Structures and oxygen affinities of crystalline human hemoglobin C (β6 Glu->Lys) in the R and R2 quaternary structures

Recent crystallographic studies suggested that fully liganded human hemoglobin can adopt multiple quaternary conformations that include the two previously solved relaxed conformations, R and R2, whereas fully unliganded deoxyhemoglobin may adopt only one T (tense) quaternary conformation. An important unanswered question is whether R, R2, and other relaxed quaternary conformations represent different physiological states with different oxygen affinities. Here, we answer this question by showing the oxygen equilibrium curves of single crystals of human hemoglobin in the R and R2 state. In this study, we have used a naturally occurring mutant hemoglobin C (β6 Glu→Lys) to stabilize the R and R2 crystals. Additionally, we have refined the x-ray crystal structure of carbonmonoxyhemoglobin C, in the R and R2 state, to 1.4 and 1.8 Å resolution, respectively, to compare precisely the structures of both types of relaxed states. Despite the large quaternary structural difference between the R and R2 state, both crystals exhibit similar noncooperative oxygen equilibrium curves with a very high affinity for oxygen, comparable with the fourth oxygen equilibrium constant (K₄) of human hemoglobin in solution. One small difference is that the R2 crystals have an oxygen affinity that is 2–3 times higher than that of the R crystals. These results demonstrate that the functional difference between the two typical relaxed quaternary conformations is small and physiologically less important, indicating that these relaxed conformations simply reflect a structural polymorphism of a high affinity relaxed state.     

The enigma of the liganded hemoglobin end state: a novel quaternary structure of human carbonmonoxy hemoglobin

The liganded hemoglobin (Hb) high-salt crystallization condition described by Max Perutz has generated three different crystals of human adult carbonmonoxy hemoglobin (COHbA). The first crystal is isomorphous with the "classical" liganded or R Hb structure. The second crystal reveals a new liganded Hb quaternary structure, RR2, that assumes an intermediate conformation between the R form and another liganded Hb quaternary structure, R2, which was discovered more than a decade ago. Like the R2 structure, the diagnostic R state hydrogen bond between beta2His97 and alpha1Thr38 is missing in the RR2 structure. The third crystal adopts a novel liganded Hb conformation, which we have termed R3, and it shows substantial quaternary structural differences from the R, RR2, and R2 structures. The quaternary structure differences between T and R3 are as large as those between T and R2; however, the T --> R3 and T --> R2 transitions are in different directions as defined by rigid-body screw rotation. Moreover, R3 represents an end state. Compared to all known liganded Hb structures, R3 shows remarkably reduced strain at the alpha-heme, reduced steric contact between the beta-heme ligand and the distal residues, smaller alpha- and beta-clefts, and reduced alpha1-alpha2 and beta1-beta2 iron-iron distances. Together, these unique structural features in R3 should make it the most relaxed and/or greatly enhance its affinity for oxygen compared to the other liganded Hbs. The current Hb structure-function relationships that are now based on T --> R, T -->R --> R2, or T --> R2 --> R transitions may have to be reexamined to take into account the RR2 and R3 liganded structures.     

The X-ray structure determination of bovine carbonmonoxy hemoglobin at 2.1 A resoultion and its relationship to the quaternary structures of other hemoglobin crystal froms

Crystallographic studies of the intermediate states between unliganded and fully liganded hemoglobin (Hb) have revealed a large range of subtle but functionally important structural differences. Only one T state has been reported, whereas three other quaternary states (the R state, B state, and R2 or Y state) for liganded Hb have been characterized; other studies have defined liganded Hbs that are intermediate between the T and R states. The high-salt crystal structure of bovine carbonmonoxy (CO bovine) Hb has been determined at a resolution of 2.1 A and is described here. A detailed comparison with other crystallographically solved Hb forms (T, R, R2 or Y) shows that the quaternary structure of CO bovine Hb closely resembles R state Hb. However, our analysis of these structures has identified several important differences between CO bovine Hb and R state Hb. Compared with the R state structures, the beta-subunit N-terminal region has shifted closer to the central water cavity in CO bovine Hb. In addition, both the alpha- and beta-subunits in CO bovine Hb have more constrained heme environments that appear to be intermediate between the T and R states. Moreover, the distal pocket of the beta-subunit heme in CO bovine Hb shows significantly closer interaction between the bound CO ligand and the Hb distal residues Val 63(E11) and His 63(E7). The constrained heme groups and the increased steric contact involving the CO ligand and the distal heme residues relative to human Hb may explain in part the low intrinsic oxygen affinity of bovine Hb.     

