine for oxy- and carbonmonoxyhemoglobin to the upfield side, whereas that of the alpha subunit was insensitive to pressure. Such a preferential pressure-induced upfield shift for the beta E11 valine gamma 1-methyl signal was also encountered for the isolated carbonmonoxy beta chain. For deoxyhemoglobin, hyperfine shifted resonances of the heme peripheral proton groups and the proximal histidyl NH proton for the beta subunit were pressure-dependent, in contrast to the pressure-insensitive responses for these resonances of the alpha subunit. These results indicate the structural nonequivalence of the pressure-induced structural changes in the alpha and beta subunits of hemoglobin. The exchangeable proton resonances due to the intra- and intersubunit hydrogen bonds which have been used as the oxy and deoxy quaternary structural probes were not changed upon pressurization. From all of above results, it was concluded that pressure induces the tertiary structural change preferentially at the beta heme pocket of the ferrous hemoglobin derivatives with the quaternary structure retained.     

Electron transfer kinetics between hemoglobin subunits

The kinetics for electron transfer have been measured for samples of hemoglobin valency hybrids with initially one type of subunit, alpha or beta, in the oxidized state. Incubation of these samples under anaerobic conditions tends to randomize the type of subunit that is oxidized. With a time coefficient of a few hours at pH 7, 25 degrees C, the Hb solution (0.1 mm heme) approaches a form with about 60% of beta chains reduced, indicating a faster transfer rate in the direction alpha to beta. There was no observable electron transfer for samples saturated with oxygen. The electron transfer occurs predominantly between deoxy and aquo-met subunits, both high spin species. Furthermore, electron transfer does not depend on the quaternary state of hemoglobin. Incubation of oxidized cross-linked tetramer Hb A with deoxy Hb S also displayed electron transfer, implying a mechanism via inter-tetramer collisions. A dependence on the overall Hb concentration confirms this mechanism, although a small contribution of transfer between subunits of the same tetramer cannot be ruled out. These results suggest that in vivo collisions between the Hb tetramers will be involved in the relative distribution of the methemoglobin between subunits in association with the reductase system present in the erythrocyte.     

Functional divergence prediction from evolutionary analysis: a case study of vertebrate hemoglobin

It is a central assumption of evolution that gene duplications provide the genetic raw material from which to create proteins with new functions. The increasing availability in multigene family sequences that has resulted from genome projects has inspired the creation of novel in silico approaches to predict details of protein function. The underlying principle of all such approaches is to compare the evolutionary properties of homologous sequence positions in paralogous proteins. It has been proposed that the positions that show switches in substitution rate over time-i.e., "heterotachous sites," are good indicators of functional divergence. Here, we analyzed the alpha and beta paralogous subunits of hemoglobin in search for such signatures. We found as many heterotachous sites in comparisons between groups of paralogous subunits (alpha/beta) as between orthologous ones (alpha/alpha, beta/beta). Thus, the importance of substitution rate shifts as predictors of specialization between protein subfamilies might be reconsidered. Instead, such shifts may reflect a more general process of protein evolution, consistent with the fact that they can be compatible with function conservation. As an alternative, we focused on those residues showing highly constrained states in two sequence groups, but different in each group, and we named them CBD (for "constant but different"). As opposed to heterotachous positions, CBD sites were markedly overrepresented in paralogous (alpha/beta) comparisons, as opposed to orthologous ones (alpha/alpha, beta/beta), identifying them as likely signatures of functional specialization between the two subunits. When superimposed onto the three-dimensional structure of hemoglobin, CBD positions consistently appeared to cluster preferentially on inter-subunit surfaces, two contact areas crucial to function in vertebrate tetrameric hemoglobin. The identification and analysis of CBD sites by complementing structural information with evolutionary data may represent a promising direction for future studies dealing with the functional characterization of a growing number of multigene families identified by complete genome analyses.     

