Mutational analysis of phenylalanine beta 85 in the valine beta 6 acceptor pocket during hemoglobin S polymerization.

Hemoglobin (Hb) S containing Leu, Ala, Thr, or Trp substitutions at beta 85 were made and expressed in yeast in an effort to evaluate the role of Phe-beta 85 in the acceptor pocket during polymerization of deoxy Hb S. The four Hb S variants have the same electrophoretic mobility as Hb S, and these beta 85 substitutions do not significantly affect heme-globin interactions and tetramer helix content. Hb S containing Trp-beta 85 had decreased oxygen affinity, whereas those with Leu-, Ala-, and Thr-beta 85 had increased oxygen affinity. All four supersaturated beta 85 variants polymerized with a delay time as does deoxy Hb S. This is in contrast to deoxy Hb S containing Phe-beta 88, Ala-beta 88, Glu-beta 88, or Glu-beta 85, which polymerized with no clear delay time (Adachi K, Konitzer P, Paulraj CG, Surrey S, 1994, J Biol Chem 269:17477-17480; Adachi K, Reddy LR, Surrey S, 1994, J Biol Chem 269:31563-31566). Leu substitution at beta 85 accelerated deoxy Hb S polymerization, whereas Ala, Thr, or Trp substitution inhibited polymerization. The length of the delay time and total polymer formed for these beta 85 Hb S variants depended on hemoglobin concentration in the same fashion as for deoxy Hb S: the higher the concentration, the shorter the delay time and the more polymer formed. Critical concentrations required for polymerization of deoxy Hb SF veta 85L, Hb SF beta 85A, Hb SF beta 85T, and Hb SF beta 85W are 0.65-, 2.2-, 2.5- and 3-fold higher, respectively, than Hb S.(ABSTRACT TRUNCATED AT 250 WORDS)     

Internal electron transfer between hemes and Cu(II) bound at cysteine beta93 promotes methemoglobin reduction by carbon monoxide

Previous studies showed that CO/H2O oxidation provides electrons to drive the reduction of oxidized hemoglobin (metHb). We report here that Cu(II) addition accelerates the rate of metHb beta chain reduction by CO by a factor of about 1000. A mechanism whereby electron transfer occurs via an internal pathway coupling CO/H2O oxidation to Fe(III) and Cu(II) reduction is suggested by the observation that the copper-induced rate enhancement is inhibited by blocking Cys-beta93 with N-ethylmaleimide. Furthermore, this internal electron-transfer pathway is more readily established at low Cu(II) concentrations in Hb Deer Lodge (beta2His --> Arg) and other species lacking His-beta2 than in Hb A0. This difference is consistent with preferential binding of Cu(II) in Hb A0 to a high affinity site involving His-beta2, which is ineffective in promoting electron exchange between Cu(II) and the beta heme iron. Effective electron transfer is thus affected by Hb type but is not governed by the R left arrow over right arrow T conformational equilibrium. The beta hemes in Cu(II)-metHb are reduced under CO at rates close to those observed for cytochrome c oxidase, where heme and copper are present together in the oxygen-binding site and where internal electron transfer also occurs.     

Differences in changes of the alpha1-beta2 subunit contacts between ligand binding to the alpha and beta subunits of hemoglobin A: UV resonance raman analysis using Ni-Fe hybrid hemoglobin

The alpha1-beta2 subunit contacts in the half-ligated hemoglobin A (Hb A) have been explored with ultraviolet resonance Raman (UVRR) spectroscopy using the Ni-Fe hybrid Hb under various solution conditions. Our previous studies demonstrated that Trpbeta37, Tyralpha42, and Tyralpha140 are mainly responsible for UVRR spectral differences between the complete T (deoxyHb A) and R (COHb A) structures [Nagai, M., Wajcman, H., Lahary, A., Nakatsukasa, T., Nagatomo, S., and Kitagawa, T. (1999) Biochemistry, 38, 1243-1251]. On the basis of it, the UVRR spectra observed for the half-ligated alpha(Ni)beta(CO) and alpha(CO)beta(Ni) at pH 6.7 in the presence of IHP indicated the adoption of the complete T structure similar to alpha(Ni)beta(deoxy) and alpha(deoxy)beta(Ni). The extent of the quaternary structural changes upon ligand binding depends on pH and IHP, but their characters are qualitatively the same. For alpha(Ni)beta(Fe), it is not until pH 8.7 in the absence of IHP that the Tyr bands are changed by ligand binding. The change of Tyr residues is induced by binding of CO, but not of NO, to the alpha heme, while it was similarly induced by binding of CO and NO to the beta heme. The Trp bands are changed toward R-like similarly for alpha(Ni)beta(CO) and alpha(CO)beta(Ni), indicating that the structural changes of Trp residues are scarcely different between CO binding to either the alpha or beta heme. The ligand induced quaternary structural changes of Tyr and Trp residues did not take place in a concerted way and were different between alpha(Ni)beta(CO) and alpha(CO)beta(Ni). These observations directly indicate that the phenomenon occurring at the alpha1-beta2 interface is different between the ligand binding to the alpha and beta hemes and is greatly influenced by IHP. A plausible mechanism of the intersubunit communication upon binding of a ligand to the alpha or beta subunit to the other subunit and its difference between NO and CO as a ligand are discussed.     

