Carbon monoxide binding to the ferrous chains of [Mn,Fe(II)] hybrid hemoglobins: pH dependence of the chain affinity constants associated with specific hemoglobin ligation pathways

In mixed-metal [Mn,Fe] hybrid hemoglobins (Hb), the two chains of a single type, alpha or beta, are substituted with manganese protoporphyrin IX, which does not bind CO in either the Mn(II) or Mn(III) valency states. Thus, CO binding by the two ferrous subunits of a hybrid with Mn of either valency represents a simplified two-step Hb ligation process in which ligands bind to a single-chain type. Considering the [Mn(II),Fe(II)] hybrids, which are deoxy T-state analogues, at pH 6.6 both types bind CO with low affinity (alpha-Fe, 0.38 mmHg; beta-Fe, 0.71 mmHg) and noncooperatively (Hill coefficient n = 1). At elevated pH, both exhibit an increase in affinity (Bohr effect) and strong cooperativity, with the alpha-Fe hybrid having a higher degree of cooperativity (n approximately equal to 1.6) than beta-Fe (approximately equal to 1.3) at pH 9.0. The CO association constants for the Hb ligation routes in which the first two ligands bind to the same chain type are obtained from these measurements, and their pH dependence provides estimates of the proton release at each step. Through studies of CO on- and off-rates, the [Mn(III),Fe(II)] hybrids are used to obtain the pH dependence of the association constants for binding the fourth CO to the individual Hb chains.(ABSTRACT TRUNCATED AT 250 WORDS)     

31P-NMR investigation of trimethylphosphine binding to [alpha Fe(II), beta Mn(II)] hybrid hemoglobin. A model for partially liganded species

31P-NMR of trimethylphosphine binding to the ferrous chains of a ([alpha Fe(II), beta Mn(II)]hemoglobin hybrid is employed to investigate partially liganded species. This study shows that at low pH (6.5), in the presence of inositol hexaphosphate, the resonance at 23.2 ppm (from H3PO4) is due to phosphine bonding to alpha-chains in the T quaternary state. At elevated pH (7.6), phosphine binding to the alpha-chains produces a resonance at 24.8 ppm which is associated with a T-to-R conversion. These findings are discussed in relation with our previous results on direct observation of intermediate ligation states of hemoglobin.     

Double-mixing kinetic studies of the reactions of monoliganded species of hemoglobin: alpha 2(CO)1 beta 2 and alpha 2 beta 2(CO)1.

The kinetics of CO association to and dissociation from the two isomers of monoliganded species alpha ICO beta I(alpha II beta II) and alpha I beta I (alpha II beta COII) has been studied by double-mixing stopped-flow and microperoxidase methods. The monoliganded species were generated by hybridization between excess ferric Hb and alpha CO2 beta +2 or alpha +2 beta CO2 prepared by high-pressure liquid chromatography (HPLC). The results indicated that: 1) there were no significant differences in the reactivities of alpha and beta chains in the first step of ligation; 2) in the second step of ligation there was significant cooperativity in the reaction of deoxyhemoglobin with 0.05 or 0.1 equivalent of CO. Diliganded species were therefore formed in significant amounts. The double-mixing HPLC results suggested that in the second step of ligation alpha chains reacted faster than the beta chains, and the main diliganded species formed was alpha I beta ICO (alpha IICO beta II) or its isomer alpha ICO I(alpha II beta IICO). These results seem to indicate that the reaction of the first CO is mostly random and in the second step of ligation CO binds more to the tetramers in which one beta chain is already ligated: alpha I beta I (alpha II beta II) + CO----alpha ICO beta I (alpha II beta II) and alpha I beta ICO (alpha II beta II) + CO----alpha I beta ICO (alpha IICO beta II).     

Allosteric kinetics and equilibria of triligated, cross-linked hemoglobin.