High resolution NMR studies of histidine-substituted and histidine-perturbed hemoglobin variants. Histidine assignments, electrostatic interactions at the protein surface, and implications for hemoglobin S polymerization

The aromatic region of the proton NMR spectrum of human adult hemoglobin (HbA) contains resonances from at least 11 titratable histidine residues. Assignments for five beta chain histidines have previously been proposed. In order to further characterize the aromatic spectra of HbA we studied 11 histidine-substituted and -perturbed hemoglobin variants in oxy and deoxy states and at different pH values by 400 MHz NMR spectroscopy. We propose assignments for the resonances corresponding to the C2 protons of His alpha 20, His alpha 72, His alpha 112, and His beta 77 in oxy and deoxy spectra and of His beta 97 and His beta 117 in deoxy spectra. Our assignments for His beta 2 and His beta 117 in the oxy state agree with those previously reported for the CO form, but in the deoxy state our spectra suggest a different assignment. Studies with Hb variants in which a histidine is perturbed by a neighboring substitution suggest additional assignments for His alpha 50 and His alpha 89 and demonstrate a strong dependence of the imidazole ring pK on hydrogen bond interactions and on the net charge of neighboring residues. Some of the newly proposed assignments of histidine resonances are used to discuss specific intermolecular interactions implicating His alpha 20, His beta 77, and His beta 117 in deoxy HbS polymers.     

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).     

Site-directed mutations of human hemoglobin at residue 35beta: a residue at the intersection of the alpha1beta1, alpha1beta2, and alpha1alpha2 interfaces

Because Tyr35beta is located at the convergence of the alpha1beta1, alpha1beta2, and alpha1alpha2 interfaces in deoxyhemoglobin, it can be argued that mutations at this position may result in large changes in the functional properties of hemoglobin. However, only small mutation-induced changes in functional and structural properties are found for the recombinant hemoglobins betaY35F and betaY35A. Oxygen equilibrium-binding studies in solution, which measure the overall oxygen affinity (the p50) and the overall cooperativity (the Hill coefficient) of a hemoglobin solution, show that removing the phenolic hydroxyl group of Tyr35beta results in small decreases in oxygen affinity and cooperativity. In contrast, removing the entire phenolic ring results in a fourfold increase in oxygen affinity and no significant change in cooperativity. The kinetics of carbon monoxide (CO) combination in solution and the oxygen-binding properties of these variants in deoxy crystals, which measure the oxygen affinity and cooperativity of just the T quaternary structure, show that the ligand affinity of the T quaternary structure decreases in betaY35F and increases in betaY35A. The kinetics of CO rebinding following flash photolysis, which provides a measure of the dissociation of the liganded hemoglobin tetramer, indicates that the stability of the liganded hemoglobin tetramer is not altered in betaY35F or betaY35A. X-ray crystal structures of deoxy betaY35F and betaY35A are highly isomorphous with the structure of wild-type deoxyhemoglobin. The betaY35F mutation repositions the carboxyl group of Asp126alpha1 so that it may form a more favorable interaction with the guanidinium group of Arg141alpha2. The betaY35A mutation results in increased mobility of the Arg141alpha side chain, implying that the interactions between Asp126alpha1 and Arg141alpha2 are weakened. Therefore, the changes in the functional properties of these 35beta mutants appear to correlate with subtle structural differences at the C terminus of the alpha-subunit.     

Molecular determinants of glycine receptor subunit assembly.

The inhibitory glycine receptor (GlyR) is a pentameric transmembrane protein composed of homologous alpha and beta subunits. Single expression of alpha subunits generates functional homo-oligomeric GlyRs, whereas the beta subunit requires a co-expressed alpha subunit to assemble into hetero-oligomeric channels of invariant stoichiometry (alpha(3)beta(2)). Here, we identified eight amino acid residues within the N-terminal region of the alpha1 subunit that are required for the formation of homo-oligomeric GlyR channels. We show that oligomerization and N-glycosylation of the alpha1 subunit are required for transit from the endoplasmic reticulum to the Golgi apparatus and later compartments, and that addition of simple carbohydrate side chains occurs prior to GlyR subunit assembly. Our data are consistent with both intersubunit surface and conformational differences determining the different assembly behaviour of GlyR alpha and beta subunits.     

Structure dynamics of the hemoglobin mutants Hb H?tel Dieu, HbG Philadelphia, HbJ Mexico, Hb St. Mandé and Hb San Diego, studied by nanosecond-laser-flash photolysis

The kinetics of the change from the carboxy to the deoxy conformation of the mutated hemoglobins mentioned in the title and of normal human adult hemoglobin were determined from measurements of light absorption changes occurring up to 50 microseconds after nanosecond-laser photodissociation of the corresponding CO complexes. The spectral evolution of the mutated hemoglobins was found to be similar in its main features to that of normal hemoglobin. The kinetics could be decomposed into two phases with rates 1.1-1.8 x 10(6) s-1 and 0.17-0.34 x 10(6) s-1 (except Hb St. Mandé which displayed only the faster phase). Study of the mutated subunits of HbJ Mexico (alpha subunit) and Hb H?tel Dieu (beta subunit) showed that they convert exponentially to the stable deoxy state after photodeligation at the same rates as the corresponding subunits of normal Hb: 1.1 x 10(6) s-1 (alpha) and 0.3 x 10(6) s-1 (beta). The results indicate that there is no direct correlation between the kinetics of spectral relaxation in the time range studied and the oxygenation properties for these hemoglobins. However, there is some indication that the kinetics are dependent upon the region of mutation.     

