The hemoglobin of the common sting-ray, Dasyatis sabina: structural and functional properties.

1. The hemoglobin of the sting-ray, Dasyatis sabina, is both polymorphic and heterogeneous; three components predominate. 2. One major component has two kinds of polypeptide chain, of which one, presumably an alpha-chain, has a blocked NH2-terminus and an arginyl COOH-terminus, whereas carboxypeptidases A and B release tyrosine and histidine from the COOH-terminus of the beta-chain. 3. The amino acid sequence of the beginning NH2-terminal segment of the beta-chain of the major component has been determined. 4. The hemoglobin of the sting-ray, Dasyatis sabina, is highly resistant to urea and does not dissociate readily into subunits. 5. Oxygen binding by the hemoglobin is not affected by organic phosphates or high concentrations of either NaCl or urea. 6. The hemoglobin does not polymerize beyond tetramers. 7. Cooperativity, as monitored by n in the Hill equation, is pH-dependent and maximal between pH 8.5 and 9.0. 8. The hemoglobin has a large Bohr effect; the oxygen affinity is 16 times higher at pH 10 than at pH 6.5.     

Combining the influence of two low O2 affinity-inducing chemical modifications of the central cavity of hemoglobin

HexaPEGylated hemoglobin (Hb), a non-hypertensive Hb, exhibits high O2 affinity, which makes it difficult for it to deliver the desired levels of oxygen to tissues. The PEGylation of very low O2 affinity Hbs is now contemplated as the strategy to generate PEGylated Hbs with intermediate levels of O2 affinity. Toward this goal, a doubly modified Hb with very low O2 affinity has been generated. The amino terminal of the beta-chain of HbA is modified by 2-hydroxy, 3-phospho propylation first to generate a low oxygen affinity Hb, HPPr-HbA. The oxygen affinity of this Hb is insensitive to DPG and IHP. Molecular modeling studies indicated potential interactions between the covalently linked phosphate group and Lys-82 of the trans beta-chain. To further modulate the oxygen affinity of Hb, the alpha alpha-fumaryl cross-bridge has been introduced into HPPr-HbA in the mid central cavity. The doubly modified HbA (alpha alpha-fumaryl-HPPr-HbA) exhibits an O2 affinity lower than that of either of the singly modified Hbs, with a partial additivity of the two modifications. The geminate recombination and the visible resonance Raman spectra of the photoproduct of alpha alpha-fumaryl-HPPr-HbA also reflect a degree of additive influence of each of these modifications. The two modifications induced a synergistic influence on the chemical reactivity of Cys-93(beta). It is suggested that the doubly modified Hb has accessed the low affinity T-state that is non-responsive to effectors. The doubly modified Hb is considered as a potential candidate for generating PEGylated Hbs with an O2 affinity comparable to that of erythrocytes for developing blood substitutes.     

Interactions of nicotinamide adenine dinucleotides with varied states and forms of hemoglobin

Spectrofluorometric techniques were used to quantify NADPH-hemoglobin interactions based on the quenching of NADPH fluorescence upon binding to hemoglobin. Fluorometric titrations were carried out with hemoglobin in varied states and with hemoglobins in which the beta-chain anion site is altered. At pH 6.5 in 0.05 M 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffer, NADPH binds with high affinity, Kd = 1.03 microM, to deoxy human hemoglobin tetramers. Lower affinity binding of NADPH occurs as the beta-chain anion-binding site is discharged by increasing the pH. Moreover, the cofactor binds in a 1:1 ratio to deoxy tetramers, inositol hexaphosphate binds competitively, and binding is decreased in hemoglobins whose structural alterations result in decreased effects of 2,3-diphosphoglycerate. The cofactor binds to oxidized (met) hemoglobin with an estimated Kd of 33.3 microM but has little or no affinity for the oxy form. These results indicate that NADPH binds at the beta-chain anion-binding site and can be considered as a fluorescent analog of 2,3-diphosphoglycerate. Fluorescence measurements gave no indication of NADPH binding to deoxygenated ferrous or ferric myoglobin. Reductive processes within the erythrocyte, such as reduction of met hemoglobin and hemoglobin-catalyzed enzymatic reactions, may be affected by the significant binding of the reduced cofactor to both deoxygenated and oxidized hemoglobin. Cofactor-hemoglobin interactions predict a shift in redox potential as red cells become oxygenated, which may account for unexplained oxygen-linked shifts in red cell metabolism.     