Using modulated excitation, we have measured the forward and reverse rates of the allosteric transition between relaxed (R) and tense (T) quaternary structures for triply ligated hemoglobin (Hb), cross-linked between the alpha chains at Lys 99. Oxygen, carbon monoxide, and water were used as ligands and were studied in phosphate and low Cl- bis-Tris buffers at neutral pH. Since the cross-link prohibits disproportionation, triply ligated aquomet Hb species with ferrous beta chains were specifically isolated by isoelectric focusing. Modulated excitation provides rate pairs and therefore gives equilibrium constants between quaternary structures. To coordinate with that information, oxygen binding curves of fully ferrous and tri-aquomet Hb were also measured. L3, the equilibrium constant between three liganded R and T structures, is determined by modulated excitation to be of order unity for O2 or CO (1.1 to 1.5 for 3O2 and 0.7 for 3CO bound), while with three aquomet subunits it is much greater (> or = 23). R-->T conversion rates are similar to those found for HbA, with weak sensitivity to changes in L3. The L3 values from HbXL O2 were used to obtain a unique allosteric decomposition of the ferrous O2 binding curve in terms of KT, KR, and L3. From these values and the O2 binding curve of tri-aquomet HbXL, L3 was calculated to be 2.7 for the tri-aquomet derivative. Consistency in L3 values between equilibrium and modulated excitation data for tri-aquomet-HbXL can be achieved if the equilibrium constant for O2 binding to the alpha chains is six times lower than that for binding to the beta chains in the R state, while the cooperative properties remain homogeneous. The results are in quantitative agreement with other studies, and suggest that the principal effect of the cross-link is to decrease the R state and T state affinity of the alpha subunits with almost no change in the affinity of the beta subunits, leaving the allosteric parameters L and c unchanged.     

Ligand binding kinetic studies on the hybrid hemoglobin alpha (human):beta (carp): a hemoglobin with mixed conformations and sequential conformational changes

Oxygen and CO ligand binding kinetics have been studied for the hybrid hemoglobin (Hb) alpha (human):beta (carp), hybrid II. Valency and half-saturated hybrids were used to aid in the assignment of the conformations of both chains. In hybrid II, an intermediate S state occurs, in which one chain has R- and the other T-state properties. In HbCO at pH 6 (plus 1 mM inositol hexaphosphate), the human alpha-chain is R state and the carp beta-chain is T state. We have no evidence at this pH that the carp beta-chain ever assumes the R conformation. At pH 6, the human alpha-chain shows human Hb R-state kinetics at low fractional photolysis and T-state rates for CO ligation by stopped flow. At pH 7, the human-chain R-state rate slows toward a carp hemoglobin rate. The carp beta-chains, on the other hand, react 50% more rapidly in the liganded conformation than in carp hemoglobin, and while the human alpha-chains are in the R state, the two beta-chains appear to function as a cooperative dimer. In this hemoglobin, the chains appear to be somewhat decoupled near pH 7, allowing a sequential conformational change from the R state in which the beta-chains first assume T-state properties, followed by the alpha-chains. The rate of the R-T conformational change for the carp beta-chains is at least 300 times greater than that for the human alpha-chains. At pH 9, the R----T conformational transition rate is at least 200 times slower than that for human hemoglobin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes in the abnormal alpha-subunit upon CO-binding to the normal beta-subunit of Hb M Boston: resonance Raman,EPR and CD study

Heme-heme interaction in Hb M Boston (His alpha 58-->Tyr) was investigated with visible and UV resonance Raman (RR), EPR, and CD spectroscopies. Although Hb M Boston has been believed to be frozen in the T quaternary state, oxygen binding exhibited appreciable co-operativity (n=1.4) and the near-UV CD spectrum indicated weakening of the T marker at pH 9.0. Binding of CO to the normal beta-subunit gave no change in the EPR and visible Raman spectra of the abnormal alpha-subunit at pH 7.5, but it caused an increase of EPR rhombicity and significant changes in the Raman coordination markers as well as the Fe(III)-tyrosine related bands of the alpha-subunit at pH 9.0. The UVRR spectra indicated appreciable changes of Trp but not of Tyr upon CO binding to the alpha-subunit at pH 9.0. Therefore, we conclude that the ligand binding to the beta heme induces quaternary structure change at pH 9.0 and is communicated to the alpha heme, presumably through His beta 92-->Trp beta 37-->His alpha 87.     

