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.     

Carbon dioxide binding to human hemoglobin cross-linked between the alpha chains

The binding of carbon dioxide to human hemoglobin cross-linked between Lys alpha 99 residues with bis(3,5-di-bromosalicyl) fumarate was measured using manometric techniques. The binding of CO2 to unmodified hemoglobin can be described by two classes of sites with high and low affinities corresponding to the amino-terminal valines of the beta and alpha chains, respectively (Perrella, M., Kilmartin, J. V., Fogg, J., and Rossi-Bernardi, L. (1975b) Nature 256, 759-761. The cross-linked hemoglobin bound less CO2 than native hemoglobin at all CO2 concentrations in deoxygenated and liganded conformations, and the ligand-linked effect was reduced. Fitting the data to models of CO2 binding suggests that only half of the expected saturation with CO2 is possible. The remaining binding is described by a single affinity constant that for cross-linked deoxyhemoglobin is about two-thirds of the high affinity constant for deoxyhemoglobin A and that for cross-linked cyanomethemoglobin is equal to the high affinity constant for unmodified cyanomethemoglobin A or carbonmonoxyhemoglobin A. The low affinity binding constant for cross-linked hemoglobin in both the deoxygenated and liganded conformations is close to zero, which is significantly less than the affinity constants for either subunit binding site in unmodified hemoglobin. Comparing the low affinity sites in this modified hemoglobin to native hemoglobin suggests that cross-linking hemoglobin between Lys alpha 99 residues prevents CO2 binding at the alpha-subunit NH2 termini.     

The dissociation of carbon monoxide from the alpha and the beta subunits of human carbonmonoxy hemoglobin

We have measured the intrinsic CO dissociation rates from the subunits of the human hemoglobin tetramers (alpha CO beta NO)2 and (alpha NO beta CO)2 using microperoxidase and a stopped-flow spectrophotometer. The dissociation of NO is negligible. The rate constants for the and the subunits are similar (0.014 s-1 vs. 0.011 s-1, respectively, at pH 7, 20 C; and 0.016 s-1 for both in the presence of inositol hexaphosphate), indicating that they are equivalent in the first step of the CO dissociation. Therefore, the chain unequality observed in the third and fourth steps (Samaja, M., Rovida, E., Niggeler, M., Perrella, M., and Rossi-Bernardi, L. (1987). J. Biol. Chem.: 262, 4528-4533) are not due to the intrinsic properties of the subunits, but to the conformational state of the molecule.     

Cooperative cyanide dissociation from ferrous hemoglobin.

Rapid reduction of cyano-met hemoglobin (Hb+CN-) leads to the formation of an intermediate species, the cyanide derivative of ferrous hemoglobin, which dissociates to unliganded hemoglobin because of the extremely low affinity of the ligand for the ferrous heme iron. The properties of the intermediate were studied by transient spectroscopy in human hemoglobin and its isolated alpha and beta chains, in the presence and absence of CO. When mixing with dithionite, the time courses of reduction of the heme iron and dissociation of cyanide overlap considerably; addition to the reaction mixture of the redox indicator methyl viologen considerably increases the rate of reduction and allows unequivocal determination of the spectroscopic and kinetic properties of the intermediate. The results show that (i) the dissociation of cyanide from the isolated alpha and beta chains (as well as the (alpha CO)2(beta + CN-)2 hybrid) is a simple process; (ii) the two chains display similar rate parameters, but show spectroscopic inequivalence, both in the Soret and the visible regions; (iii) cooperative effects are shown to control the rate of dissociation of cyanide from hemoglobin, similarly to what happens for oxygen; and (iv) allosteric effectors (typically inositol hexaphosphate) increase the overall rate of dissociation by stabilization of the T state. We have, therefore, shown for the first time that the dissociation of cyanide from ferrous hemoglobin is controlled by the quaternary state, thereby adding one more ligand to the analysis of the structure-function relationships in hemoglobin.     

