Oxygen binding to sickle cell hemoglobin.

The extent of oxygen binding and light scattering of concentrated solutions of hemoglobin S have been determined as a function of oxygen partial pressure using a thin film optical cell. Nearly reversible oxygen binding is observed as witnessed by the small hysteresis found between slow deoxygenation and reoxygenation runs. High co-operativity is noted from unusually large concentration-dependent Hill coefficients when aggregated hemoglobin S is present. The application of linkage theory with the inclusion of non-ideal solution properties permits a test of various simple models for oxygen binding to both the monomer (α₂β₂^s) and polymer (aggregated) phase. It is concluded that oxygen binding to the polymer is either negligible or small under present experimental conditions. Phase diagrams of the solution concentration in equilibrium with polymer phase as a function of oxygen partial pressure are derived using best fit values of polymer parameters.     

Oxygen equilibria of hemoglobin A and hemoglobin S valency hybrids.

Oxygen equilibrium determinations with “unsymmetrical” MetHb/Hb hybrids derived from human hemoglobins A and S are reported. All four of the possible hybrids have higher oxygen affinity than the parent hemoglobins. The α₂^Metβ₂^S hybrid has a lower oxygen affinity than that of α₂^Metβ₂^S. However, both the β^Met hybrids have similar oxygen affinity. The Bohr value of α₂^Metβ₂^S is more negative than that of α₂^Metβ₂^A while the β^Met hybrids appear to have almost identical Bohr values. These findings favor the view that α and β chains in hemoglobin A have different conformations and indicate that hemoglobin S has a β-chain conformation different from that of β-chain of hemoglobin A. This difference is probably carried into the oxygenation properties of the α-chain in such a way as to be reflected only when the β chain is oxidized.     

Oxygen binding to partially nitrosylated hemoglobin

Reactions of nitric oxide (NO) with hemoglobin (Hb) are important elements in protection against nitrosative damage. NO in the vasculature is depleted by the oxidative reaction with oxy Hb or by binding to deoxy Hb to generate partially nitrosylated Hb (Hb–NO). Many aspects of the formation and persistence of Hb–NO are yet to be clarified. In this study, we used a combination of EPR and visible absorption spectroscopy to investigate the interactions of partially nitrosylated Hb with O₂. Partially nitrosylated Hb samples had predominantly hexacoordinate NO–heme geometry and resisted oxidation when exposed to O₂ in the absence of anionic allosteric effectors. Faster oxidation occurred in the presence of 2,3-diphosphoglycerate (DPG) or inositol hexaphosphate (IHP), where the NO–heme derivatives had higher levels of pentacoordinate heme geometry. The anion-dependence of the NO–heme geometry also affected O₂ binding equilibria. O₂-binding curves of partially nitrosylated Hb in the absence of anions were left-shifted at low saturations, indicating destabilization of the low O₂ affinity T-state of the Hb by increasing percentages of NO–heme, much as occurs with increasing levels of CO–heme. Samples containing IHP showed small decreases in O₂ affinity, indicating shifts toward the low-affinity T-state and formation of inert α-NO/β-met tetramers. Most remarkably, O₂-equilibria in the presence of the physiological effector DPG were essentially unchanged by up to 30% NO–heme in the samples. As will be discussed, under physiological conditions the interactions of Hb with NO provide protection against nitrosative damage without impairing O₂ transport by Hb's unoccupied heme sites. This article is part of a Special Issue entitled: Oxygen Binding and Sensing Proteins.     

The demonstration of asymmetric hemoglobin hybrids by polyacrylamide electrophoresis.

A simpler, more economical technique than previously reported, that of conventional polyacrylamide gel electrophoresis alone, is described for the detection of asymmetric hemoglobin hybrids of the forms alphaXalphaYbeta2 and alpha2betaXbetaY when bloods from individuals with alpha and beta chain variants were examined. The presence of alpha chain variant hybrids, never before reported, is further evidence that hybrid formation is a more widespread phenomenon than has previously been thought of. Hybrids were found in artificial mixtures of hemoglobins and more importantly, are also reported here for the first time in bloods of individuals heterozygous for hemoglobin variants. These hybrid tetramers were as stable as the parent hemoglobins when examined under anaerobic conditions. The involvement of HbF in the formation of hybrids of the type alpha2betagamma is reported, and an analysis of the possible role of these as well as alpha2betaAbetaS hybrids in the sickling process is presented.     