The dissociation of carbon monoxide from hemoglobin intermediate

To investigate the mechanism of allosteric switching in human hemoglobin, we have studied the dissociation of the ligand (CO) from several intermediate ligation states by a stopped-flow kinetic technique that utilizes competitive binding of CO by microperoxidase. The hemoglobin species investigated include Hb(CO)4, the diliganded symmetrical species (alpha beta-CO)2 and (alpha-CO beta)2, and the di- and monoliganded asymmetrical species (alpha-CO beta-CO)(alpha beta), (alpha-CO beta)(alpha beta-CO), (alpha beta-CO) (alpha beta), and (alpha-CO beta)(alpha beta). They were obtained by rapid reduction with dithionite of the corresponding valence intermediates that in turn were obtained by chromatography or by hybridization. The nature and concentration of the intermediates were determined by isoelectric focusing at -25 degrees C. The study was performed at varying hemoglobin concentrations (0.1, 0.02, and 0.001 mM [heme]), pH (6.0, 7.0, 8.0), with and without inositol hexaphosphate. The results indicate that: (a) hemoglobin concentration in the 0.1-0.02 mM range does not significantly affect the kinetic rates; (b) the alpha chains dissociate CO faster than the beta chains; (c) the symmetrical diliganded intermediates show cooperativity with respect to ligand dissociation that disappears in the presence of inositol hexaphosphate; (d) the monoliganded intermediates dissociate CO faster than the diliganded intermediates; (e) the asymmetrical diliganded intermediates are functionally different from the symmetrical species.     

Heats of carbon monoxide binding by hemoglobin M Iwate.

The heat of reaction of CO gas with the alpha2Mmetbeta2 and alpha2Mbeta2 species of the alpha-chain mutant hemoglobin M Iwate has been studied in buffers with different heats of ionization of 25degrees and in the absence of organic phosphates. For the alpha2Mmetbeta2deoxy species we find a small Bohr effect (0.12 mol of H+/mol of CO) which is in correspondence with that found in equilibrium studies. The heat of reaction, when corrected for proton reaction with buffer, is -18.4 +/- 0.3 kcal/mol of CO at pH 7.4 At pH 9 the same value is observed within experimental error. This value compares closely with heats of reaction of CO with myoglobin and with van't Hoff determinations of the heat of oxygen binding to isolated hemoglobin alpha and beta chains after correction for the heat of replacement of O2 by CO. Furthermore, an analysis of the differential heat of ligand binding as a function of the extent of reaction indicated that, within experimental error, the heat of reaction with the first beta-chain heme in alpha2Mmetbeta2deoxy is the same as the second. Since the quaternary Tleads to R transition is blocked in this mutant hemoglobin, we compared it with Hb A to estimate the enthalpic component of the allosteric T leads to R transition in Hb A. The heats of reaction with CO(g) and Hb A are -15.7 +/- 0.5 and -20.9 +/- 0.5 kcal/mol at pH 7.4 and 9.0, respectively. In going from the T to the R state we find an enthalpy of transition of 9 +/- 2.5 kcal at pH 7.4 and -12 +/- 2.5 kcal at pH 9.0. From published free energies of transsition we conclude the T leads to R transition is enthalpically controlled at p/ 7.4 but entropically controlled at pH 9.0 A near normal Bohr effect is estimated from heats of reaction of CO with alpha2Mdeoxybeta2deoxy in various buffers. A large than normal heat of reaction (-21.6 +/- 0.5 kcal/mol of CO) is attributed to the abnormal alpha chains in Hb M Iwate.     

Polymerization and solubility of Ni(II)-Fe(II) hybrid Hb S

Polymerization of half-liganded Hb S was investigated using Ni(II)-Fe(II) hybrid Hb S, in which heme in either alpha or beta s subunits is replaced by Ni (II) protoporphyrin IX. Studies on the polymerization of these hybrid hemoglobins were carried out under aerobic conditions. Both alpha 2 (Ni) beta 2s (Fe-CO) and alpha 2 (Fe-CO) beta 2s (Ni) polymerized with a distinct delay time as do native deoxy-Hb S and Ni(II) Hb S. However, the critical concentration for polymerization of half-liganded Hb S, alpha 2 (Ni) beta 2s (Fe-CO) and alpha 2 (Fe-CO) beta 2s (Ni), was 4- and 8-times higher, respectively, than that of Ni(II)-Hb S. Kinetics of polymerization of both deoxygenated hybrid hemoglobins with CO completely removed were the same, although the critical concentrations for polymerization were intermediate between those for deoxy-Hb S and Ni(II)-Hb S. These results suggest that the small tertiary conformational change associated with the doubly liganded state may be much less favorable to polymerization than the completely unliganded state of Hb S. The conformational change depends on whether alpha or beta chain is liganded. The ease of polymerization and low solubility of sickle hemoglobin is dependent not only on quaternary, but on tertiary structural changes, as well as on the substitution of Val for Glu at the beta 6 position.     