The carbon monoxide derivative of human hemoglobin carrying the double mutation LeuB10-->Tyr and HisE7-->Gln on alpha and beta chains probed by infrared spectroscopy

The fine structural properties of the distal heme pocket have been probed by infrared spectroscopy of ferrous carbon monoxy human hemoglobin mutants carrying the mutations LeuB10-->Tyr and HisE7-->Gln on the alpha, beta, and both chains, respectively. The stretching frequency of iron-bound carbon monoxide occurs as a single broad band around 1943 cm(-1) in both the alpha and the beta mutated chains. Such a frequency value indicates that no direct hydrogen bonding exists between the bound CO molecule and the TyrB10 phenolic oxygen, at variance with other naturally occurring TyrB10, GlnE7 nonvertebrate hemoglobins. The rates of carbon monoxide release have been determined for the first time by a Fourier transform infrared spectroscopy stopped-flow technique that allowed us to single out the heterogeneity in the kinetics of CO release in the alpha and beta chains for the mutated proteins and for native HbA. The rates of CO release are 15- to 20-fold faster for the mutated alpha or beta chains with respect to the native ones consistent with the lack of distal stabilization on the iron-bound CO molecule. The present results demonstrate that residues in key topological positions (namely E7 and B10) for the distal steric control of the iron-bound ligand are not interchangeable among hemoglobins from different species.     

Determination of the rate and equilibrium constants for oxygen and carbon monoxide binding to R-state human hemoglobin cross-linked between the alpha subunits at lysine 99

The kinetics of O2 and CO binding to R-state human hemoglobin A0 and human hemoglobin cross-linked between the alpha chains at Lys99 residues were examined using ligand displacement and partial photolysis techniques. Oxygen equilibrium curves were measured by Imai's continuous recording method (Imai, K. (1981) Methods Enzymol. 76, 438-449). The rate of the R to T transition was determined after full laser photolysis of the carbon monoxide derivative by measuring the resultant absorbance changes at an isosbestic point for ligand binding. Chemical cross-linking caused the R-state O2 affinity of alpha subunits to decrease 6-fold compared with unmodified hemoglobin. This inhibition of O2 binding was the result of both a decrease in the rate constant for ligand association and an increase in the rate constant for dissociation. The O2 affinity of R-state beta subunits was reduced 2-fold because of an increase in the O2 dissociation rate constant. These changes were attributed to proximal effects on the R-state hemes as the result of the covalent cross-link between alpha chain G helices. This proximal strain in cross-linked hemoglobin was also expressed as a 5-fold higher rate for the unliganded R to T allosteric transition. The fourth O2 equilibrium binding constant, K4, measured by kinetic techniques, could be used to analyze equilibrium curves for either native or cross-linked hemoglobin. The resultant fitted values of the Adair constants, a1, a2, and a3 were similar to those obtained when K4 was allowed to vary, and the fits were of equal quality. When K4 was fixed to the kinetically determined value, the remaining Adair constants, particularly a3, became better defined.     

Double-mixing kinetic studies of the reactions of methyl isocyanide and CO with diliganded intermediates of hemoglobin: alpha 2CO beta 2 and alpha 2 beta 2CO

Kinetics of the reactions of CO and methyl isocyanide with two diliganded intermediates of hemoglobin, alpha 2CO beta 2 and alpha 2 beta 2CO, have been studied by double-mixing and microperoxidase methods. The valency hybrids were prepared by high-pressure liquid chromatography. The reaction time courses of ligand combination and dissociation with both of the ligands were biphasic, and in CO combination reaction the zero-time amplitudes of the two phases were independent of the protein concentration. In the presence of 2 M urea the reaction time course was clearly dependent on protein concentration, as the zero-time amplitude of the fast phase increased at lower protein concentrations. These two observations indicate that little dissociation of tetramers into dimers occurs in the absence of urea. Consistent with this, the kinetic data for the reactions of CO best fit a reaction model consisting of two tetrameric species not in rapid equilibrium with each other. Various considerations, however, suggest that the reaction model is more appropriately described as 2D in equilibrium R in equilibrium T. The reaction of triliganded species (Hb4(CO)2Me1) with methyl isocyanide was monophasic, and the reaction model suggested a fast T in equilibrium R structural change after the binding of the third ligand. Although the precise structural nature of the two species remains undefined, it is concluded that the biphasicity in the reactions of the two hybrids is characteristic of the diliganded species only and is independent of the nature of the ligand.     