Geminate ligand recombination as a probe of the R, T equilibrium in hemoglobin

Flash photolysis kinetics of carbon monoxide hemoglobin show a decrease in the fraction of ligand recombination occurring as geminate when the hemoglobin has fewer ligands bound. Fully saturated samples, normally referred to as R state, show approximately 50% geminate phase, while samples at low saturation (T state) show less than 3%. The latter result was obtained by photolysis of samples with a short delay after stopped flow of solutions of deoxy hemoglobin (Hb) and ligand. The decrease in the fraction of geminate phase was also observed using a double flash technique. The transient mixture of R and T states generated by flash photolysis of Hb-CO was probed with a weaker time-delayed photolysis pulse. The kinetics of both the geminate and bimolecular phases following the second pulse were measured. The fraction geminate signal was least at delays where the maximum proportion of liganded T state tetramer is expected. The biphasic bimolecular process is also an indicator of the allosteric state of Hb. The populations of R and T may be determined from the overall ligand recombination kinetics; however, the analysis is model-dependent. The fraction geminate reaction may provide a rapid measure of the amount of liganded hemes in the R and T states.     

Effect of ligands of ferric hemes on interaction between ferric and ferrous chains in partially oxidized hemoglobin A.

Normal values of Bohr effect of oxygenation of partially oxidized hemoglobin A with ferrihemes liganded either with H2O and OH or with CN have been found in the range of pH values from 6.8 to 7.6 in 45 micrometer (Fe)-hemoglobin containing 36--38% of ferrihemes. As the changes of oxygen affinity of Hb A induced by changes of pH are due to the modifications of R state, this quaternary conformation is thought to be unchanged in the studied of R state, this quaternary conformation is thought to be unchanged in the studied forms of partially oxidized hemoglobin. It is suggested that interactions between ferric and ferrous hemes leading to the increased affinity of ferrous hemes to oxygen occur in deoxygenated form of partially oxidized hemoglobin. In partially oxidized hemoglobin with ferric hemes liganded with H2O asymmetry of oxygen binding curves has been noted, which is not observed in forms with ferric hemes liganded with OH ot CN. This shows the effect of ligands of ferric hemes on interactions between chains containing ferric and ferrous hemes.     

Kinetics of ligand binding and quaternary conformational change in the homodimeric hemoglobin from Scapharca inaequivalvis

The kinetics of the reaction with oxygen and carbon monoxide of the homodimeric hemoglobin from the bivalve mollusc Scapharca inaequivalvis has been extensively investigated by flash and dye-laser photolysis, temperature jump relaxation, and stopped flow methods. The results indicate that cooperativity in ligand binding, already observed for oxygen at equilibrium, finds its kinetic counterpart in a large decrease of the oxygen dissociation velocity in the second step of the binding reaction. In the case of carbon monoxide, cooperativity is clearly evident in the increase of the combination velocity constant as the reaction proceeds. Therefore, the ligand-binding kinetics of this dimeric hemoglobin shows the characteristic features of the corresponding reactions of tetrameric hemoglobins. Analysis of the data in terms of the allosteric model proposed by Monod et al. (Monod, J., Wyman, J., and Changeux, J. P. (1965) J. Mol. Biol. 12, 88-118) has shown that the values of the allosteric parameters cannot be fixed uniquely for a dimeric hemoglobin. The rapid changes in absorbance observed at the isosbestic points of unliganded and liganded hemoglobin following laser photolysis provided a value of 7 X 10(4) S-1 at 20 degrees C for the rate of the ligand-free quarternary conformational change, postulated on the basis of cooperative ligand binding. Comparison of the rapid absorbance changes observed during ligand rebinding in this hemoglobin with those observed in tuna hemoglobin indicate that, at full photolysis, binding to the T state is followed by further binding and conversion to the liganded R state; at partial photolysis, population of the liganded T state occurs immediately and is followed by a decay to the liganded R state upon further ligand binding. These new results, in conjunction with previous equilibrium data on the same system, show unequivocally that the presence of two different types of chain is not an absolute prerequisite for cooperativity in hemoglobins, contrary to currently accepted ideas.     