Electron paramagnetic resonance of Hb St Louis beta28 (B10) Leu replaced by Gln.

Hemoglobin St Louis beta28 (B10) Leu replaced by Gln is a new mutant which occurs as a natural valency hybrid (alpha2beta+2), or hemoglobin M (Cohen-Solal, M., Seligmann, M., Thillet, J. and Rosa, J. (1973) FEBS Lett. 33, 37-41). The electron paramagnetic resonance (EPR) spectrum of native Hb St Louis at pH 6.2 shows a mixture of three species. Two are high spin, one with tetragonal symmetry, like Hb+ A, the other with rhombic distortion. The third is a low-spin form corresponding to a hemichrome with the distal (E7) histidine as the sixth ligand of the ferric iron. The hemichrome is also found in red blood cells. After oxidation to the alpha+2beta+2 form, three EPR species are seen. Surprisingly, there remains only one high-spin signal, with almost tetragonal symmetry. Besides the low-spin hemichrome, a hydroxy signal is observed even at pH 6.2. These observations imply interactions between the alpha and beta hemes.     

Hemoglobin-carbon monoxide binding rate. Low temperature magneto-optical detection of spin-tunneling.

The spin-tunneling model of Hb--CO binding is used to calculate the binding rate at low temperature and high magnetic fields. The rate is calculated in second order perturbation theory assuming that spin-orbit coupling mediates the Hb iron electronic state change. The reaction which occurs at the crossing of the S = 2 and S = 0 energy vs. configuration coordinate curves is nonadiabatic, having a small electronic transition matrix element. Since detection of CO binding by polarized light in the Soret band makes it possible to observe hemes at specific orientation to the field direction, the rate is calculated for arbitrary heme orientation. Comparison with measurements at low temperature in zero field is made for spin quantization along the molecular crystal field direction.     

Inhibition of hemoglobin S polymerization in vitro by a novel 15-mer EF-helix beta73 histidine-containing peptide

Our mutational studies on Hb S showed that the Hb S beta73His variant (beta6Val and beta73His) promoted polymerization, while Hb S beta73Leu (beta6Val and beta73Leu) inhibited polymerization. On the basis of these results, we speculated that EF-helix peptides containing beta73His interact with beta4Thr in Hb S and compete with Hb S, resulting in inhibition of Hb S polymerization. We, therefore, studied inhibitory effects of 15-, 11-, 7-, and 3-mer EF-helix peptides containing beta73His on Hb S polymerization. The delay time prior to Hb S polymerization increased only in the presence of the 15-mer His peptide; the higher the amount, the longer the delay time. DIC image analysis also showed that the fiber elongation rate for Hb S polymers decreased with increasing concentration of the 15-mer His peptide. In contrast, the same 15-mer peptide containing beta73Leu instead of His and peptides shorter than 11 amino acids containing beta73His including His alone showed little effect on the kinetics of polymerization and elongation of polymers. Analysis by protein-chip arrays showed that only the 15-mer beta73His peptide interacted with Hb S. CD spectra of the 15-mer beta73His peptide did not show a specific helical structure; however, computer docking analysis suggested a lower energy for interaction of Hb S with the 15-mer beta73His peptide compared to peptides containing other amino acids at this position. These results suggest that the 15-mer beta73His peptide interacts with Hb S via the beta4Thr in the betaS-globin chain in Hb S. This interaction may influence hydrogen bond interaction between beta73Asp and beta4Thr in Hb S polymers and interfere in hydrophobic interactions of beta6Val, leading to inhibition of Hb S polymerization.     

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.     