Determination of equilibrium constants for a sequential model of dioxygen binding by hemoglobin-inositol hexaphosphate complexes: the structural pathway from deoxy- to oxy-hemoglobin

The affinity of human hemoglobin (Hb4) for dioxygen was determined in 0.050 M bistris, 0.005 M inositol hexaphosphate (IHP) at pH 7.0 and 20.0 degrees C. Binding of dioxygen by Hb4 was determined by detailed spectroscopic analysis of the absorption spectrum in the region from 460 to 620 nm. The absorption spectrum of samples at intermediate values of fractional saturation (F) could not be resolved into components of Hb4 and (HbO2)4 without generating a residual spectrum, the amplitude of which was greatest at F from 0.4 to 0.5 and least at values of F of 0 and 1. An equation of state for dioxygen binding by the Hb4-IHP complex was formulated and tested by its ability to predict (i) the equilibrium binding curve and (ii) the variation in amplitude of the residual spectrum with F. The equilibrium binding data was fitted to the following equation of state: (Formula: see text) where K1 is the equilibrium constant for binding of dioxygen to an alpha chain of the Hb4-IHP complex, K2 is the constant for the second alpha chain, K3 is the equilibrium constant for the large-scale conformational change, K4 is the equilibrium constant for binding of oxygen by both beta chains, and (L) is the ligand concentration. The best-fitting values were as follows: K1, 0.03497 mm Hg-1; K2, 0.01368 mm Hg-1; K3, 2.44; K4, 0.0008867 mm Hg-2. The residual spectra were attributed to differential loading of dioxygen by the alpha and beta chains. Equations of state for F of each chain are presented, and the amplitude of the residual spectra was shown to be accurately predicted by the differences in F of each chain when subjected to the constraint that the best-fitting values of K1-K4 be used in predicting saturation of each chain with dioxygen.     

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 recombination to the alpha and beta subunits of human hemoglobin

The rebinding of CO, O2, NO, methyl, ethyl, n-propyl, and n-butyl isocyanide to isolated alpha and beta chains and intact hemoglobin at pH 7, 20 degrees C was examined both during and after a 30-ns dye laser pulse. The resultant absorbance changes were analyzed in terms of a linear three-step reaction scheme: Hb + X in equilibrium with C in equilibrium with B in equilibrium with A or HbX, where A is the final bound state, and C and B are geminate states. Rate constants were assigned for each of the transitions in this mechanism using fitting procedures described previously for analyzing ligand rebinding to sperm whale myoglobin at room temperature (Gibson, Q. H., Olson, J. S., McKinnie, R. E., and Rohlfs, R. J. (1986) J. Biol. Chem. 261, 10228-10239). Five major conclusions were obtained. First, initial geminate recombination phases for the NO and O2 complexes of hemoglobin and its isolated subunits exhibit half-times equal to approximately 12 and approximately 440 ps, respectively. These values are in excellent agreement with more direct, picosecond measurements of the geminate recombination of HbNO (Cornelius, P. A., Hochstrasser, R. M., and Steele, A. W. (1983) J. Mol. Biol. 163, 119-128) and HbO2 (Friedman, J. M., Scott, T. W., Fisanick, G. J., Simon, S. R., Findsen, E. W., Ondrias, M. R., and MacDonald, V. W. (1985) Science 229, 187-229) following extremely short laser pulses. Second, the correspondence between our nanosecond measurements and the published picosecond data suggests strongly that the intrinsic photochemical yield of all ferrous, hexacoordinate heme complexes approaches one. Third, the major differences between the isolated alpha and beta chains involve the rate of ligand migration to the solvent, kC----X and the extent of recombination from the second geminate state, C, as measured by the ratio kC----B/kC----X. Fourth, for both isolated chains and intact hemoglobin, the rate and equilibrium constants for the formation of the initial O2 geminate state starting from ligand in the solvent (i.e. kX----B and KX----B) are 5-10 times greater than the corresponding parameters for the formation of the first CO geminate state. Fifth, the rate-limiting step for NO, O2, and isonitrile binding to hemoglobin and its isolated subunits is ligand migration up to the initial geminate state (i.e. kX----B). In the case of CO binding, both migration to state B and iron-ligand bond formation (kB----A) affect the overall, bimolecular association rate constant.     

Oxygen equilibria of hybrid-heme hemoglobins containing proto- and mesoheme groups. On the nonequivalence of alpha and beta chains.

