The removal of organic phosphates from hemoglobin

Allosteric Effectors Influence the Tetramer Stability of Both R- and T-states of Hemoglobin A

The contribution of heterotropic effectors to hemoglobin allostery is still not completely understood. With the recently proposed global allostery model, this question acquires crucial significance, because it relates tertiary conformational changes to effector binding in both the R- and T-states. In this context, an important question is how far the induced conformational changes propagate from the binding site(s) of the allosteric effectors. We present a study in which we monitored the interdimeric interface when the effectors such as Cl-, 2,3-diphosphoglycerate, inositol hexaphosphate, and bezafibrate were bound. We studied oxy-Hb and a hybrid form (alphaFeO2)2-(betaZn)2 as the T-state analogue by monitoring heme absorption and Trp intrinsic fluorescence under hydrostatic pressure. We observed a pressure-dependent change in the intrinsic fluorescence, which we attribute to a pressure-induced tetramer to dimer transition with characteristic pressures in the 70-200-megapascal range. The transition is sensitive to the binding of allosteric effectors. We fitted the data with a simple model for the tetramer-dimer transition and determined the dissociation constants at atmospheric pressure. In the R-state, we observed a stabilizing effect by the allosteric effectors, although in the T-analogue a stronger destabilizing effect was seen. The order of efficiency was the same in both states, but with the opposite trend as inositol hexaphosphate > 2,3-diphosphoglycerate > Cl-. We detected intrinsic fluorescence from bound bezafibrate that introduced uncertainty in the comparison with other effectors. The results support the global allostery model by showing that conformational changes propagate from the effector binding site to the interdimeric interfaces in both quaternary states.

Allosteric effects of chloride ions at the intradimeric alpha1beta1 and alpha2beta2 interfaces of human hemoglobin

The structural transition induced by ligand binding in human hemoglobin encompasses quaternary structure changes at the interfaces between the two alphabeta dimers. In contrast, the interfaces between alpha and beta subunits within the same dimer (i.e., alpha1beta1 and alpha2beta2 interfaces) are structurally invariant. Previous work from this laboratory using NMR spectroscopy has identified four sites at the intradimeric alpha1beta1 and alpha2beta2 interfaces that, although structurally invariant, experience significant changes in the rates of proton exchange upon ligand binding. These sites are Hisalpha103(G10) and Hisalpha122(H5) in each alpha subunit of the hemoglobin tetramer. In the present work, we show that the proton exchange at the Hisalpha103(G10) sites is affected by the interactions of hemoglobin with chloride ions. Increasing concentrations of chloride ions at pH 6.45 and at 37 degrees C enhance the exchange rate of the Hisalpha103(G10) N(epsilon 2) proton. The enhancement is greater in deoxygenated than in ligated hemoglobin. In the framework of the local unfolding model for proton exchange, these results suggest that the structural free energy and/or the proton transfer reactions at the Hisalpha103(G10) sites depend on the concentration of chloride ions. Therefore, the ligand-induced changes at the Hisalpha103(G10) sites are modulated by the allosteric effect of chloride ions on hemoglobin.

Global allostery model of hemoglobin. Modulation of O(2) affinity, cooperativity, and Bohr effect by heterotropic allosteric effectors

The O(2) equilibria of human adult hemoglobin have been measured in a wide range of solution conditions in the presence and absence of various allosteric effectors in order to determine how far hemoglobin can modulate its O(2) affinity. The O(2) affinity, cooperative behavior, and the Bohr effect of hemoglobin are modulated principally by tertiary structural changes, which are induced by its interactions with heterotropic allosteric effectors. In their absence, hemoglobin is a high affinity, moderately cooperative O(2) carrier of limited functional flexibility, the behaviors of which are regulated by the homotropic, O(2)-linked T/R quaternary structural transition of the Monod-Wyman-Changeux/Perutz model. However, the interactions with allosteric effectors provide such "inert" hemoglobin unprecedented magnitudes of functional diversities not only of physiological relevance but also of extreme nature, by which hemoglobin can behave energetically beyond what can be explained by the Monod-Wyman-Changeux/Perutz model. Thus, the heterotropic effector-linked tertiary structural changes rather than the homotropic ligation-linked T/R quaternary structural transition are energetically more significant and primarily responsible for modulation of functions of hemoglobin.