Effects of different beta73 amino acids on formation of 14-stranded fibers of Hb S versus double-stranded crystals of Hb C-Harlem

Hb S (alpha(2)beta(2)(6Glu-->Val)) forms polymers, while Hb C-Harlem (alpha(2)beta(2)(6Glu-->Val,73Asp-->Asn)) forms crystals upon oversaturation. Since the only difference between the two is the beta73 amino acid, it follows that this site is a critical determinant in promoting either polymerization or crystallization. Beta73 Asp in Hb S forms a hydrogen bond with beta4 Thr, while beta73 Asn in Hb C-Harlem may inhibit this interaction as well as increase the hydrophobicity at the EF helix beta6 Val acceptor sites. Two new beta73 Hb S variants (beta73 His and Leu) were constructed and analyzed to define other amino acids facilitating formation of Hb S-like polymers versus Hb C-Harlem-like crystals. The two variants that were chosen were expected to either (1) enhance formation of the beta73-beta4 hydrogen bond (beta73 His) or (2) inhibit it and increase the hydrophobicity of the EF helix beta6 Val acceptor sites (beta73 Leu). beta73 His Hb S formed fibers but at a lower concentration than Hb S, while beta73 Leu Hb S formed crystals but at a higher concentration than Hb C-Harlem. The solubility of beta73 His Hb S was (1)/(7) of that of Hb S, while the solubility of beta73 Leu Hb S was similar to that of Hb C-Harlem. The delay time prior to polymer or crystal formation depended on Hb concentration. The delay time for beta73 His Hb S was 10(5)-fold shorter than that for Hb S, while that for beta73 Leu Hb S was 10(5)-fold longer in 1.0 M phosphate buffer. NMR results indicate beta73 amino acid changes induce alteration in the beta-chain heme pocket region, while CD results indicate no change in the helical content of the variants. These results suggest that enhancing the beta73-beta4 hydrogen bond and/or induced changes in the heme pocket by the beta73 Asp to His change facilitate formation of Hb S-like fibers. Our results also suggest that removal of the beta73-beta4 hydrogen bond and enhancing the hydrophobicity of the EF helix beta6 Val acceptor sites by the beta73 Asp to Leu or Asn changes delay nuclei formation and facilitate formation of Hb C-Harlem-like crystals.     

Tetramer-dimer equilibrium of oxyhemoglobin mutants determined from auto-oxidation rates.

One of the main difficulties with blood substitutes based on hemoglobin (Hb) solutions is the auto-oxidation of the hemes, a problem aggravated by the dimerization of Hb tetramers. We have employed a method to study the oxyHb tetramer-dimer equilibrium based on the rate of auto-oxidation as a function of protein concentration. The 16-fold difference in dimer and tetramer auto-oxidation rates (in 20 mM phosphate buffer at pH 7.0, 37 degrees C) was exploited to determine the fraction dimer. The results show a transition of the auto-oxidation rate from low to high protein concentrations, allowing the determination of the tetramer-dimer dissociation coefficient K4,2 = [Dimer] 2/[Tetramer]. A 14-fold increase in K4,2 was observed for addition of 10 mM of the allosteric effector inositol hexaphosphate (IHP). Recombinant hemoglobins (rHb) were genetically engineered to obtain Hb with a lower oxygen affinity than native Hb (Hb A). The rHb alpha2beta2 [(C7) F41Y/(G4) N102Y] shows a fivefold increase in K4,2 at pH 7.0, 37 degrees C. An atmosphere of pure oxygen is necessary in this case to insure fully oxygenated Hb. When this condition is satisfied, this method provides an efficient technique to characterize both the tetramer-dimer equilibrium and the auto-oxidation rates of various oxyHb. For low oxygen affinity Hb equilibrated under air, the presence of deoxy subunits accelerates the auto-oxidation. Although a full analysis is complicated, the auto-oxidation studies for air equilibrated samples are more relevant to the development of a blood substitute based on Hb solutions. The double mutants, rHb alpha2beta2 [(C7) F41Y/(G4) N102A] and rHb alpha2beta2 [(C7) F41Y/(E10) K66T], show a lower oxygen affinity and a higher rate of oxidation than Hb A. Simulations of the auto-oxidation rate versus Hb concentration indicate that very high protein concentrations are required to observe the tetramer auto-oxidation rate. Because the dimers oxidize much more rapidly, even a small fraction dimer will influence the observed oxidation rate.     