A survey of hemoglobin quaternary structures

We perform an analysis of the quaternary structure and dimer/dimer interface in the crystal structures of 165 human hemoglobin tetramers; 112 are in the T, 17 the R, 14 the Y (or R2) state; 11 are high-affinity T state mutants, and 11 may either be intermediates between the states, or off the allosteric transition pathway. The tertiary structure is fixed within each state, in spite of the different ligands, mutations, and chemical modifications present in individual entries. The geometry of the tetramer assembly is essentially the same in all the R or the Y state entries; it is slightly different in high salt and low salt crystals of T state hemoglobins. The dimer/dimer interface differs in terms of size, chemical composition and polar interactions, between the states. It is loosely packed, like crystal packing contacts or the subunit interface of weakly associated homodimers, and unlike most oligomeric proteins, which have close-packed interfaces. The loose packing is most obvious in the liganded forms, where the tetramer is known to dissociate at low concentration. We identify cavities that contribute to the loose packing of the α1β2 and α2β1 contacts. Two pairs of cavities occur recurrently in both the T and the R state tetramers. They may contribute to the allosteric mechanism by facilitating the subunit movements and the tertiary structure changes that accompany the transition from T to R to Y.     

Zn(II)-induced dimerization of human carbonmonoxy hemoglobin

Binding of Zn(II) to the carbon monoxide complex of human hemoglobin was shown by equilibrium sedimentation and sedimentation velocity experiments at pH 7.0 to induce the dissociation of liganded tetramers to dimers but not to monomers. These results provide direct confirmation of previous kinetic and gel filtration experiments (R. D. Gray, (1980) J. Biol. Chem.255, 1812–1818) that Zn(II) binding to liganded hemoglobin produces a change in aggregation state of liganded hemoglobin.     

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)     

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.     

Dynamics of hemoglobin investigated by M?ssbauer spectroscopy

M?ssbauer Spectra of Fe enriched horse hemoglobin and sperm whale myoglobin were measured in the temperature range from 80 K to 260 K. An analysis of the temperature dependence of the recoiless fraction (the Lamb-M?ssbauer factor) shows it to be sensitive to conformational fluctuations which affect the mean square displacement of the iron. We have found that the protein conformation has a dramatic effect on these measurements. For hemoglobin greater conformational fluctuations at lower temperatures are observed for carbonmonoxyhemoglobin in the liganded conformation than for deoxyhemoglobin in the unliganded conformation. On the other hand, the Lamb-M?ssbauer factor is insensitive to the binding of ligands to myoglobin and shows conformational fluctuations similar to deoxyhemoglobin even in the liganded state. It is also shown that a reversible complex with the distal histidine is formed in frozen deoxyhemoglobin solution above 200 K where the Lamb-M?ssbauer factor shows the excitation of new modes of conformational fluctuations. This complex is not formed with carbonmonoxyhemoglobin which already has a sixth ligand and with deoxymyoglobin which appears to undergo much more limited conformational fluctuations. A possible relationship between the formation of the distal histidine complex and the cooperative ligand binding reaction is suggested by results with partially liganded hemoglobin which indicate increased formation of the distal histidine complex.     

Dynamics of Hemoglobin Investigated by Mössbauer Spectroscopy

Abstract

Mössbauer Spectra of ⁵⁷Fe enriched horse hemoglobin and sperm whale myoglobin were measured in the temperature range from 80 K to 260 K. An analysis of the temperature dependence of the recoiless fraction (the Lamb-Mössbauer factor) shows it to be sensitive to conformational fluctuations which affect the mean square displacement of the iron. We have found that the protein conformation has a dramatic effect on these measurements. For hemoglobin greater conformational fluctuations at lower temperatures are observed for carbonmonoxyhemoglobin in the liganded conformation than for deoxyhemoglobin in the unliganded conformation. On the other hand, the Lamb-Mössbauer factor is insensitive to the binding of ligands to myoglobin and shows conformational fluctuations similar to deoxyhemoglobin even in the liganded state. It is also shown that a reversible complex with the distal histidine is formed in frozen deoxyhemoglobin solutions above 200 K where the Lamb-Mössbauer factor shows the excitation of new modes of conformational fluctuations. This complex is not formed with carbonmonoxyhemoglobin which already has a sixth ligand and with deoxymyoglobin which appears to undergo much more limited conformational fluctuations. A possible relationship between the formation of the distal histidine complex and the cooperative ligand binding reaction is suggested by results with partially liganded hemoglobin which indicate increased formation of the distal histidine complex.     