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.     

Effects of heterotropic allosteric effectors on the equilibrium and kinetics of the reaction of a single ligand molecule with an alpha or beta subunit of deoxygenated HbA

Symmetrical FeZn hybrids of human HbA have been used to measure K(1)(alpha) and K(1)(beta), the dissociation constants for the binding of a single molecule of oxygen to unliganded HbA at an alpha subunit and at a beta subunit, respectively. The kinetic constants, l(1)'(alpha) and l(1)'(beta), for the combination of the first CO molecule to unliganded HbA at an alpha or a beta subunit, respectively, were also measured. Measurements were carried out between pH 6 and pH 8 in the presence and absence of inositol hexaphosphate (IHP). Both equilibrium constants exhibit a significant Bohr effect in the absence of IHP. The addition of IHP to a concentration of 0.1 mM increases both dissociation constants in a pH-dependent manner with the result that both Bohr effects are greatly reduced. These results require a negative thermodynamic linkage between the binding of a single oxygen at either an alpha or a beta subunit and the binding of IHP to the T quaternary structure of HbA. Although the beta hemes are relatively near the IHP binding site, a linkage between that site and the alpha hemes, such that the binding of a single oxygen molecule to the heme of one alpha subunit reduces the affinity of the T state for IHP, requires communication across the molecule. l(1)'(alpha) exhibits a very slight pH dependence, with a maximum variation of 20%, while l(1)'(beta) varies with pH three times as much. IHP has no effect on the pH dependence of either rate constant but reduces l(1)'(alpha) marginally, 20%, and l(1)'(beta) by 2-fold at all pH values.     

Oxygen and CO binding to triply NO and asymmetric NO/CO hemoglobin hybrids.

The bimolecular and geminate CO recombination kinetics have been measured for hemoglobin (Hb) with over 90% of the ligand binding sites occupied by NO. Since Hb(NO)4 with inositol hexaphosphate (IHP) at pH below 7 is thought to take on the low affinity (deoxy) conformation, the goal of the experiments was to determine whether the species IHPHb-(NO)3(CO) also exists in this quaternary structure, which would allow ligand binding studies to tetramers in the deoxy conformation. For samples at pH 6.6 in the presence of IHP, the bimolecular kinetics show only a slow phase with rate 7 x 10(4) M-1 s-1, characteristic of CO binding to deoxy Hb, indicating that the triply NO tetramers are in the deoxy conformation. Unlike Hb(CO)4, the fraction recombination occurring during the geminate phase is low (< 1%) in aqueous solutions, suggesting that the IHPHb(NO)3(CO) hybrid is also essentially in the deoxy conformation. By mixing stock solutions of HbCO and HbNO, the initial exchange of dimers produces asymmetric (alpha NO beta NO/alpha CO beta CO) hybrids. At low pH in the presence of IHP, this hybrid also displays a high bimolecular quantum yield and a large fraction of slow (deoxy-like) CO recombination; the slow bimolecular kinetics show components of equal amplitude with rates 7 and 20 x 10(4) M-1 s-1, probably reflecting the differences in the alpha and beta chains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proton nuclear magnetic resonance and spectrophotometric studies of nickel(II)-iron(II) hybrid hemoglobins