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.     

Interaction between bound cupric ion and spin-labeled cysteine beta-93 in human and horse hemoglobins

The location of the various copper binding sites for horse and human hemoglobin was probed using spin labels attached to the beta-93 cysteine residue. Dipole-dipole interactions between the spin label and bound copper produce a decrease in the amplitude of the spin label spectrum which was used to estimate the Cu(II) spin label distance. By comparing the results with horse and human hemoglobin at 298 and 77 K four different Cu(II) binding sites were identified. The low affinity horse hemoglobin site with the sulfhydryl blocked (site 1) was found to be located 10-13 A from the sulfhydryl spin label on the surface of the molecule. Only with a free sulfhydryl is the site (site 2) in the pocket between the F and H helices closer to the SH-group and the iron populated. It is site 2 which is responsible for the oxidation. In frozen solutions a Cu-nitroxide distance of about 17 A was determined with human hemoglobin. This distance is consistent with the previously postulated location of the "high affinity" human hemoglobin site near the amino terminus of the beta-chain. At 298 K a much shorter Cu-nitroxide distance of about 7 A was calculated for human hemoglobin. This shorter distance at higher temperature also correlated with a slightly smaller value of g11 and A11 for the Cu(II) ESR spectrum. It is postulated that in solution cross-linking between nitrogenous ligands in the region of the amino terminus of one beta-chain and the carboxyl terminus of the other beta-chain can explain this shorter distance. This cross-link could involve histidine beta-143, which is one of the ligands thought to be also involved in site 1. Binding to the "high-affinity" site in solution thus stabilizes the "low-affinity" site 2 relative to site 1 explaining the reported interaction between the "high-affinity" and "low-affinity" sites.     

Altered ligand rebinding kinetics due to distal-side effects in hemoglobin chico (Lysbeta66(E10) --> thr)

Hb Chico is an unusual human hemoglobin variant that has lowered oxygen affinity, but unaltered cooperativity and anion sensitivity. Previous studies showed these features to be associated with distal-side heme pocket alterations that confer increased structural rigidity on the molecule and that increase water content in the beta-chain heme pocket. We report here that the extent of nanosecond geminate rebinding of oxygen to the variant and its isolated beta-chains is appreciably decreased. Structural alterations in this variant decrease its oxygen recombination rates without significantly altering rates of migration out of the heme pocket. Data analysis indicates that one or more barriers that impede rebinding of oxygen from docking sites in the heme pocket are increased, with less consequence for CO rebinding. Resonance Raman spectra show no significant alterations in spectral regions sensitive to interactions between the heme iron and the proximal histidine residue, confirming that the functional differences in the variant are due to distal-side heme pocket alterations. These effects are discussed in the context of a schematic representation of heme pocket wells and barriers that could aid the design of novel hemoglobins with altered ligand affinity without loss of the normal allosteric responses that facilitate unloading of oxygen to respiring tissues.     

Specific antibodies to hemoglobin A1 (anti-Glu) and hemoglobin S (anti-Val) in the guinea pig: immunologic and structural correlations.

Like goats and sheep, guinea pigs can produce, in response to human sickle cell hemoglobin (beta6 Glu leads to Val), an antibody population (anti-Val) that will bind sickle cell hemoglobin but not normal hemoglobin HbA. Unlike goats and sheep, guinea pigs can produce in response to human hemoglobin A1 an antibody fraction, anti-Glu, that will not react with human sickle cell hemoglobin. These anti-Glu antibodies have been isolated by affinity chromatography and their specificity confirmed by fluorescence-quenching titrations. The sequence of the first 10 amino acids of the beta-chain of guinea pig hemoglobin has been determined. This sequence differs from those of both hemoglobin HbA and sickle cell hemoglobin by two residues, those at positions 5 and 6. This explains the similarity of the immunogenicity of this site on the two human hemoglobins when administered to guinea pigs. Both goats and sheep are identical to hemoglobin A1 at the beta-6 position.     