NO and CO binding profiles of hemoglobin vesicles as artificial oxygen carriers

Hemoglobin vesicles (HbVs) are artificial oxygen carriers encapsulating purified and concentrated Hb solution in phospholipid vesicles (liposomes). We examined in-vitro reaction profiles of a formulation of HbV with NO and CO in anaerobic and aerobic conditions using stopped-flow spectrophotometry and a NO electrode. Reaction rate constants of NO to deoxygenated and oxygenated HbV were considerably smaller than those of cell-free Hb because of the intracellular NO-diffusion barrier. The reaction of CO with deoxygenated HbV was slightly slower than that of cell-free Hb solely because of the co-encapsulated allosteric effector, pyridoxal 5'-phosphate. The NO depletion in an aerobic condition in the presence of empty vesicles was monitored using a NO electrode, showing that the hydrophobic bilayer membrane of HbV, which might have higher gas solubility, does not markedly facilitate the O(2) and NO reaction, and that the intracellular Hb is the major component of NO depletion. In conclusion, HbV shows retarded gas reactions, providing some useful information to explain the absence of vasoconstriction and hypertension when they are intravenously injected.     

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.     

Oxygen binding and NO scavenging properties of truncated hemoglobin, HbN, of Mycobacterium smegmatis

Unraveling of microbial genome data has indicated that two distantly related truncated hemoglobins (trHbs), HbN and HbO, might occur in many species of slow-growing pathogenic mycobacteria. Involvement of HbN in bacterial defense against NO toxicity and nitrosative stress has been proposed. A gene, encoding a putative HbN homolog with conserved features of typical trHbs, has been identified within the genome sequence of fast-growing mycobacterium, Mycobacterium smegmatis. Sequence analysis of M. smegmatis HbN indicated that it is relatively smaller in size and lacks N-terminal pre-A region, carrying 12-residue polar sequence motif that is present in HbN of M. tuberculosis. HbN encoding gene of M. smegmatis was expressed in E. coli as a 12.8kD homodimeric heme protein that binds oxygen reversibly with high affinity (P50 approximately 0.081 mm Hg) and autooxidizes faster than M. tuberculosis HbN. The circular dichroism spectra indicate that HbN of M. smegmatis and M. tuberculosis are structurally similar. Interestingly, an hmp mutant of E. coli, unable to metabolize nitric oxide, exhibited very low NO uptake activity in the presence of M. smegmatis HbN as compared to HbN of M. tuberculosis. On the basis of cellular heme content, specific nitric oxide dioxygenase (NOD) activity of M. smegmatis HbN was nearly one-third of that from M. tuberculosis. Additionally, the hmp mutant of E. coli, carrying M. smegmatis HbN, exhibited nearly 10-fold lower cell survival under nitrosative stress and nitrite derived reactive nitrogen species as compared to the isogenic strain harboring HbN of M. tuberculosis. Taken together, these results suggest that NO metabolizing activity and protection provided by M. smegmatis HbN against toxicity of NO and reactive nitrogen is significantly lower than HbN of M. tuberculosis. The lower efficiency of M. smegmatis HbN for NO detoxification as compared to M. tuberculosis HbN might be related to different level of NO exposure and nitrosative stress faced by these mycobacteria during their cellular metabolism.     

Oxygen binding and aggregation of bullfrog hemoglobin

The hemoglobin of the bullfrog, Rana catesbeiana, forms aggregates larger than tetramers in two ways. The first, which results from intermolecular disulfide bonds, can be prevented by treatment with iodoacetamide. The second way results from the association of the deoxygenated forms of the two major components, B and C, to form reversibly an aggregate which is believed to be a trimer, BC2. The sedimentation velocity data show that the stoichiometry of the aggregate cannot be 1:1. The electrophoretic pattern of the deoxygenated B/C mixture suggests that the association is not indefinite. No significant aggregation of the separate deoxygenated tetramers of the components nor of the oxygenated components or mixture occurs. Gel chromatography of the oxygenated forms of components B and C and of mixtures indicates that the B and C tetramers both form dimers upon dilution with a dissociation constant of 2-3 micron. The oxygen-binding data indicate that the B/C aggregate has a much lower oxygen affinity than its constituent tetramers. Dissociation of the low affinity B/C aggregate to higher affinity B and C tetramers with increasing oxygenation gives rise to enhanced cooperativity as measured by the Hill coefficient which is maximal near 75-80% oxygenation and is as high as 4.1 at a heme concentration of 15 mM.     

Kinetics of carbon monoxide binding to fully and partially reduced human hemoglobin valency hybrids.

The kinetics of carbon monoxide binding following fast reduction of the valency hybrids alpha2+betaCO2 and alphaCO2beta+2 by hydrated electrons have been studied at different degrees of reduction. The results show that at pH 6.0 and 7.0 reduction of one heme group yields a species which reacts fast with carbon monoxide (rate constant of the order of 10(6) M-1S-1). At pH 6.0 the intermediates alphaCO2beta2 and alpha2betaCO2 bind carbon monoxide with a rate characteristic of the T state. At pH 7.0 alphaCO2beta2 is for the greater part in the T state, while in the case of alpha2betaCO2 the R and the T state are about equally populated.     