Hybrid-heme hemoglobins, alpha(meso)2beta(proto)2 and alpha(proto)2beta(meso)2, were prepared, and the O2 equilibria of their alpha and beta chains were measured separately at the isosbestic points of the partner chains at different pH values and in the presence and absence of inositol hexaphosphate. The Adair equation was extended to distinguish between the O2 saturations of the alpha and beta chains, and the seven equilibrium parameters were obtained by curve fitting to those equations. The results showed that the beta chains have an affinity slightly higher than the alpha chains in the binding of the first O2 molecule. For the second O2 molecule, the molecular species that has been oxygenated on the alpha chain has a higher affinity than that carrying O2 on the beta chain. The slopes of the Hill plots were higher for the alpha chain. The O2 saturation curves for the alpha and beta chains were calculated from the parameters averaged for the hybrids alpha(meso)2beta(proto)2 and alpha(proto)2beta(meso)2 in order to cancel the effects of the heme replacement. The curves showed that the difference in O2 saturation between the two kinds of chains depends on the conditions and on the degree of O2 saturation. It was concluded that the functional difference between the chains is small enough so that it is not required to modify the models already accepted for the cooperativity of hemoglobin.     

Studies of human hemoglobin intermediates. The double mixing method for studying the reactions of the species Hb4(CO) and Hb4(CO)2

Using the double mixing method we have studied the reactions of the partially liganded species (Hb4, Hb4L1, Hb4L2, Hb4L3) of normal human hemoglobin with carbon monoxide. In the first mixing, oxygen is removed from the species Hb4(O2) chi (CO) gamma and at the second mixing the species Hb4(CO) gamma reacts with CO. At 90% saturation of oxyHb with CO the main intermediate species are Hb4(CO)3 and Hb4(CO)2, and at 10% saturation Hb4 and Hb4(CO). The four CO-combination rate constants determined are: l'1 = 1 X 10(5) M-1 S-1, l'2 = 7 X 10(5) M-1 S-1, l'3 = 2 X 10(5) M-1 S-1 and l'4 = 4.8 X 10(6) M-1 S-1. The results indicate that there is no monotonic increase in the successive CO-combination rate constants. It is difficult to explain these results on the basis of the two-state model (Monod et al., 1965) or the stereochemical model of Perutz (1970).     

The hemoglobin cyanomet ligation analogue and carbon monoxide induce similar allosteric mechanisms

Current thermodynamic models of protein cooperativity predicting sigmoidal ligand equilibrium curves differ in the assumptions regarding the structural/functional properties of the intermediate ligation states. Quantitative information on the intermediates cannot be extracted from the equilibrium curves, but must be obtained from direct studies of the intermediates. Since the intermediates are intrinsically unstable species, ligation analogues with reduced mobility are indispensable tools for cooperativity studies provided that the tertiary/quaternary changes triggered by the ligation analogue are similar to those observed using the physiological ligands. We demonstrate that the valency exchange reactions occurring in mixtures of deoxy and cyanomethemoglobin yield non-random distributions of deoxy/cyanomet intermediates that resemble those observed in the equilibrium with carbon monoxide. Previous and new data using the analogue, in agreement with the studies of the CO intermediates, indicate that the mechanism of hemoglobin cooperativity is neither purely concerted nor sequential nor combinatorial, but contains some elements of each of these models.     

Patterns of hemoglobin assembly in reticulocytes of sickle cell trait individuals.