1H-NMR investigation of the oxygenation of hemoglobin in intact human red blood cells.

Using improved selective excitation methods for protein nuclear magnetic resonance (NMR), we have conducted measurements of the oxygenation of hemoglobin inside intact human red blood cells. The selective excitation methods use pulse shape-insensitive suppression of the water signal, while producing uniform phase excitation in the region of interest and, thus, are suitable for a wide variety of applications in vivo. We have measured the areas of 1H-NMR resonances of the hyperfine-shifted, exchangeable N delta H protons of the proximal histidine residues of the alpha- and beta-chains in deoxyhemoglobin (63 and 76 ppm downfield from the proton resonance of 2,2-dimethyl-2-silapentane-5-sulfonate (DSS), respectively), which are sensitive to the paramagnetic state of the iron, and for which the alpha- and beta-chain resonances are resolved, and from the ring current-shifted gamma 2-CH3 protons of the distal valine residues in oxyhemoglobin (2.4 ppm upfield from DSS), which are sensitive to the conformation of the heme pocket in the oxy state. We have found that the proximal histidine resonances are directly correlated with the degree of oxygenation of hemoglobin, whereas the distal valine resonances appear to be correlated with the conformation in the heme pocket that occurs after the binding of oxygen, in both the presence and absence of 2,3-diphosphoglycerate. In addition, from the proximal histidine resonances, we have observed a preference for the binding of oxygen to the alpha-chain (up to about 10%) of hemoglobin over the beta-chain in both the presence and absence of 2,3-diphosphoglycerate. These new results obtained in intact erythrocytes are consistent with our previous 1H-NMR studies on purified human normal adult hemoglobin. A unique feature of our 1H-NMR method is the ability to monitor the binding of oxygen specifically to the alpha- and beta-chains of hemoglobin both in solution and in intact red blood cells. This information is essential to our understanding of the molecular basis for the hemoglobin molecule serving as the oxygen carrier in vertebrates.     

High-resolution X-ray study of deoxy recombinant human hemoglobins synthesized from beta-globins having mutated amino termini.

The crystal structures of three mutant hemoglobins reconstituted from recombinant beta chains and authentic human alpha chains have been determined in the deoxy state at 1.8-A resolution. The primary structures of the mutant hemoglobins differ at the beta-chain amino terminus. One mutant, beta Met, is characterized by the addition of a methionine at the amino terminus. The other two hemoglobins are characterized by substitution of Val 1 beta with either a methionine, beta V1M, or an alanine, beta V1A. All the mutation-induced structural perturbations are small intrasubunit changes that are localized to the immediate vicinity of the beta-chain amino terminus. In the beta Met and beta V1A mutants, the mobility of the beta-chain amino terminus increases and the electron density of an associated inorganic anion is decreased. In contrast, the beta-chain amino terminus of the beta V1M mutant becomes less mobile, and the inorganic anion binds with increased affinity. These structural differences can be correlated with functional data for the mutant hemoglobins [Doyle, M. L., Lew, G., DeYoung, A., Kwiatkowski, L., Noble, R. W., & Ackers, G. K. (1992) Biochemistry preceding paper is this issue] as well as with the properties of ruminant hemoglobins and a mechanism [Perutz, M., & Imai, K. (1980) J. Mol. Biol. 136, 183-191] that relates the intrasubunit interactions of the beta-chain amino terminus to changes in oxygen affinity. Since the structures of the mutant deoxyhemoglobins show only subtle differences from the structure of deoxyhemoglobin A, it is concluded that any of the three hemoglobins could probably function as a surrogate for hemoglobin A.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hemoglobin Tilburg: alpha 2-beta 2 73 (E 17) Asp----Gly. A new hemoglobin with reduced oxygen affinity