Conformational sensitivity of beta-93 cysteine SH to ligation of hemoglobin observed by FT-IR spectroscopy

The SH vibrational absorption of cysteine F9(beta-93) in concentrated aqueous solutions of native liganded hemoglobin (human HbA, horse, and bovine) has been observed by use of Fourier transform infrared spectroscopy. The pattern of beta-93 SH absorption intensity is ligand dependent. In bovine hemoglobin derivatives the SH absorption intensity pattern is (carbonmonoxy)hemoglobin (HbCO) greater than oxyhemoglobin (HbO2) = cyanomethemoglobin (HbCN) much greater than aquomethemoglobin (metHb) and deoxyhemoglobin (deoxyHb). In horse and human hemoglobin derivatives the pattern is HbCO greater than or equal to HbO2 greater than HbCN greater than metHb. The bovine metHb beta-93 SH shows a much lower absorptivity than that of horse or human metHb, and thus it has a different local tertiary equilibrium conformation than does horse or human hemoglobin. X-ray diffraction studies have shown the beta-93 SH in carbon monoxide or oxygen bound hemoglobin to be situated within a nonpolar pocket between the F, G, and H helices. The higher than usual SH absorption frequency (2592 cm-1) that we observe implies there is no hydrogen bonding for this thiol group while situated within this nonpolar pocket. A similar beta-93 SH absorption has been observed in the beta-chain tetramer (thalassemic hemoglobin H in vivo). The beta-112 SH stretching band, previously observed in the alpha 2 beta 2 tetramer, was observed for the first time in the beta-chain tetramer. A band at 2610 cm-1 that is not due to SH was resolved and found to be ligand dependent.     

Phase separation and crystallization of hemoglobin C in transgenic mouse and human erythrocytes

Individuals expressing hemoglobin C (β6 Glu→Lys) present red blood cells (RBC) with intraerythrocytic crystals that form when hemoglobin (Hb) is oxygenated. Our earlier in vitro liquid-liquid (L-L) phase separation studies demonstrated that liganded HbC exhibits a stronger net intermolecular attraction with a longer range than liganded HbS or HbA, and that L-L phase separation preceded and enhanced crystallization. We now present evidence for the role of phase separation in HbC crystallization in the RBC, and the role of the RBC membrane as a nucleation center. RBC obtained from both human homozygous HbC patients and transgenic mice expressing only human HbC were studied by bright-field and differential interference contrast video-enhanced microscopy. RBC were exposed to hypertonic NaCl solution (1.5-3%) to induce crystallization within an appropriate experimental time frame. L-L phase separation occurred inside the RBC, which in turn enhanced the formation of intraerythrocytic crystals. RBC L-L phase separation and crystallization comply with the thermodynamic and kinetics laws established through in vitro studies of phase transformations. This is the first report, to the best of our knowledge, to capture a temporal view of intraerythrocytic HbC phase separation, crystal formation, and dissolution.     

Relative stabilities of the two quaternary conformations of human fetal hemoglobin.