Venous blood was obtained from five sickle cell trait donors with relatively high hemoglobin S concentrations (40% of total hemoglobin) and five donors with unusually low hemoglobin S concentrations (25 to 30%). A fraction of cells with 15 to 20% reticulocytes was isolated from the blood and incubated with [3H]leucine in a medium supporting protein synthesis for various times from 1.25 to 60 min. Previous studies showed an imbalance in globin chain synthesis in reticulocytes of "low hemoglobin S" donors which suggested the presence of an alpha-thalassemia gene; reticulocytes of "high hemoglobin S" donors had balanced globin chain synthesis (DeSimone, J., Kleve, L., Longley, M.A., and Shaeffer, J. (1974) Biochem. Biophys. Res. Commun. 59, 564-569). In the present study the soluble phase of the 3H-labeled reticulocytes was examined by electrophoresis on strips of cellulose acetate. The tetramer hemoglobins A and S were separated from each other and from a small pool of free, newly synthesized alpha and beta chains. Kinetics of labeling studies showed that the free alpha and beta chains were intermediates in tetramer hemoglobin assembly. The distribution of radioactivity between the alpha and beta chains of each of the electrophoretically isolated components were determined by separation of their globin chains on CM-cellulose columns. After 5 min of 3H-labeling of the reticulocytes from donors with 40% hemoglobin S the ratio of newly synthesized alpha chains to beta chains in the tetramer hemoglobins A and S ranged from 0.37 to 0.58. This ratio increased with longer labeling times. Almost all of the radioactivity of the free chain intermediates was in the alpha chain. These results confirmed the presence of a significant pool of newly synthesized alpha chains and a normal pattern of hemoglobin assembly in which initially unlabeled alpha chains combined with labeled beta chains when the cells were exposed to [3H]leucine. Conversely, in the reticulocytes of donors with 25 to 30% hemoglobin S the ratio of newly synthesized alpha chains to beta chains in the completed hemoglobins A and S ranged from 0.96 to 1.37 and remained unchanged throughout the 3H-labelling period. The radioactivity of the free alpha chain pool was substantially less that the total radioactivity of the betaA and betaS chain pools. These results confirmed the existence of a decreased pool size of soluble alpha chain intermediates and a pattern of hemoglobin assembly consistent with the presence of the alpha-thalassemia gene.     

What the intermediate compounds in ligand binding to hemoglobin tell about the mechanism of cooperativity

The populations of the intermediates in concentrated solutions of hemoglobin A0 equilibrated at various PCO values, pH 7.0, 0.1 M KCl, and 20 degrees C, have been determined using cryogenic methods. Data on CO saturations and distributions of intermediates were analysed in terms of the free energies of dimer-tetramer assembly of the intermediates (G.K. Ackers and F.R. Smith, Annu. Rev. Biophys. Chem. 16 (1987) 583). The cooperative free energy value of the singly ligated species was approximately one-half the total cooperative energy. The cooperative free energy value of the doubly ligated species was not significantly different from that of carboxyhemoglobin. Because of experimental error, the observed difference in concentrations among the populations of the doubly ligated species cannot be taken as indicative of their functional heterogeneity. Additional studies on some NO intermediates have emphasized that (alpha 1 beta 1)(alpha 2 beta 2)X, a key intermediate in the formulation of the 'third-state' hypothesis in the deoxy/cyanomethemoglobin system, has a free energy value for dimer-tetramer assembly which is critically dependent on the nature of the ligand X as suggested by Ackers and Smith (reference as cited above).     

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).     

Microspectrophotometric studies on single crystals of the tryptophan synthase alpha 2 beta 2 complex demonstrate formation of enzyme-substrate intermediates

Microspectrophotometry of single crystals of the tryptophan synthase alpha 2 beta 2 complex from Salmonella typhimurium is used to compare the catalytic and regulatory properties of the enzyme in the soluble and crystalline states. Polarized absorption spectra demonstrate that chromophoric intermediates are formed between pyridoxal phosphate at the active site of the beta subunit and added substrates, substrate analogs, and reaction intermediate analogs. Although the crystalline and soluble forms of the enzyme produce some of the same enzyme-substrate intermediates, including Schiff base and quinonoid intermediates, in some cases the equilibrium distribution of these intermediates differs in the two states of the enzyme. Ligands which bind to the active site of the alpha subunit alter the distribution of intermediates formed at the active site of the beta subunit in both the crystalline and soluble states. The three-dimensional structures of the tryptophan synthase alpha 2 beta 2 complex and of a derivative with indole-3-propanol phosphate bound at the active site of the alpha subunit have recently been reported (Hyde, C. C., Ahmed, S. A., Padlan, E. A., Miles, E. W., and Davies, D. R. (1988) J. Biol. Chem. 264, 17857-17871). Our present findings help to establish experimental conditions for selecting defined intermediates for future x-ray crystallographic analysis of the alpha 2 beta 2 complex with ligands bound at the active sites of both alpha and beta subunits. These crystallographic studies should explain how catalysis occurs at the active site of the beta subunit and how the binding of a ligand to one active site affects the binding of a ligand to the other active site which is 25 A away.     

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.     

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.