A new hemoglobin variant has been found in a Dutch Caucasian girl and detected also in members of three generations of her family. This variant is characterized by the substitution of an aspartic acid at position 73 (E 17) of the beta-chain with a glycine residue. Hemoglobin Tilburg makes up to 42% of the total hemoglobin in the blood of the proposita, it is stable at the isopropanol test, and not associated with significant hematological abnormalities in heterozygous carriers. The oxygen dissociation curve of the purified variant, carried out at different pH values, shows a definite reduction of the affinity for oxygen and a normal alkaline Bohr effect. Three more hemoglobins with a single amino acid substitution at the same site have been previously described: Hb Korle-Bu (Asp----Asn), Hb Mobile (Asp----Val) and Hb Vancouver (Asp----Tyr). In all these proteins the affinity for oxygen is lowered to an extent which is variable and characteristic of each mutant. In this paper we discuss the possible mechanism responsible for the abnormal behaviour of hemoglobins substituted at beta 73.     

Isolation and characterization of two opioid peptides from a bovine hemoglobin peptic hydrolysate.

Two opioid peptides were isolated from a bovine hemoglobin hydrolysate, by use of gel permeation (GP) and reverse phase (RP) high performance liquid chromatography (HPLC). Their primary structure and accurate molecular weights, determined by amino acid analysis and fast atom bombardment (FAB) mass spectrometry, were identical to fragments 31-40 (LVV-hemorphin-7) and 32-40 (VV-hemorphin 7) of the beta-chain of bovine hemoglobin. The same fragments occur in human hemoglobin in positions 32-41 and 33-41 of the beta-chain, respectively. The opioid potency of these peptides, exhibited by use of electrically stimulated muscle of isolated guinea-pig ileum (GPI), were significant and comparable with some others previously described. In addition, the location of the two opioid peptides, VV-hemorphin-7 and LVV-hemorphin-7, revealed the existence of a "strategic zone" both in the bovine and human beta-chains of hemoglobin.     

Additive effects of beta chain mutations in low oxygen affinity hemoglobin betaF41Y,K66T.

In order to decrease significantly the oxygen affinity of human hemoglobin, we have associated the mutation betaF41Y with another point mutation also known to decrease the oxygen affinity of Hb. We have synthesized a recombinant Hb (rHb) with two mutations in the beta chains: rHb betaF41Y,K66T. In the absence of 2, 3-diphosphoglycerate, additive effects of the mutations are evident, since the doubly mutated Hb exhibits a larger decrease in oxygen affinity than for the individual single mutations. In the presence of 2,3-diphosphoglycerate, the second mutation did not significantly increase the P(50) value relative to the single mutations. However, the kinetics of CO binding still indicate combined effects on the allosteric equilibrium, as evidenced by more of the slow bimolecular phase characteristic of binding to the deoxy conformation. Dimer-tetramer equilibrium studies indicate an increase in stability of the mutants relative to rHb A; the double mutant rHb betaF41Y, K66T at pH 7.5 showed a K(4,2) value of 0.26 microM. Despite the lower oxygen affinity, the single mutant betaF41Y and double mutant betaF41Y,K66T show only a moderate increase of 20% in the autoxidation rate. These mutations are thus of interest in developing a Hb-based blood substitute.     

A unique loop extension in the serine protease domain of haptoglobin is essential for CD163 recognition of the haptoglobin-hemoglobin complex

Haptoglobin and haptoglobin-related protein are homologous hemoglobin-binding proteins consisting of a complement control repeat (alpha-chain) and a serine protease domain (beta-chain). Haptoglobin-hemoglobin complex formation promotes high affinity binding of hemoglobin to the macrophage scavenger receptor CD163 leading to endocytosis and degradation of the haptoglobin-hemoglobin complex. In contrast, complex formation between haptoglobin-related protein and hemoglobin does not promote high affinity interaction with CD163. To define structural components of haptoglobin important for CD163 recognition, we exploited this functional difference to design and analyze recombinant haptoglobin/haptoglobin-related protein chimeras complexed to hemoglobin. These data revealed that only the beta-chain of haptoglobin is involved in receptor recognition. Substitution of 4 closely spaced amino acid residues of the haptoglobin beta-chain (valine 259, glutamate 261, lysine 262, and threonine 264) abrogated the high affinity receptor binding. The 4 residues are encompassed by a part of the primary structure not present in other serine protease domain proteins. Structural modeling based on the well characterized serine protease domain fold suggests that this sequence represents a loop extension unique for haptoglobin and haptoglobin-related protein. A synthetic peptide representing the haptoglobin loop sequence exhibited a pronounced inhibitory effect on receptor binding of haptoglobin-hemoglobin.     