The assignment of carbon monoxide association rate constants to the alpha and beta subunits in native and mutant human deoxyhemoglobin tetramers

The association kinetics of CO binding to site-directed mutants of human deoxyhemoglobin were measured by stopped-flow rapid mixing techniques at pH 7.0, 20 degrees C. Hemoglobin tetramers were constructed from one set of native subunits and one set of mutated partners containing His(E7) to Gly, Val(E11) to Ala, or Val(E11) to Ile substitutions. The reactivity of beta Cys93 with p-hydroxymercuribenzoate was measured to ensure that the mutant deoxyhemoglobins were capable of forming T-state quaternary conformations. Time courses for the complete binding of CO were measured by mixing the deoxygenated proteins with a 5-fold excess of ligand in the absence and presence of inositol hexaphosphate. Association rate constants for the individual alpha and beta subunits in the T-state conformation were assigned by measuring time courses for the reaction of a small, limiting amount of CO with a 20-fold excess of deoxyhemoglobin (i.e. Hb4 + CO----Hb4(CO)). The effects of the E7 and E11 mutations in T-state alpha subunits were qualitatively similar to those observed for the same subunit in the R-state (Mathews, A.J., Rohlfs, R.J., Olson, J.S., Tame, J., Renaud, J-P., and Nagai, K. (1989) J. Biol. Chem. 264, 16573-16583). The alpha His58(E7) to Gly and Val62(E11) to Ala substitutions caused 80- and 3-fold increases, respectively, in k'CO for T-state alpha subunits, and the alpha Val62(E11) to Ile mutation caused a 3-fold decrease. The beta His63(E7) to Gly and Val67(E11) to Ala substitutions produced 70- and 8-fold increases, respectively, in k'CO for T-state beta subunits whereas these same mutations caused little effect on the rate of CO binding to R-state beta subunits. The beta Val67(E11) to Ile mutation produced the same large effect, a 23-fold reduction in k'CO, in both quaternary conformations of beta subunits. These kinetic results can be interpreted qualitatively in terms of differences between the alpha and beta subunits in the deoxy and liganded crystal structures of human hemoglobin (Perutz, M.F. (1990) Annu. Rev. Physiol. 52, 1-25). Both the structural and functional data suggest that the distal portion of the beta heme pocket is tightly packed in deoxyhemoglobin whereas the CO binding site in R-state beta subunits is much more open. In contrast, the distal portion of the alpha heme pocket is restricted sterically in both quaternary states.(ABSTRACT TRUNCATED AT 400 WORDS)     

Proton nuclear magnetic resonance studies of hemoglobin Malm?: implications of mutations at homologous positions of the alpha and beta chains.

The abnormal human hemoglobin Malm? (beta97FG4 His leads to Gln) has been studied and its properties are compared with those of normal adult hemoglobin A. The data presented here show that the ring-current shifted proton resonances of both HbCO and HbO2 Malm? are very different from the corresponding forms of Hb A. The hyperfine shifted proton resonances of deoxy-Hb Malm? do not differ drastically from those of deoxy-Hb A. This result, together with the finding that the exchangeable proton resonances of the deoxy form of the two hemoglobins are similar, suggests that unliganded Hb Malm? can assume a deoxy-like quaternary structure both in the absence and presence of organic phosphates We have also compared the properties of Hb Malm? with those of Hb Chesapeake (alpha92FG4 Arg leads to Leu). This allows us to study the properties of two abnormal human hemoglobins with mutations at homologous positions of the alpha and beta chains in the three-dimenstional structure of the hemoglobin molecule. Our present results suggest that the mutaion at betaFG4 has its greatest effect on the teritiary structure of the heme pocket of the liganded forms of the hemoglobin while the mutation at alphaFG4 alters the deoxy structure of the hemoglogin molecule but does not alter the teriary structure of the heme pockets of the liganded form of the hemoglobin molecule. Both hemoglobins undergo a transition from the deoxy (T) to the oxy (R) quaternary structure upon ligation. The abnormally high oxygen affinities and low cooperativities of these two hemoglobins must therefore be due to either the structural differences which we have observed and/or to an altered transition between the T and R structures.