Inhibition of Human Hemoglobin Autoxidaiton by Sodium n-Dodecyl Sulphate

The effect of sodium n-dodecyl sulphate (SDS) on hemoglobin autoxidation was studied in the presence of a 100 mM phosphate buffer (pH 7.0) by different methods. These included spectrophotometry, fluorescence technique, cyclic voltametry, differential scanning calorimetry, and densitometry. Spectroscopic studies showed that SDS concentrations up to 1 mM increased deoxy-, decreases oxy-, and had no significant effect on the met- conformation of hemoglobin. Therefore, a SDS concentration up to 1 mM increased the deoxy form of hemoglobin as the folded, compact state and decreases the oxy conformation. The turbidity measurements and differential scanning calorimetry techniques indicated a more stable conformation for hemoglobin in the presence of SDS up to 1 mM. Electrochemical studies also confirmed a more difficult oxidation under these conditions. The induction of the deoxy form in the presence of SDS was confirmed by densitometry techniques. The compact structure of deoxyhemoglobin blocks the formation of met-conformation in low SDS concentrations.

Electron paramagnetic resonance and oxygen binding studies of alpha-Nitrosyl hemoglobin. A novel oxygen carrier having no-assisted allosteric functions

alpha-Nitrosyl hemoglobin, alpha(Fe-NO)2beta(Fe)2, which is frequently observed upon reaction of deoxy hemoglobin with limited quantities of NO in vitro as well as in vivo, has been synthetically prepared, and its reaction with O2 has been investigation by EPR and thermodynamic equilibrium measurements. alpha-Nitrosyl hemoglobin is relatively stable under aerobic conditions and undergoes reversible O2 binding at the heme sites of its beta-subunits. Its O2 binding is coupled to the structural/functional transition between T- (low affinity extreme) and R- (high affinity) states. This transition is linked to the reversible cleavage of the heme Fe-proximal His bonds in the alpha(Fe-NO) subunits and is sensitive to allosteric effectors, such as protons, 2,3-biphosphoglycerate, and inositol hexaphosphate. In fact, alpha(Fe-NO)2beta(Fe)2 is exceptionally sensitive to protons, as it exhibits a highly enhanced Bohr effect. The total Bohr effect of alpha-nitrosyl hemoglobin is comparable to that of normal hemoglobin, despite the fact that the oxygenation process involves only two ligation steps. All of these structural and functional evidences have been further confirmed by examining the reactivity of the sulfhydryl group of the Cysbeta93 toward 4, 4'-dipyridyl disulfide of several alpha-nitrosyl hemoglobin derivatives over a wide pH range, as a probe for quaternary structure. Despite the halved O2-carrying capacity, alpha-nitrosyl hemoglobin is fully functional (cooperative and allosterically sensitive) and could represent a versatile low affinity O2 carrier with improved features that could deliver O2 to tissues effectively even after NO is sequestered at the heme sites of the alpha-subunits. It is concluded that the NO bound to the heme sites of the alpha-subunits of hemoglobin acts as a negative allosteric effector of Hb and thus might play a role in O2/CO2 transport in the blood under physiological conditions.

Primary structure and oxygen-binding properties of the hemoglobin from the lesser hedgehog tenrec (Echinops telfairi, Zalambdodonta). Evidence for phylogenetic isolation

The primary structures of the alpha- and beta-hemoglobin chains of the lesser hedgehog tenrec (Echinops telfairi, Zalambdodonta) are presented. Chain separation was performed by carboxymethyl-cellulose chromatography. The peptides, obtained by tryptic digestion of the oxidized chains, were prefractionated by gel chromatography and isolated by reversed-phase HPLC. For sequence analysis gas and liquid phase sequencers were employed. The tenrec hemoglobin consists of one alpha- and two beta-chains the latter occurring in a 1:1 ratio and differing in beta 16 Gly/Cys and beta 118 Phe/Leu. Two external cysteine residues at beta 16 and beta 52 cause reversible polymerization to octamers and most likely irreversible formation of higher polymers. A comparison of the whole chains and certain positions of tenrec hemoglobin with those of Insectivora sensu strictu, Scandentia and Proto- and Metatheria corroborates a long and independent evolution of tenrec and its phylogenetic isolation from the Insectivora s.str. (hedgehog, musk shrew and mole). Replacements at positions involved in heme and subunit interface contacts are discussed. Compared to human hemoglobin the tenrec pigment shows a low intrinsic oxygen affinity as well as lower chloride and temperature sensitivities, a reduced Bohr effect and a strong response to 2,3-DPG. The possible adaptive significance of these properties is discussed in relation to the large diurnal body temperature variations seen in tenrecs.