Ni(II)-Fe(II) hybrid hemoglobins, alpha(Fe)2 beta(Ni)2 and alpha(Ni)2 beta(Fe)2 have been characterized by proton nuclear magnetic resonance with Ni(II) protoporphyrin IX (Ni-PP) incorporated in apoprotein, which serves as a permanent deoxyheme. alpha(Fe)2 beta(Ni)2, alpha(Ni)2 beta(Fe)2, and NiHb commonly show exchangeable proton resonances at 11 and 14 ppm, due to hydrogen-bonded protons in a deoxy-like structure. Upon binding of carbon monoxide (CO) to alpha(Fe)2 beta(Ni)2, these resonances disappear at pH 6.5 to pH 8.5. On the other hand, the complementary hybrid alpha(Ni)2 beta(Fe-CO)2 showed the 11 and 14 ppm resonances at low pH. Upon raising pH, the intensities of both resonances are reduced, although these changes are not synchronized. Electronic absorption spectra and hyperfine-shifted proton resonances indicate that the ligation of CO in the beta(Fe) subunits induced changes in the coordination and spin states of Ni-PP in the alpha subunits. In a deoxy-like structure, the coordination of Ni-PP in the alpha subunits is predominantly in a low-spin (S = 0) four-coordination state, whereas in an oxy-like structure the contribution of a high-spin (S = 1) five-coordination state markedly increased. Ni-PP in the beta subunits always takes a high-spin five-coordination state regardless of solution conditions and the state of ligation in the partner alpha(Fe) subunits. In the beta(Ni) subunits, a significant downfield shift of the proximal histidyl N delta H resonance and a change in the absorption spectrum of Ni-PP were detected, upon changing the quaternary structure of the hybrid.(ABSTRACT TRUNCATED AT 250 WORDS)     

Modulation of reactivity and conformation within the T-quaternary state of human hemoglobin: the combined use of mutagenesis and sol-gel encapsulation

A range of conformationally distinct functional states within the T quaternary state of hemoglobin are accessed and probed using a combination of mutagenesis and sol-gel encapsulation that greatly slow or eliminate the T --> R transition. Visible and UV resonance Raman spectroscopy are used to probe the proximal strain at the heme and the status of the alpha(1)beta(2) interface, respectively, whereas CO geminate and bimolecular recombination traces in conjunction with MEM (maximum entropy method) analysis of kinetic populations are used to identify functionally distinct T-state populations. The mutants used in this study are Hb(Nbeta102A) and the alpha99-alpha99 cross-linked derivative of Hb(Wbeta37E). The former mutant, which binds oxygen noncooperatively with very low affinity, is used to access low-affinity ligated T-state conformations, whereas the latter mutant is used to access the high-affinity end of the distribution of T-state conformations. A pattern emerges within the T state in which ligand reactivity increases as both the proximal strain and the alpha(1)beta(2) interface interactions are progressively lessened after ligand binding to the deoxy T-state species. The ligation and effector-dependent interplay between the heme environment and the stability of the Trp beta37 cluster in the hinge region of the alpha(1)beta(2) interface appears to determine the distribution of the ligated T-state species generated upon ligand binding. A qualitative model is presented, suggesting that different T quaternary structures modulate the stability of different alphabeta dimer conformations within the tetramer.     

NMR studies of the quaternary structure and heterogeneity of nitrosyl- and methemoglobin.

NMR was used to study the quaternary structure of nitrosyl- and methemoglobin, the kinetics and equilibrium behavior of nitric oxide binding, and the oxidation of hemoglobin. The -9.6 ppm (from H2O) resonance was used as a measure of nitrosylhemoglobin molecules in the T quaternary structure. We found that stripped nitrosylhemoglobin is 70% in the T state below pH 6.4, and is in the R state above. Inositol hexaphosphate (IHP) raises this transition point to pH 7.5. For stripped aquomethemoglobin, the T marker at -10 ppm is absent. In IHP, at pH 6.5 all of the molecules are in the T state. At both higher and lower pH they shift to the R state. The intensity decreases to half of its maximum at pH 5.5 and 7.4. The relative affinity of nitric oxide binding to the alpha and beta subunits was inferred from the intensities of the resonances at -12 and -18 ppm. Under conditions in which nitrosylhemoglobin exists in the T state, NO binds to the alpha subunit 10 times more strongly than it does to the beta subunit. The kinetic experiments reveal that it binds to the two subunits at the same rate and that it dissociates at 5 x 10(-3) s-1 from the beta subunit and at 5 x 10(-4) s-1 from alpha subunit. At high pH, the two subunits are ligated at the same rate. Potassium ferricyanide oxidation, at pH 6.0 in the absence of IHP, is about 3 times more favorable for the alpha than the beta subunit. Addition of IHP raises this preferential oxidation slightly. At pH 8.44, both alpha and beta subunits were oxidized at the same rate.     

