The binding of CO2 to human hemoglobin.

CO2-dissociation curves of concentrated human deoxy- and carbonmonoxyhemoglobin at 37 degrees, pH 7.6 to 7.0, PCO2 equal to 10 to 160 mm Hg, have been obtained by a rapid mixing and ion exchange technique. The CO2-dissociation curves for deoxyhemogloblin can only be fitted by assuming two classes of binding sites for carbon dioxide. The simplest way to account for the experimental data is to assume that the alpha-amino groups of the alpha and beta chains react with carbon dioxide with affinities that differ by at least a factor of 3. No difference in reactivity with CO2 was found among the four terminal alpha-amino groups of carbonmonoxyhemoglobin.     

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.     

Antagonistic interaction between oxygenation-linked lactate and CO2 binding to human hemoglobin

Oxygen binding to hemoglobin (Hb) depends on allosteric effectors (CO(2), lactate and protons) that may increase drastically in concentration during exercise. The effectors share common binding sites on the Hb molecules, predicting mutual interaction in their effects on Hb (de)oxygenation. We analysed the effects of lactate and CO(2), separately and in combination, on O(2) binding of purified human Hb at 37 degrees C and physiological pH and chloride values. We demonstrate pH-dependent, inhibitory interactions between lactate binding and CO(2) binding (carbamate formation); at pH 7.4, physiological CO(2) tension ( approximately 43 mm Hg) reduced lactate binding more markedly ( approximately 75%), than lactate (50 mM) inhibited carbamate formation ( approximately 25%). In contrast to previous studies on blood and Hb solutions, we moreover find that added lactate neither 'reverses' oxylabile carbamate formation (resulting in lower carbamate levels in deoxyHb than in oxyHb) nor exerts greater allosteric effects on Hb-O(2) affinity than equal increases in chloride ion concentrations.     

Carbon-13 NMR studies of 13CO binding to human hemoglobin

In the ¹³C NMR spectrum of hemoglobin A carbonylated with ¹³CO, separate resonances can be distinguished at 207.04 ppm and 206.60 ppm (with respect to the ¹³C resonance of external tetramethyl-silane) for ¹³Co bound to the α and β chains of the hemoglobin tetramer. A study of the ¹³Co derivatives of the isolated α and β chains, and of the abnormal hemoglobin M_IWATE which contains α chains which are in the met [Fe(III)] form and do not bind CO, has permitted an assignment of the high field (206.60 ppm) resonance to the β chain ¹³CO and the low field one to the α chain ¹³CO. The identification of these ¹³Co resonances permits a study of the differences in the chemistry of the α and β heme units in intact hemoglobin. Some results on the differences in the redox behavior of these chains are included.     

Interaction between alpha 1 and beta 1 subunits of human hemoglobin

We prepared normal and modified alpha and beta globulin chains in which C-terminal residues were enzymatically removed. The CD spectra of the deoxy form of these chains and the reconstituted modified Hb's were measured in the Soret region. The CD spectra of the modified Hb's were markedly different from the arithmetic means of respective spectra of their constituent chains. This difference was ascribed to the interaction between alpha 1 and beta 1 subunits to make the alpha 1 beta 1 dimer. The peak wavelength of the difference CD spectra could be classified into two groups, one was 433 +/- 1 nm and the other 437 +/- 1 nm. A comparison of this classification with the previously identified quaternary structures revealed that the R and T structures showed a maximum of the difference CD spectra at 437 +/- 1 nm and 433 +/- 1 nm, respectively. These results indicated that the R and T structures differed in the interaction between alpha 1 and beta 1 subunits.     

Conformational studies on the beta subunits of human hemoglobin and their arginyl-COOH peptides.

The beta subunits of hemoglobin upon alkylation of the cysteinyl residues with iodoacetamide showed a sedimentation velocity with an S20w, near 1.8 as for monomeric subunits. They reacted with alpha chains to give a tetrameric hemoglobin with a sedimentation constant near 4.4. Their CD spectrum was indistinguishable from that of untreated beta chains below 270 nm, otherwise they showed some deviation that became pronounced in the Soret region, where the optical activity of the alkylated subunits was definitely lower than that of the native subunits. Upon removal of the heme the apo-beta subunits showed a decreased optical activity in the far-uv region of the spectrum indicating a substantial loss of helical content. Their sedimentation behavior was consistent with the presence of large aggregates, which dissociates into monomers upon reconstitution with cyanoheme. The apo-beta subunits could be renatured from 6 M guanidine hydrochloride. They showed a stoichiometric reaction with heme in the molar ratio 1:1. Upon reconstitution with the heme their optical activity became similar to that of the native beta chains in the far-uv region of the spectrum, but remained lower in the near-uv and Soret regions. After acylation of the lysyl residues with citraconic anhydride the apo-beta subunits were digested with trypsin and the arginyl-COOH peptides beta(1-30), beta(31-40), beta(41-104), and beta(105-146) were separated by gel chromatography. With the exception of the peptide beta/105-146), which was insoluble at neutral pH, the sedimentation behavior of the other peptides showed the presence of small polymers. The sedimentation behavior of the peptide beta(31-40) was not tested. The percentage of alpha helix, beta conformation, and of random coil (or unordered structure) of the various proteins and peptides was measured fitting their CD spectra in the far-uv region with the parameter published by Y.H. Chen et al. ((1974), Biochemistry 13, 3350) and by N. Greenfield and G.D. Fasman ((1969), Biochemistry 8, 4108). In this way the helical content of the native and reconstituted alkylated beta subunits appeared to be near 76%, a value very near to that present in the same subunits in the hemoglobin crystal. The helical content of the apo-beta subunits in 0.04 M borate buffer at pH 9.6 decreased to a value near 45%. The helical content of the isolated peptides in electrolyte solutions was in any case near 10% indicating an almost complete loss of the structure that they have in the hemoglobin crystal. Cyanoheme reacted with the peptide beta(41-104), however, the reaction was not stoichiometric indicating a low affinity of the heme for the peptide. With the exception of the peptide beta(31-104), all of the other peptides recovered some of their helical structure when dissolved in 50% methanol. Notably also the apo-beta subunits did so suggesting that the loss of structure upon the removal of the heme could be in part due to the exposure of the heme pocket to water.     