A biophysical investigation of recombinant hemoglobins with aromatic B10 mutations in the distal heme pockets

This study examines the structural and functional effects of amino acid substitutions in the distal side of both the alpha- and beta-chain heme pockets of human normal adult hemoglobin (Hb A). Using our Escherichia coli expression system, we have constructed four recombinant hemoglobins: rHb(alphaL29F), rHb(alphaL29W), rHb(betaL28F), and rHb(betaL28W). The alpha29 and beta28 residues are located in the B10 helix of the alpha- and beta-chains of Hb A, respectively. The B10 helix is significant because of its proximity to the ligand-binding site. Previous work showed the ability of the L29F mutation to inhibit oxidation. rHb(alphaL29W), rHb(betaL28F), and rHb(betaL28W) exhibit very low oxygen affinity and reduced cooperativity compared to those of Hb A, while the previously studied rHb(alphaL29F) exhibits high oxygen affinity. Proton nuclear magnetic resonance spectroscopy indicates that these mutations in the B10 helix do not significantly perturb the alpha(1)beta(1) and alpha(1)beta(2) subunit interfaces, while as expected, the tertiary structures near the heme pockets are affected. Experiments in which visible spectrophotometry was utilized reveal that rHb(alphaL29F) has equivalent or slower rates of autoxidation and azide-induced oxidation than does Hb A, while rHb(alphaL29W), rHb(betaL28F), and rHb(betaL28W) have increased rates. Bimolecular rate constants for NO-induced oxidation have been determined using a stopped-flow apparatus. These findings indicate that amino acid residues in the B10 helix of the alpha- and beta-chains can play different roles in regulating the functional properties and stability of the hemoglobin molecule. These results may provide new insights for designing a new generation of hemoglobin-based oxygen carriers.     

Studies on cobalt myoglobins and hemoglobins, XIII. A consequence of the occurrence of glutamine at the E7 (58) site of alpha subunits in opossum hemoglobin

To investigate the mode of interactions between heme metal, bound oxygen and the distal residue at the E7 site, we have measured accurate oxygen equilibrium curves, oxygen binding relaxations following temperature-jump, and electron paramagnetic resonance spectra of natural and cobalt-substituted opossum hemoglobin, which has glutamine and histidine at the E7 site of the α chain and the β chain, respectively, and compared them with those of natural and cobalt-substituted human hemoglobin, which has histidine at the E7 site of both the α and β chains.Natural opossum hemoglobin has a lower oxygen affinity, slightly smaller and pH-dependent co-operativity, a somewhat greater Bohr effect, and a smaller effect of organic phosphates such as 2,3-diphosphoglycerate and inositol hexaphosphate on oxygen affinity as compared to natural human hemoglobin. Upon substitution of cobalt for iron, these oxygenation characteristics of opossum hemoglobin relative to those of human hemoglobin were preserved well. The behavior of the intrinsic oxygen association constants pertaining to the four oxygenation steps (i.e. the Adair constants) upon addition of the organic phosphates or pH changes indicates that the allosteric equilibrium in opossum hemoglobin is biased towards the T state as compared with that in human hemoglobin, and that the oxygen affinity of the R structure is lower for opossum hemoglobin than for human hemoglobin. The temperature-jump kinetic data indicate that the lower oxygen affinity of opossum cobalt-hemoglobin in comparison with that of human cobalt-hemoglobin can be ascribed to a decreased oxygen association rate constant. The electron paramagnetic resonance experiments on oxy and deoxy opossum and human cobalt-hemoglobins in buffered H₂O and ²H₂O, including their photolysed products at a low temperature, provided the following information. The cobaltous ion of the α subunits of deoxy opossum cobalt-hemoglobin is in an environment that is similar to that for cobaltous ions of deoxy human cobalt-hemoglobin in the T state. The hydrogen bond between the bound oxygen and the residue at E7, which has been shown to exist in oxy human cobalt-hemoglobin and oxy sperm whale cobalt-myoglobin, is absent or, at least, significantly altered in the α subunits of oxy opossum cobalt-hemoglobin, probably resulting in a lower oxygen affinity. Interference by isoleucine at E11α with an oxygen molecule is suggested as an explanation for the lowered affinity of opossum iron-hemoglobin. However, no straightforward structural explanation is available for the lower oxygen affinity of the R structure and the allosteric equilibrium biased towards the T state in opossum iron-hemoglobin.     