Quaternary structure and geminate recombination in hemoglobin: flow-flash studies on alpha 2CO beta 2 and alpha 2 beta 2CO.

The kinetics of geminate recombination for the diliganded species alpha 2CO beta 2 and alpha 2 beta 2CO of human hemoglobin were studied using flash photolysis. The unstable diliganded species were generated just before photolysis by chemical reduction in a continuous flow reactor from the more stable valency hybrids alpha 2CO beta 2+ and alpha 2+ beta 2CO, which could be prepared by high pressure liquid chromatography. Before the flash photolysis studies, the hybrids had been characterized by double-mixing stopped-flow kinetics experiments. At pH 6.0 in the presence of inositol hexaphosphate (IHP) both of the diliganded species show second order kinetics for overall addition of a third CO that is clearly characteristic of the T state (l' = 1-2 x 10(5) M-1 s-1), whereas at higher pH and in the absence of IHP they show combination rates characteristic of an R state. The kinetics of geminate recombination following photolysis of a bound CO, however, showed little dependence on pH and IHP concentration. This surprising observation is explained on the basis that the kinetics of geminate recombination of CO primarily depends on the tertiary structure of the ligand binding site, which apparently does not differ much between the R state and the liganded T state formed on adding IHP in this system. Since this explanation requires distinguishing different tertiary structures within a particular quaternary structure, it amounts to a contradiction to the two-state allosteric model.     

Quaternary structure dynamics and carbon monoxide binding kinetics of hemoglobin valency hybrids.

The kinetics of CO binding and changes in quaternary structure for symmetric valency hybrids of human hemoglobin have been extensively studied by laser photolysis techniques. Both alpha+beta and alpha beta+ hybrids were studied with five different ferric ligands, over a broad range of CO concentrations and photolysis levels. After full CO photolysis, the hybrid tetramers switch extensively and rapidly (< 200 microseconds) to the T quaternary structure. Both R --> T and T --> R transition rates for valency hybrid tetramers with 0 and 1 bound CO have been obtained, as well as the CO association rates for alpha and beta subunits in the R and T states. The results reveal submillisecond R reversible T interconversion, and, for the first time, the changes in quaternary rates and equilibria due to binding a single CO per tetramer have been resolved. The data also show significant alpha-beta differences in quaternary dynamics and equilibria. The allosteric constants do not vary with the spin states of the ferric subunits as predicted by the Perutz stereochemical model. For the alpha beta+CN hybrid the kinetics are heterogeneous and imply partial conversion to a T-like state with very low (seconds) R reversible T interconversion.     

Oligomerization and ligand binding in a homotetrameric hemoglobin: two high-resolution crystal structures of hemoglobin Bart's (gamma(4)), a marker for alpha-thalassemia

Hemoglobin (Hb) Bart's is present in the red blood cells of millions of people worldwide who suffer from alpha-thalassemia. alpha-Thalassemia is a disease in which there is a deletion of one or more of the four alpha-chain genes, and excess gamma and beta chains spontaneously form homotetramers. The gamma(4) homotetrameric protein known as Hb Bart's is a stable species that exhibits neither a Bohr effect nor heme-heme cooperativity. Although Hb Bart's has a higher O(2) affinity than either adult (alpha(2)beta(2)) or fetal (alpha(2)gamma(2)) Hbs, it has a lower affinity for O(2) than HbH (beta(4)). To better understand the association and ligand binding properties of the gamma(4) tetramer, we have solved the structure of Hb Bart's in two different oxidation and ligation states. The crystal structure of ferrous carbonmonoxy (CO) Hb Bart's was determined by molecular replacement and refined at 1.7 A resolution (R = 21.1%, R(free) = 24.4%), and that of ferric azide (N(3)(-)) Hb Bart's was similarly determined at 1.86 A resolution (R = 18.4%, R(free) = 22.0%). In the carbonmonoxy-Hb structure, the CO ligand is bound at an angle of 140 degrees, and with an unusually long Fe-C bond of 2.25 A. This geometry is attributed to repulsion from the distal His63 at the low pH of crystallization (4.5). In contrast, azide is bound to the oxidized heme iron in the methemoglobin crystals at an angle of 112 degrees, in a perfect orientation to accept a hydrogen bond from His63. Compared to the three known quaternary structures of human Hb (T, R, and R2), both structures most closely resemble the R state. Comparisons with the structures of adult Hb and HbH explain the association and dissociation behaviour of Hb homotetramers relative to the heterotetrameric Hbs.     