Effects of amino acid substitutions at beta 131 on the structure and properties of hemoglobin: evidence for communication between alpha 1 beta 1- and alpha 1 beta 2-subunit interfaces

Substitutions of Asn, Glu, and Leu for Gln at the beta131 position of the hemoglobin molecule result in recombinant hemoglobins (rHbs) with moderately lowered oxygen affinity and high cooperativity compared to human normal adult hemoglobin (Hb A). The mutation site affects the hydrogen bonds present at the alpha(1)beta(1)-subunit interface between alpha103His and beta131Gln as well as that between alpha122His and beta35Tyr. NMR spectroscopy shows that the hydrogen bonds are indeed perturbed; in the case of rHb (beta131Gln --> Asn) and rHb (beta131Gln --> Leu), the perturbations are propagated to the other alpha(1)beta(1)-interface H-bond involving alpha122His and beta35Tyr. Proton exchange measurements also detect faster exchange rates for both alpha(1)beta(1)-interface histidine side chains of the mutant rHbs in 0.1 M sodium phosphate buffer at pH 7.0 than for those of Hb A under the same conditions. In addition, the same measurements in 0.1 M Tris buffer at pH 7.0 show a much slower exchange rate for mutant rHbs and Hb A. One of the mutants, rHb (beta131Gln --> Asn), shows the conformational exchange of its interface histidines, and exchange rate measurements have been attempted. We have also conducted studies on the reactivity of the SH group of beta93Cys (a residue located in the region of the alpha(1)beta(2)-subunit interface) toward p-mercuribenzoate, and our results show that low-oxygen-affinity rHbs have a more reactive beta93Cys than Hb A in the CO form. Our results indicate that there is communication between the alpha(1)beta(1)- and alpha(1)beta(2)-subunit interfaces, and a possible communication pathway for the cooperative oxygenation of Hb A that allows the alpha(1)beta(1)-subunit interface to modulate the functional properties in conjunction with the alpha(1)beta(2) interface is proposed.     

Flash photolytic studies of carbon monoxide binding to the ferrous chains of [Mn(II),Fe(II)] hybrid hemoglobins: kinetic mechanism for the early stages of hemoglobin ligation

Flash photolysis is employed to investigate the kinetics of CO recombination to the ferrous chains of [Mn(II),Fe(II)] hemoglobin (Hb) hybrids. At low pH (6.6), Hb remains predominantly in the T quaternary state for the first two CO ligation steps, when binding to either the alpha chains or beta chains. At elevated pH, CO binding to the alpha chains produces a larger degree of T to R conversion than binding to the beta chains, in support of earlier equilibrium measurements. This study provides the full pH dependence of the CO binding rate constants for both alpha- and beta-Fe chains within the T state and at elevated values of pH gives the R-state rate constants for the monoliganded analogues. The data can be analyzed within the context of a two-state model for Hb cooperativity, but they give clear evidence for slow quaternary structure interconversion at the monoliganded level.     

Control of heme reactivity by diffusion: structural basis and functional characterization in hemoglobin mutants.

The effect of mutagenesis on O(2), CO, and NO binding to mutants of human hemoglobin, designed to modify some features of the reactivity that hinder use of hemoglobin solutions as blood substitute, has been extensively investigated. The kinetics may be interpreted in the framework of the Monod-Wyman-Changeux two-state allosteric model, based on the high-resolution crystallographic structures of the mutants and taking into account the control of heme reactivity by the distal side mutations. The mutations involve residues at topological position B10 and E7, i.e., Leu (B10) to Tyr and His (E7) to Gln, on either the alpha chains alone (yielding the hybrid tetramer Hbalpha(YQ)), the beta chains alone (hybrid tetramer Hbbeta(YQ)), or both types of chains (Hb(YQ)). Our data indicate that the two mutations affect ligand diffusion into the pocket, leading to proteins with low affinity for O(2) and CO, and especially with reduced reactivity toward NO, a difficult goal to achieve. The observed kinetic heterogeneity between the alpha(YQ) and beta(YQ) chains in Hb(YQ) has been rationalized on the basis of the three-dimensional structure of the active site. Furthermore, we report for the first time an experiment of partial CO binding, selective for the beta chains, to high salt crystals of the mutant Hb(YQ) in the T-state; these crystallographic data may be interpreted as "snapshots" of the initial events possibly occurring on ligand binding to the T-allosteric state of this peculiar mutant Hb.     

Temperature and domain size dependence of sickle cell hemoglobin polymer melting in high concentration phosphate buffer.