Kinetic resolution of ligand binding to the alpha and beta chains within human hemoglobin.

Nitric oxide has been used as a chain-specific, spin label of unliganded heme groups present in kinetic mixtures of human hemoglobin and n-butyl isocyanide. In these experiments, deoxyhemoglobin was reacted with n-butyl isocyanide for a controlled time and then mixed rapidly with a high concentration of nitric oxide to fill residual, unoccupied heme sites. The final mixture was frozen immediately after formation to prevent any displacement of bound isonitrile. The EPR spectrum of the frozen sample was resolved into alpha and beta nitric oxide components; these reflect the relative proportions of alpha- and beta-heme sites which were unoccupied by n-butyl isocyanide. Individual time courses for the alpha and beta subunits were obtained by varying the time between the formation of the isonitrile/hemoglobin mixture and its reaction with nitric oxide. At pH 7.0 only the beta chain time course exhibits an initial rapid phase; the alpha chain time course is monophasic, exhibiting almost, exponential behavior. This result shows unequivocally that the beta-hemes within deoxyhemoglobin react much more rapidly with n-butyl isocyanide than the alpha hemes.     

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.     

Carbon 13 resonances of 13CO2 carbamino adducts of alpha and beta chains in human adult hemoglobin.

The principal component of normal adult human hemoglobin Ao, was equilibrated under various conditions with 13CO2. In addition, derivatives containing specifically carbamylated NH2-terinal groups in alpha or beta chains, or both, were prepared by treatment with cyanate, and equilibrated likewise to allow the identification of specific resonances observed by 13C nuclear magnetic resonance. In deoxyhemoglobin, a resonanance at 29.2 ppm upfield of external CS2 was assigned to the alpha chain terminal adduct, and one at 29.8 ppm to the beta chain terminal adduct. In the liganded state as the CO derivative, the terminal adduct on both chains showed a common resonance position at 29.8 ppm. Small effects of pH on the resonance positions were observed. Under certain conditions, a resonance was observed at 33.4 ppm, probably not ascribable to a carbamino compound. A carbamino resonance that became prominent at higher pH was found at 28.4 ppm, and is tentatively ascribed to one or more adducts on epsilon amino groups. The beta chain resonances in particular are minimized by the presence of inositol hexaphosphate or 2,3-diphosphoglycerate. Quantitative analysis of the resonance intensities shows that the effects of conversion from the deoxy to the liganded state in reducing the degree of carbamino adduct is much more pronounced for the beta than for the alpha chains.     

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)     

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.     

Selenium binding to human hemoglobin via selenotrisulfide

Selenotrisulfide (e.g., glutathione selenotrisulfide (GSSeSG)) is an important intermediate in the metabolism of selenite. However, its reactivity with biological substances such as peptides and proteins in the subsequent metabolism is still far from clearly understood, because of its chemical instability under physiological conditions. Penicillamine (Pen) is capable of generating a chemically stable and isolatable selenotrisulfide, PenSSeSPen. To explore the metabolic fate of selenite in red blood cells (RBC), we investigated the reaction of selenotrisulfide with human hemoglobin (Hb) using PenSSeSPen as a model. PenSSeSPen rapidly reacted with Hb under physiological conditions. From the analysis of selenium binding using the Langmuir type binding equation, the apparent binding number of selenium per Hb tetramer almost corresponded to the number of reactive thiol groups of Hb. The thiol group blockade of Hb by iodoacetamide treatment completely inhibited the reaction of PenSSeSPen with Hb. In addition, MALDI-TOF mass spectrometric analysis of the selenium-bound Hb revealed that PenSSe moiety binds to the beta subunits of Hb. Overall, the reaction of PenSSeSPen with Hb appears to involve the thiol exchange between Pen and the cysteine residues on the beta subunit of Hb.     

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).