Use of dual wavelength spectrophotometry and continuous enzymatic depletion of oxygen for determination of the oxygen binding constants of hemoglobin

A small stopped-flow cuvette was built into a computer-controlled Cary 210 spectrophotometer. The enzymatic depletion of oxygen in solutions of hemoglobin and myoglobin was initiated by flowing the hemeproteins with the enzyme against a solution of the hemeproteins containing the appropriate substrate. The deoxygenation was homogeneous throughout the solution. Oxygen activity was calculated at each instant of time from the fractional saturation of Mb, determined from observations at the Hb/HbO2 isosbestic wavelength. Fractional saturation of Hb was determined from absorbances at the Mb/MbO2 isosbestic wavelength. The spectrophotometer cycled between these two wavelengths during the deoxygenation. The deoxygenation of HbO2 was largely complete in 20-25 min, whereas the deoxygenation of MbO2 was allowed to proceed for about 1 h. This procedure eliminates equilibration of Hb solutions with a gas phase and replaces oxygen electrode readings with spectrophotometric sensing by Mb, providing essentially instantaneous determinations of oxygen activity and hence 250-500 or more independent data points per run. The Mb and Hb data vectors require several manipulations to correct for small relative displacements in time and for small non-isosbestic effects. Detailed consideration of the enzyme kinetics allowed oxygen activities to be determined in regions where Mb is a poor sensor. Studies of HbO2 deoxygenation as a function of wavelength show that the determination of the four Adair constants requires in addition the determination of three spectroscopic parameters. Values of the apparent Adair constants, determined without these spectroscopic parameters, depend strongly on the monitoring wavelength.

Roles of the beta 146 histidyl residue in the molecular basis of the Bohr effect of hemoglobin: a proton nuclear magnetic resonance study

Assessment of the roles of the carboxyl-terminal beta 146 histidyl residues in the alkaline Bohr effect in human normal adult hemoglobin by high-resolution proton nuclear magnetic resonance spectroscopy requires assignment of the resonances corresponding to these residues. Previous resonance assignments in low ionic strength buffers for the beta 146 histidyl residue in the carbonmonoxy form of hemoglobin have been controversial [see Ho and Russu (1987) Biochemistry 26, 6299-6305; and references therein]. By a careful spectroscopic study of human normal adult hemoglobin, enzymatically prepared des(His146 beta)-hemoglobin, and the mutant hemoglobins Cowtown (beta 146His----Leu) and York (beta 146His----Pro), we have resolved some of these conflicting results. By a close incremental variation of pH over a wide range in chloride-free 0.1 M N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonic acid buffer, a single resonance has been found to be consistently missing in the proton nuclear magnetic resonance spectra of these hemoglobin variants. The spectra of each of these variants show additional perturbations; therefore, the assignment has been confirmed by an incremental titration of buffer conditions to benchmark conditions, i.e., 0.2 M phosphate, where the assignment of this resonance is unambiguous. The strategy of incremental titration of buffer conditions also allows extension of this resonance assignment to spectra taken in 0.1 M [bis(2-hydroxyethyl)amino]tris(hydroxymethyl)methane buffer. Participation of the beta 146 histidyl residues in the Bohr effect has been calculated from the pK values determined for the assigned resonances in chloride-free 0.1 M N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonic acid buffer. Our results indicate that the contribution of the beta 146 histidyl residues is 0.52 H+/hemoglobin tetramer at pH 7.6, markedly less than the 0.8 H+/hemoglobin tetramer estimated by study of the mutant hemoglobin Cowtown (beta 146His----Leu) by Shih and Perutz [(1987) J. Mol. Biol. 195, 419-422]. We have found that at least two histidyl residues in the carbonmonoxy form of this mutant have pK values that are perturbed, and we suggest that these pK differences may in part account for this discrepancy. Furthermore, summation of the positive contribution of the beta 146 histidyl residues and the negative contribution of the beta 2 histidyl residues to the maximum Bohr effect measured in 0.1 M N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonic acid buffer suggests that additional sites in the hemoglobin molecule account for proton release upon ligation greater than the contribution of the beta 146 histidyl residues.(ABSTRACT TRUNCATED AT 400 WORDS)