Deoxygenated sickle cell hemoglobin (Hb S) in 1.8 M phosphate buffer, and carbon monoxide (CO) saturated buffer were rapidly mixed using a stopped-flow apparatus. The binding of the CO to the Hb S polymers and the polymer melting was measured by time resolved optical spectroscopy. Polymer melting was associated with decreased turbidity, and CO binding to deoxy-Hb S was monitored by observation of changes in the absorption profile. The reaction temperature was varied from 20 degrees C to 35 degrees C. Polymer domain size at 20 degrees C was also varied. The data for mixtures involving normal adult hemoglobin (Hb A) fit well to a single exponential process whereas it was necessary to include a second process when fitting data involving Hb S. The overall Hb S-CO reaction rate decreased with increasing temperature from 20 degrees C to 35 degrees C, and increased with decreasing domain size. In comparison, Hb A-CO reaction rates increased uniformly with increasing temperature. Two competing reaction channels in the Hb S-CO reaction are proposed, one involving CO binding directly to the polymer and the other involving CO only binding to Hb molecules in the solution phase. The temperature dependence of the contribution of each pathway is discussed.     

Oxygen equilibrium and EPR studies on alpha1beta1 hemoglobin dimer

We undertook this project to clarify whether hemoglobin (Hb) dimers have a high affinity for oxygen and cooperativity. For this, we prepared stable Hb dimers by introducing the mutation Trp-->Glu at beta37 using our Escherichia coli expression system at the alpha1beta2 interface of Hb, and analyzed their molecular properties. The mutant hybrid Hbs with a single oxygen binding site were prepared by substituting Mg(II) protoporphyrin for ferrous heme in either the alpha or beta subunit, and the oxygen binding properties of the free dimers were investigated. Molecular weight determination of both the deoxy and CO forms showed all these molecules to be dimers in the absence of IHP at different protein concentrations. Oxygen equilibrium measurements showed high affinity and non-cooperative oxygen binding for all mutant Hb and hybrid Hb dimers. However, EPR results on the [alpha(N)(Fe-NO)beta(M)(Mg)] hybrid showed some alpha1beta1 interactions. These results provide some clues as to the properties of Hb dimers, which have not been studied extensively owing to practical difficulties in their preparation.     

The stability of the heme-globin linkage in some normal, mutant, and chemically modified hemoglobins.

The rates and equilibria of heme exchange between methemoglobin and serum albumin were measured using a simple new spectrophotometric method. It is based on the large difference between the spectrum of methemoglobin and that of methemealbumin at pH 8-9. The rate of heme exchange was found to be independent of the albumin concentration and inversely proportional to the hemoglobin (Hb) concentration. Taken together with the finding that the rate was 10 times greater for Hb Rothschild, which is completely dissociated into alpha beta dimers and 10 times smaller for two cross-linked hemoglobins, the subunits of which cannot dissociate, this showed that the rate of dissociation of heme from alpha beta dimers is very much greater than from tetramers. Conditions were found for the attainment of an equilibrium distribution of hemes between beta globin and albumin. The equilibrium distribution ratio, R = methemealbumin/albumin/methemoglobin/apohemoglobin, for hemoglobin A was 3.4 with human and 0.005 with bovine serum albumin. Both the rates of exchange and the R values of HbS and HbF were the same as that for HbA. The equilibrium distribution ratio for Hb Rothschild was 7 times greater than that for HbA whereas that of one but not the other of the cross-linked hemoglobins was 10 times smaller. The structural bases for these differences are analyzed.     

Oxygen-linked CO2 binding to isolated beta subunits of human hemoglobin.

It is known that most of the oxygen-linked carbamate which is formed in normal adult human hemoglobin (Hb A) is confined to the beta subunits rather than to the alpha subunits. In order to find out if similar differences exist in the isolated protomers of Hb A we have measured the effect of various pressures of carbon dioxide (pCO2) on the oxygen affinity in the following heme pigments: isolated alpha and beta subunits with free --SH groups (alphaSH, betaSH), mercurated beta subunits (betaPMB), myoglobin (Mb), and betaSH/PLP in which the terminal alpha-amino group of betaSH was irreversibly blocked with pyridoxal phosphate (PLP). Similar measurements were done on Hb A and the fraction of oxygen-linked carbamate calculated from the effect of pCO2 (at constant pH) on the oxygen half-saturation pressure (p50). A distinct influence of CO2 on p50 was observed in betaSH which was absent in betaSH/PLP and thus indicates that the terminal alpha-amino group mediates the oxygen-linked binding of CO2 in betaSH as it does in the beta subunits of Hb A. However, the fraction of oxygen-linked carbamate was much less dependent on pH and pCO2 in betaSH than in Hb A. Neither alphaSH, betaPMB, or Mb, all of which are known to exist largely or wholly as monomers but have free terminal alpha-amino groups, showed a shift of p50 upon addition of CO2. As both betaSH and betaSH/PLP were shown to be tetrameric molecules, we conclude from this study that homotetramers composed of isolated beta subunits do exhibit a reciprocal interaction between the binding of O2 and CO2.     