The pH dependence of several functional properties of human fetal and adult hemoglobins have been studied to determine the relative stabilities of the high and low affinity (R and T) quaternary conformations of the two proteins under different conditions. Fetal aqumethemoglobin undergoes changes in sulfhydryl reactivity, absorption spectrum, and circular dichroism in the presence of insitol hexaphospahte which are consistent with a transition from the R to T quaternary state, but only at pH values below 6.8. In adult hemoglobin this transition can be induced pH values below 7.2. Even in the absence of phosphates, the ultraviolet (uv) circular dichroism spectrum of fetal aquomethemoglobin at low pH indicates the presence of some T conformation. The initial value for the second-order rate constant for combination of fetal deoxyhemoglobin with carbon monoxide is comparable to that for adult hemoglobin in the absence of organic phosphates and is not reduced by organic phosphates as much as that for the adult protein. The apparent first-order rate constant for dissociation of CO from fully liganded fetal hemoglobin, measured by replacement with NO, increases threefold in the absence of organic phosphates, and fourfold in the presence of organic phosphates, with decreasing pH; the midpoint of the pH dependent transition occurs around 6.8. A similar increase in the apparent first-order rate constant for O2 dissociation as measured by replacement with CO, can also be seen with decreasing pH. NO-hemoglobin F can be converted to the T state even when fully liganded simply by lowering the pH, as judged by uv circular dichroism, visible difference spectrum in the region of the alpha and beta bands, and a dramatic increase in the rate of NO dissociation, measured by replacement with CO in the presence of dithionite. These results are all consistent with a model for fetal hemoglobin in which the organic phosphate site may be functionally weakened by replacement of a residue involved in ionic interactions with the negatively charged phosphate groups, but in which the low affinity T conformation is intrinsically more stable than that of adllt hemoglobin. According to this model,the differences between fetal and adult hemoglobin can be accounted for primarily in terms of the relative stabilities of R and T conformations in each of the proteins with differences in the intrinsic properties of the individual conformations contributing effects of only secondary importance.     

Coupling of tertiary and quaternary changes in human hemoglobin: a 1D and 2D NMR study of hemoglobin Saint Mandé (beta N102Y)

Hemoglobin Saint Mandé (beta N102Y) is a low-affinity mutant with the substitution site situated in the quaternary-sensitive alpha 1 beta 2 interface. In adult hemoglobin the Asn102 beta contributes to the stability of the liganded (R) state, forming a hydrogen bond with Asp94 alpha. The quaternary and tertiary perturbations subsequent to the Tyr for Asn substitution in monocarboxylated hemoglobin Saint Mandé have been investigated by one- and two-dimensional nuclear magnetic resonance (NMR) spectroscopy. Analysis of the one-dimensional NMR spectra of the liganded and unliganded samples in 1H2O provides evidence that both R and T quaternary structures of Hb Saint Mandé are different from the corresponding ones in HbA. In the monocarboxylated form of the mutant hemoglobin, at acid pH, we have observed the disappearance of an R-type hydrogen bond and the appearance of a new one whose proton resonates like a deoxy T marker. Using two-dimensional NMR methods and on the basis of previous results on the monocarboxylated HbA, we have obtained a significant number of resonance assignments in the spectra of monocarboxylated Hb Saint Mandé at pH 5.6 in the presence or absence of a strong allosteric effector, inositol hexaphosphate. This enabled us to characterize the tertiary conformational changes (relative to the liganded normal hemoglobin) triggered by the quaternary-state modification. The observed structural variations are confined within the heme pocket regions but concern both the alpha and beta subunits. Most of them, localized in the C, F, G, and FG segments, could result directly from the side-chain substitution, while others, such as Leu141 beta, could be explained only by long-range interactions.     

Interface sliding as illustrated by the multiple quaternary structures of liganded hemoglobin

Initial crystallographic studies suggested that fully liganded mammalian hemoglobin can adopt only a single quaternary structure, the quaternary R structure. However, more recent crystallographic studies revealed the existence of a second quaternary structure for liganded hemoglobin, the quaternary R2 structure. Since these quaternary structures can be crystallized, both must be energetically accessible structures that coexist in solution. Unanswered questions include (i) the relative abundance of the R and R2 structures under various solution conditions and (ii) whether other quaternary structures are energetically accessible for the liganded alpha(2)beta(2) hemoglobin tetramer. Although crystallographic methods cannot directly answer the first question, they represent the most direct and most accurate approach to answering the second question. We now have determined and refined three different crystal structures of bovine carbonmonoxyhemoglobin. These structures provide clear evidence that the dimer-dimer interface of liganded hemoglobin has a wide range of energetically accessible structures that are related to each other by a simple sliding motion. The dimer-dimer interface acts as a "molecular slide bearing" that allows the two alpha beta dimers to slide back and forth without greatly altering the number or the nature of the intersubunit contacts. Since the general stereochemical features of this interface are not unusual, it is likely that interface sliding of the kind displayed by fully liganded hemoglobin plays important structural and functional roles in many other protein assemblies.     