LR16, a compound with potent effects on the oxygen affinity of hemoglobin, on blood cholesterol, and on low density lipoprotein

2-[4-(3,4-Dichlorophenylureido)phenoxy]-2-methylpropionic acid, LR16, combines with two symmetrically related sites in the central cavity of deoxyhemoglobin, 20 A away from the binding site of 2,3-bisphosphoglycerate, and acts as an allosteric effector synergistic with 2,3-bisphosphoglycerate. LR16 (1 mM) raises P50, the partial pressure of oxygen needed to achieve half-saturation with oxygen of a hemolysate of human hemoglobin, about 50 times more strongly than 1 mM 2,3-bisphosphoglycerate. Oral administration of LR16 (at small doses that produced no ill effects) to rats that were fed a diet rich in cholesterol caused substantial reductions of total serum cholesterol and low density lipoprotein-cholesterol, while high density lipoprotein-cholesterol remained unchanged.

Study of the specific heme orientation in reconstituted hemoglobins

NMR studies of the recombination reaction of apohemoglobin derivatives with natural and unnatural hemes and of the heme-exchange reaction for reconstituted hemoglobin have revealed that the heme is incorporated into the apoprotein with stereospecific heme orientations dependent upon the heme peripheral 2,4-substituents and the axial iron ligand(s). Heme orientations also depend on whether recombination occurs at the alpha or beta subunit and on whether or not the complementary subunit is occupied by the heme. In the recombination reaction with the azido complex of deuterohemin, the alpha subunit of the apohemoglobin preferentially combines with the hemin in the "disordered" heme orientation, whereas protohemin is inserted in either of two heme orientations. Mesohemin inserts predominantly in the "native" heme orientation. For the beta subunit, specific heme orientation was also encountered, but the specificity was somewhat different from that of the alpha subunit. It was also shown that the specific heme orientation in both subunits is substantially affected by the axial heme ligands. These findings imply that apohemoglobin senses the steric bulkiness of both the porphyrin 2,4-substituents and the axial iron ligands in the heme-apoprotein recombination reaction. To gain an insight into the effect of the protein structure, the heme reconstitution reaction of semihemoglobin, demonstrating that the heme orientation in the reconstituted semihemoglobin with the azido-deuterohemin complex was in the native form, was also examined.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorine nuclear magnetic resonance spectra of rabbit carbonmonoxyhemoglobin

Carbonmonoxyhemoglobin prepared from protein isolated from rabbits maintained on a diet supplemented with 4-fluorophenylalanine (Phe (4F)) has been studied by fluorine NMR spectroscopy. Substitution of Phe(4F) appears to take place randomly at the sixteen nonequivalent phenylalanine positions of the globins; examination of hybrid hemoglobins in which only one type of globin chain contained the fluorinated amino acid, as well as changes in the spectrum upon exposure to oxygen, aided in the assignment of fluorine resonances from the alpha- or beta-globin chains. The effects of modification of Cys-beta-93 with a spin label and variation of pH and sample temperature on the spectrum were also examined. These data in association with theoretical estimates of aromatic ring current and van der Waals effects on chemical shifts were used to support tentative assignments of several signals observed to specific amino acid residues. Evidence suggesting the presence of two conformational forms of the protein, possibly due to disorder of the heme groups, is described.

Analysis of teleost hemoglobin by Adair and Monod-Wyman-Changeux models. Effects of nucleoside triphosphates and pH on oxygenation of tench hemoglobin

The allosteric effects of the erythrocytic nucleoside triphosphates (NTP) and of proton concentrations were investigated by precise measurement of Hb-O2 equilibria of tench hemoglobin (including extreme, high and low saturation ranges) and analysed in terms of the MWC two state model and the Adair four step oxygenation theory. At low concentrations (NTP/Hb ratio = 1.0, and pH greater than 7.3) ATP, GTP and protons decrease Hb-O2 affinity by increasing the allosteric constant L and reducing KT, the association constant of the deoxy, tense state of the Hb, without significantly affecting that (KR) of the oxy state, increasing the free energy of cooperativity (delta G). High concentrations of these effectors, however, also reduce KR. The greater sensitivity of the half-saturation O2 tension (P50) of the Hb to GTP than to ATP at the same concentration, correlates with greater effects of GTP on both KT and KR. The pH and NTP dependence of the four Adair association constants and the calculated fractional populations of Hb molecules in different stages of oxygenation show that the autochthonous NTP effectors and protons stabilize the T structure and postpone the T----R transition basic to cooperativity in fish Hb. The possible implications of the findings for aquatic respiration are discussed.