Quaternary interactions in hemoglobin beta subunit tetramers. Kinetics of ligand binding and self-assembly

We have investigated the rates of monomer in equilibrium with tetramer self-association of oxygenated beta SH subunits of human hemoglobin A as well as the influence of self-association on the binding kinetics for O2 and CO. A 4 beta in equilibrium with 2 beta 2 in equilibrium with beta 4 assembly pathway can be used to describe the association equilibria and kinetics. We have determined all four elementary rate constants for this assembly pathway at 15 degrees C in 0.1 M Tris-HCl, 0.1 M NaCl, 1 mM Na2EDTA, pH 7.4. These data imply that a significant amount (approximately 17%) of beta 2 can be present. Laser photolysis kinetic studies of O2 binding indicate that the O2 association rate constant is unaffected by the degree of self-association. In contrast, photolysis of beta CO solutions shows an overall rate of CO binding that increases at higher protein concentrations. These data are consistent with a concentration-dependent equilibrium between two protein species with CO association rates differing by a factor of 2.5, but they do not appear to be compatible with a direct assignment of different CO binding rates to the different assembly states. Rather, we believe the data imply that CO binding to beta oligomers is heterogeneous, with both a fast binding and a slow binding form being present in single association states. The fast binding form predominates (approximately equal to 87%) in beta 4, while the beta monomer has very little or none of the fast binding form. We propose that the slow binding component within beta 4 may be those subunits with rotationally disordered hemes (La Mar, G. N., Yamamoto, Y., Jue, T., Smith, K. M., and Pandey, R. K. (1985) Biochemistry 24, 3826-3831). The implications of these findings for the use of isolated subunits as models for the subunits within "R state" hemoglobin tetramers are discussed.     

Involvement of the distal histidine in the low affinity exhibited by Hb Chico (Lys beta 66----Thr) and its isolated beta chains.

Hemoglobin (Hb) Chico (Lys beta 66----Thr at E10) has a diminished oxygen affinity (Shih, D. T.-b., Jones, R. T., Shih, M. F.-C., Jones, M. B., Koler, R. D., and Howard, J. (1987) Hemoglobin 11, 453-464). Our studies show that its P50 is about twice that of Hb A and that its cooperativity, anion, and Bohr effects between pH 7 and 8 are normal. The Bohr effect above pH 8 is somewhat reduced, indicating a small but previously undocumented involvement of the ionic bond formed by Lys beta 66 in the alkaline Bohr effect. Since the oxygen affinity of the alpha-hemes is likely to be normal, that of the beta-hemes in the tetramer is likely to be reduced by the equivalent of 1.2 kcal/mol beta-heme in binding energy. Remarkably, both initial and final stages of oxygen binding to Hb Chico are of lowered affinity relative to Hb A under all conditions examined. The isolated beta chains also show diminished oxygen affinity. In T-state Hb A, Lys(E10 beta) forms a salt bridge with one of the heme propionates, but comparison with other hemoglobin variants shows that rupture of this bridge cannot be the cause of the low oxygen affinity. X-ray analysis of the deoxy structure has now shown that Thr beta 66 either donates a hydrogen bond to or accepts one from His beta 63 via a bridging water molecule. This introduces additional steric hindrance to ligand binding to the T-state that results in slower rates of ligand binding. We measured the O2/CO partition coefficient and the kinetics of oxygen dissociation and carbon monoxide binding and found that lowered O2 and CO affinity is also exhibited by the R-state tetramers and the isolated beta chains of Hb Chico.     

Isolation and functional characterization of hemoglobin Casper: beta106(G8) Leu replaced by Pro.

Hemoglobin Casper (beta106Leu replaced by Pro) can be separated from hemoglobin (Hb) A by isoelectric focusing on polyacrylamide gel. This abnormal hemoglobin was estimated to be 30% of teh total by both isoelectric focusing and heat lability kinetics. Its oxygen equilibrium curves indicate a high oxygen affinity, low degree of subunit interaction, and a decreased Bohr effect. Mixtures of Hb Casper and Hb A appear to bind oxygen as if no hybrid molecules exist.