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

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

Oxygen binding characteristics of Artemia hemoglobin domains

• 1.1. The extracellular hemoglobins of the crustacean Artemia can be split into structural and functional domains by limited proteolysis.
• 2.2. The oxygen affinity of the multi-domain fragments increases linearly with decreasing molecular weight.
• 3.3. Cooperativity is expressed only in the intact dimeric molecule and not at the subunit or multi-domain level.

     

Oxygen binding constants for human hemoglobin tetramers

High-precision studies of oxygen binding in hemoglobin (HbA0) solutions at near-physiological concentrations (2-12 mM heme; pHs 7.0-9.1; various buffers) have led to an unanticipated result: an unmeasurably low contribution from the triply ligated species. We have obtained this result from new differential oxygen-binding measurements for human hemoglobin through the use of a thin-layer apparatus, which enables study of solutions at high Hb concentrations. The effect of tetramer dissociation into dimers, which becomes significant at hemoglobin concentrations below 1 mM in heme, is avoided. The analysis of the binding reactions is thus cast in terms of tetramer-binding polynomial written with overall Adair equilibrium constants which directly reflect the contributions of intermediate ligated species. The unmeasurable contribution of the triply ligated species renders the equilibrium constants of the third and fourth stepwise reactions practically undeterminable.     

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.     

Oxygen binding to partially oxidized hemoglobin. Analysis in terms of an allosteric model

We report on oxygen binding to partially oxidized (aquomet) hemoglobin. The fractional saturation with oxygen is evaluated by deconvoluting the optical absorption spectra, in the 500-700 nm wavelength region, in terms of oxyhemoglobin, deoxyhemoglobin and methemoglobin spectral components. Experiments have been performed with auto-oxidized samples and with samples obtained by mixing ferrous hemoglobin with fully oxidized hemoglobin (mixed samples). An increase in oxygen affinity and a decrease in cooperativity are observed on increasing the amount of ferric hemoglobin in the sample. A high cooperativity (nH approximately 2) is maintained even in the presence of 50-60% ferric hemes. Moreover, for equal amounts of methemoglobin the oxygen affinity is lower and the cooperativity higher for mixed samples than for those auto-oxidized. The results are analyzed within the framework of a modified Monod-Wyman-Changeux allosteric model taking into account the effects brought about by the presence of oxidized hemes and of alpha betta dimers. The distribution of ferric subunits within the tetramers in fully deoxygenated and fully oxygenated samples, as derived from the model, provides details on the cooperative behavior of partially oxidized hemoglobin.     

Oxygen binding and oxidation reactions of human hemoglobin conjugated to carboxylate dextran

Human hemoglobin (Hb) conjugated to benzene tetracarboxylate substituted dextran produces a polymeric Hb (Dex-BTC-Hb) with similar oxygen affinity to that of red blood cells (P(50)=28-29 mm Hg). Under physiological conditions, the oxygen affinity (P(50)) of Dex-BTC-Hb is 26 mm Hg, while that of native purified human HbA(0) is 14 mm Hg, but it exhibits a slight reduction in cooperativity (n(50)), Bohr effect, and lacks sensitivity to inositol hexaphosphate (IHP), when compared to HbA(0). Oxygen-binding kinetics, measured by rapid mixing stopped-flow method showed comparable oxygen dissociation and association rates for both HbA(0) and Dex-BTC-Hb. The rate constant for NO-mediated oxidation of the oxy form of Dex-BTC-Hb, which is governed by NO entry to the heme pocket, was reduced to half of the value obtained for HbA(0). Moreover, Dex-BTC-Hb is only slightly more sensitive to oxidative reactions than HbA(0), as shown by about 2-fold increase in autoxidation, and slightly higher H(2)O(2) reaction and heme degradation rates. Dextran-BTC-based modification of Hb produced an oxygen-carrying compound with increased oxygen release rates, decreased oxygen affinity and reduced nitric oxide scavenging, desirable properties for a viable blood substitute. However, the reduction in the allosteric function of this protein and the lack of apparent quaternary T-->R transition may hinder its physiological role as an oxygen transporter.     

The CO and NO Bohr effect of human hemoglobin with and without inositolhexaphosphate.

Using NO and CO as ligands the Bohr effect of human hemoglobin has been measured with and without inositolhexophosphate. It appears that in the absence and presence of inositolhexaphosphate hemoglobin shows a distinct ligand specificity with respect to the Bohr effect. Ligation with NO is accompanied by release of a larger number of Bohr effect. It is shown that this latter result is due to the fact that the number of protons taken up upon binding of inositolhexaphosphate to ligated hemoglobin is larger for HbNO than for HbCO. It is suggested that this additional proton uptake is partially due to a restoration of the saltbridge between His 146beta and Asp 94beta upon addition of IHP.     

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.