Effect of Cl- and H+ on the oxygen binding properties of glutaraldehyde-polymerized bovine hemoglobin-based blood substitutes

Bovine hemoglobin was cross-linked with glutaraldehyde, resulting in high oxygen affinity polymeric hemoglobin dispersions of varying molecular weight distributions. High oxygen affinity acellular oxygen carriers were designed in order to exhibit oxygen release profiles closer to that of human red blood cells (RBCs), without exhibiting the inherent increased vasoactivity that occurs with low oxygen affinity acellular oxygen carriers (1, 2). Oxygen dissociation curves were measured for polymerized hemoglobin dispersions at various pH values (7.0, 7.4, and 8.0) and chloride ion concentrations. Unmodified hemoglobin showed an increase in oxygen affinity with increased chloride ion concentration and a decrease in oxygen affinity with increased pH, as was previously demonstrated in the literature (3). For glutaraldehyde-polymerized hemoglobin dispersions, the ability of the oxygen affinity to respond to changes in Bohr H+ and Cl- concentration was weakened. However, at acidic physiological pH (pH = 7), the Bohr effect was still present at high Cl- concentrations. Thus, the Bohr effect maintained some dependency on the Cl- concentration.     

Fixation of aldehydic dextrans onto human deoxyhemoglobin.

A procedure commonly used to transform native adult human hemoglobin (Hb) into a physiological oxygen carrier consists of a pyridoxylation of the protein to lower its oxygen affinity, followed by its polymerization in the presence of glutaraldehyde, with or without further reduction, to increase its circulating half-life. This series of reactions yields derivatives presenting a great molecular heterogeneity that have to be fractionated for use in vivo. Hemoglobin derivatives with low oxygen affinity and a narrow distribution of molecular weights were obtained by linking a dextran polyaldehydic derivative to deoxyhemoglobin at pH 8. From oxygen-binding measurements carried out in the presence of inositolhexaphosphate, a strong effector of hemoglobin, it appeared that the allosteric site of hemoglobin was blocked, probably by crosslinking bonds, which stabilizes its deoxy structure. On the other hand, when the reaction was performed in the presence of inositolhexaphosphate, the resulting conjugates exhibited an oxygen affinity identical to that of unmodified hemoglobin. After treatment with NaBH4, the polymer-hemoglobin derivatives were stable and possessed a reversible oxygen-carrying capacity similar to that of blood. The conjugates prepared from oxyhemoglobin all possessed a lower P50 than native hemoglobin whatever the reaction conditions.     

Acylation of human hemoglobin with polyoxyethylene derivatives

Monomethoxypolyoxyethylene (Mw = 5000) was covalently linked to human hemoglobin via an amide bond formed between amino groups of the protein and a carboxylic group introduced onto the polymer. The conjugates thus obtained have a molecular size corresponding to that of a globular protein with a molecular weight of about 190 000. Their oxygen-binding properties depend upon the initial conformation of the hemoglobin and reaction pH: hemoglobin modified in the deoxy state exhibited a lower oxygen affinity than that modified in the oxy state, and the lower the reaction pH, the lower the oxygen affinity of polymer-linked hemoglobin. However, the affinity of modified hemoglobin is always higher than that of native hemoglobin. On the other hand, when deoxyHb was complexed with organic phosphates during the condensation reaction, the resulting conjugates exhibited oxygen-binding characteristics quite similar to those of native hemoglobin, i.e., the same oxygen affinity, modified cooperativity and the same alkaline Bohr effect. Finally, in order to decrease the oxygen affinity of hemoglobin conjugates, the polymer was coupled to deoxy hemoglobin previously covalently modified with pyridoxal phosphate. The oxygen affinity of such conjugates was in fact as low as that of the initial pyridoxylated hemoglobin.     