An additional H-bond in the alpha 1 beta 2 interface as the structural basis for the low oxygen affinity and high cooperativity of a novel recombinant hemoglobin (beta L105W)

Site-directed mutagenesis has been used to construct three recombinant mutant hemoglobins (rHbs), rHb(beta L105W), rHb(alpha D94A/betaL105W), and rHb(alpha D94A). rHb(beta L105W) is designed to form a new hydrogen bond from beta 105Trp to alpha 94Asp in the alpha(1)beta(2) subunit interface to lower the oxygen binding affinity by stabilizing the deoxy quaternary structure. We have found that rHb(beta L105W) does indeed possess a very low oxygen affinity and maintains normal cooperativity (P(50) = 28.2 mmHg, n(max) = 2.6 in 0.1 M sodium phosphate at pH 7.4) compared to those of Hb A (P(50) = 9.9 mmHg, n(max) = 3.2 at pH 7.4). rHb(alpha D94A/beta L105W) and rHb(alpha D94A) are expressed to provide evidence that rHb(betaL 105W) does form a new H-bond from beta 105Trp to alpha 94Asp in the alpha(1)beta(2) subunit interface of the deoxy quaternary structure. Our multinuclear, multidimensional nuclear magnetic resonance (NMR) studies on (15)N-labeled rHb(beta L105W) have identified the indole nitrogen-attached (1)H resonance of beta 105Trp for rHb(beta L105W). (1)H NMR studies on Hb A and mutant rHbs have been used to investigate the structural basis for the low O(2) affinity of rHb(beta L105W). Our NMR results provide evidence that rHb(beta L105W) forms a new H-bond from beta 105Trp to alpha 94Asp in the alpha(1)beta(2) subunit interface of the deoxy quaternary structure. The NMR results also show that these three rHbs can switch from the R quaternary structure to the T quaternary structure in their ligated state upon addition of an allosteric effector, inositol hexaphosphate. We propose that the low O(2) affinity of rHb(beta L105W) is due to the formation of a new H-bond between alpha 105Trp and alpha 94Asp in the deoxy quaternary structure.     

Probing the diphosphoglycerate binding pocket of HbA and HbPresbyterian (beta 108Asn --> Lys).

HbPresbyterian (beta 108Asn --> Lys, HbP) contains an additional positive charge (per alpha beta dimer) in the middle of the central cavity and exhibits a lower oxygen affinity than wild-type HbA in the presence of chloride. However, very little is known about the molecular origins of its altered functional properties. In this study, we have focused on the beta beta cleft of the Hb tetramer. Recently, we developed an approach for quantifying the ligand binding affinity to the beta-end of the Hb central cavity using fluorescent analogues of the natural allosteric effector 2, 3-diphosphoglycerate (DPG) [Gottfried, D. S., et al. (1997) J. Biol. Chem. 272, 1571-1578]. Time-correlated single-photon counting fluorescence lifetime studies were used to assess the binding of pyrenetetrasulfonate to both HbA and HbP in the deoxy and CO ligation states under acidic and neutral pH conditions. Both the native and mutant proteins bind the probe at a weak binding site and a strong binding site; in all cases, the binding to HbP was stronger than to HbA. The most striking finding was that for HbA the binding affinity varies as follows: deoxy (pH 6.35) > deoxy (pH 7.20) > CO (pH 6.35); however, the binding to HbP is independent of ligation or pH. The mutant oxy protein also hydrolyzes p-nitrophenyl acetate, through a reversible acyl-imidazole pathway linked to the His residues of the beta beta cleft, at a considerably higher rate than does HbA. This implies a perturbation of the microenvironment of these residues at the DPG binding pocket. Structural consequences due to the presence of the new positive charge in the middle of the central cavity have been transmitted to the beta beta cleft of the protein, even in its liganded conformation. This is consistent with a newly described quaternary state (B) for liganded HbPresbyterian and an associated change in the allosteric control mechanism.