Coupling of ferric iron spin and allosteric equilibrium in hemoglobin.

The allosteric transition in triply ferric hemoglobin has been studied with different ferric ligands. This valency hybrid permits observation of oxygen or CO binding properties to the single ferrous subunit, whereas the liganded state of the other three ferric subunits can be varied. The ferric hemoglobin (Hb) tetramer in the absence of effectors is generally in the high oxygen affinity (R) state; addition of inositol hexaphosphate induces a transition towards the deoxy (T) conformation. The fraction of T-state formed depends on the ferric ligand and is correlated with the spin state of the ferric iron complexes. High-spin ferric ligands such as water or fluoride show the most T-state, whereas low-spin ligands such as cyanide show the least. The oxygen equilibrium data and kinetics of CO recombination indicate that the allosteric equilibrium can be treated in a fashion analogous to the two-state model. The binding of a low-spin ferric ligand induces a change in the allosteric equilibrium towards the R-state by about a factor of 150 (at pH 6.5), similar to that of the ferrous ligands oxygen or CO; however, each high-spin ferric ligand induces a T to R shift by a factor of 40.     

T-state hemoglobin with four ligands bound

Flash photolysis kinetics have been measured for ligand recombination to hemoglobin (Hb) in the presence of two effectors: bezafibrate (Bzf) and inositol hexakisphosphate (IHP). The combined influence of the two independent effectors leads to predominantly T-state behavior. Samples equilibrated with 0.1 atm of CO are fully saturated, yet after photodissociation they show only T-state bimolecular recombination rates at all photolysis levels; this indicates that the allosteric transition from R to T occurs before CO rebinding and that the allosteric equilibrium favors the T-state tetramer with up to three ligands bound. Since all four ligands bind at the rate characteristic for the T-state, the return transition from T to R must occur after the fourth ligand was bound. At 1 atm of CO, rebinding to the initial R state competes with the allosteric transition resulting in a certain fraction of CO bound at the rate characteristic for the R state; this fraction is greater the smaller the percentage dissociation. Under 1 atm of oxygen, samples are not more than 93% saturated and show mainly T-state kinetics. The results show that all four hemes can bind oxygen or CO ligands in the T structure. The fraction of the kinetics occurring as geminate is less for partially liganded (T-state) samples than for fully liganded (R-state) Hb.     

Evolution of allosteric models for hemoglobin

We compare various allosteric models that have been proposed to explain cooperative oxygen binding to hemoglobin, including the two-state allosteric model of Monod, Wyman, and Changeux (MWC), the Cooperon model of Brunori, the model of Szabo and Karplus (SK) based on the stereochemical mechanism of Perutz, the generalization of the SK model by Lee and Karplus (SKL), and the Tertiary Two-State (TTS) model of Henry, Bettati, Hofrichter and Eaton. The preponderance of experimental evidence favors the TTS model which postulates an equilibrium between high (r)- and low (t)-affinity tertiary conformations that are present in both the T and R quaternary structures. Cooperative oxygenation in this model arises from the shift of T to R, as in MWC, but with a significant population of both r and t conformations in the liganded T and in the unliganded R quaternary structures. The TTS model may be considered a combination of the SK and SKL models, and these models provide a framework for a structural interpretation of the TTS parameters. The most compelling evidence in favor of the TTS model is the nanosecond - millisecond carbon monoxide (CO) rebinding kinetics in photodissociation experiments on hemoglobin encapsulated in silica gels. The polymeric network of the gel prevents any tertiary or quaternary conformational changes on the sub-second time scale, thereby permitting the subunit conformations prior to CO photodissociation to be determined from their ligand rebinding kinetics. These experiments show that a large fraction of liganded subunits in the T quaternary structure have the same functional conformation as liganded subunits in the R quaternary structure, an experimental finding inconsistent with the MWC, Cooperon, SK, and SKL models, but readily explained by the TTS model as rebinding to r subunits in T. We propose an additional experiment to test another key prediction of the TTS model, namely that a fraction of subunits in the unliganded R quaternary structure has the same functional conformation (t) as unliganded subunits in the T quaternary structure.