Anionic Control of Function in Vertebrate Hemoglobins

Point mutations in the amino acid sequence of normal human hemoglobinhave provided a powerful means of probing structure-functionrelationships in this respiratory protein. Through studies ofspecific hemoglobin variants it has been possible to gain abetter understanding of how electrostatic interactions exercisecontrol over the functional properties of hemoglobin. Humanhemoglobin variants of particular interest in this respect arethose with alterations of amino or carboxyl terminal residuesand alterations at or near the binding site for the physiologicallyimportant cofactor 2,3-diphosphoglycerate. In deoxy hemoglobinit has been established that salt bridges formed by the terminalresidues constrain the tetramer in a low affinity conformation.From the information presently available, it appears that thecharge cluster of the 2,3 diphosphoglycerate binding site isan important part of the innerspring mechanism that tends todestabilize the deoxy conformation. When anions bind to theseresidues the repulsive interactions between the positively chargedresidues of this region are decreased. This provides a directmeans by which anionic interactions with hemoglobin can shiftthe conformational equilibrium toward the low affinity state.Accordingly anion and pH effects are decreased in a number ofhemoglobin variants whose substitutions reduce the positivecharge density in the region of the binding site for polyphosphates.The presence of the charge cluster provides for a fine tuningof hemoglobin s functional properties that is responsive tothe concentration of metabolic effectors in vivo. The degreeto which this is possible varies in the vertebrate hemoglobinswhich have been examined. In human hemoglobin eight positivelycharged residues contribute to the charge cluster and anionicmodulation of oxygen affinity is effective. Susceptibility toanionic modulation is decreased in hemoglobins where the chargecluster is less developed and is completely absent in some vertebratehemoglobins. Anionic modulation, which occurs via an effecton the equilibrium between conformational states of high andlow oxygen affinity is possible even in systems which do notshow cooperative interactions in oxygen binding. This is wellestablished by studies on isolated chains of human hemoglobinand by studies on enzymatically modified tetramers of Amphiumahemoglobin.     

Consequences of chemical modifications on the free radical reactions of human hemoglobin.

Hemoglobin-based oxygen carriers (HBOCs) are candidates for use as blood substitutes and resuscitation fluids. We determined that HBOCs of specific types differ in their ability to generate or interact with free radicals. The differences do not correlate with oxygen affinity. Detailed comparisons with unmodified human hemoglobin, HbA0, were carried out with two cross-linked derivatives: HbA-FMDA, produced by the reaction of human oxyhemoglobin with fumaryl monodibromoaspirin, and HbA-DBBF, produced by the reaction of human deoxyhemoglobin with bis(3,5-dibromosalicyl) fumarate. Both derivatives had lower oxygen affinity than unmodified HbA0. As previously reported, exposure of oxyhemoglobin to H2O2 causes generation of free radicals capable of generating formaldehyde from dimethyl sulfoxide. Relative to the reaction catalyzed by 50 microM HbA (18.0 +/- 3.5 nmol/30 min/ml), the formaldehyde formation was roughly 70% for HbA-DBBF and 50% for HbA-FMDA under comparable conditions. More profound differences are exhibited at lower hemoglobin concentrations. Spectral changes of the HBOCs during the reaction differ qualitatively and occur at different rates. The HBOCs also differ in rates of hemoglobin-catalyzed NADPH oxidation and aniline hydroxylation, reactions mediated by reactive oxygen species. These results show that stereochemical differences brought about by chemical cross-linking alter the ability of HBOCs to generate radicals and to react with activated oxygen species. These studies also show that the ability of hemoglobin to produce activated species of oxygen can be enhanced or suppressed independently of oxygen affinity.