NMR study of hybrid hemoglobins containing unnatural heme: effect of heme modification on their tertiary and quaternary structures

The effect of heme modification on the tertiary and quaternary structures of hemoglobins was examined by utilizing the NMR spectra of the reconstituted [mesohemoglobin (mesoHb), deuterohemoglobin (deuteroHb)] and hybrid heme (meso-proto, deutero-proto) hemoglobins (Hbs). The heme peripheral modification resulted in the preferential downfield shift of the proximal histidine N1H signal for the beta subunit, indicating nonequivalence of the structural change induced by the heme modification in the alpha and beta subunits of Hb. In the reconstituted and hybrid heme Hbs, the exchangeable proton resonances due to the intra- and intersubunit hydrogen bonds, which have been used as the oxy and deoxy quaternary structural probes, were shifted by 0.2-0.3 ppm from that of native Hb upon the beta-heme substitution. This suggests that, in the fully deoxygenated form, the quaternary structure of the reconstituted Hbs is in an "imperfect" T state in which the hydrogen bonds located at the subunit interface are slightly distorted by the conformational change of the beta subunit. Moreover, the two heme orientations are found in the alpha subunit of deuteroHb, but not in the beta subunit of deuteroHb, and in both the alpha and beta subunits of mesoHb. The tertiary and quaternary structural changes in the Hb molecule induced by the heme peripheral modification were also discussed in relation to their functional properties.

Functional properties of hemoglobins from deep-sea fish: correlations with depth distribution and presence of a swimbladder

The ligand binding properties of the hemoglobins of several deep-sea, bottom-living fish have been examined. These include five species of rattails (Macrouridae) and Antimora rostrata, all of which possess swimbladders, and two unrelated species without swimbladders, Bathysaurus mollis and Alepocephalus sp. All of the hemolysates of these fish exhibited the Root effect with a minimum ligand affinity at about pH 6 in the presence of organic phosphate. Under these conditions the hemolysates from fish which possess swimbladders exhibit two roughly equal populations of heme groups with markedly different ligand affinities. For the deeper-dwelling species the affinities for carbon monoxide differ by some 500-fold, the low-affinity population having a p50(CO) of 100 mmHg at 15 degrees C. This very low affinity is associated with a second-order rate constant for CO combination of the order of 10(3) M-1 X s-1. Those species without swimbladders have hemoglobins which do not have such heterogeneous binding sites, suggesting a relationship between these very-low-affinity heme groups and the pumping of oxygen into a swimbladder at high hydrostatic pressures.

Assessment of role of beta 146-histidyl and other histidyl residues in the Bohr effect of human normal adult hemoglobin

The contribution of the carboxyl-terminal histidines of the beta chains, beta 146(HC3), to the alkaline Bohr effect of human normal adult hemoglobin has been shown by this laboratory to depend upon the solvent composition. Using high-resolution proton nuclear magnetic resonance spectroscopy, we have found that the pKa value of the beta 146-histidine is 8.0 in the deoxy form, while in the carbonmonoxy form it ranges from 7.1 to 7.85 depending upon the concentration of inorganic phosphate and chloride ions present. These conclusions have been questioned by Perutz and co-workers on the basis of biochemical, structural, and proton nuclear magnetic resonance studies of mutant and enzymatically or chemically modified hemoglobins [Perutz, M. F., Kilmartin, J. V., Nishikura, K., Fogg, J. H., Butler, P. J., & Rollema, H. S. (1980) J. Mol. Biol. 138, 649-670; Kilmartin, J. V., Fogg, J. H., & Perutz, M. F. (1980) Biochemistry 19, 3189-3193; Perutz, M. F., Gronenborn, A. M., Clore, G. M., Fogg, J. H., & Shih, D. T.-b. (1985) J. Mol. Biol. 183, 491-498]. In this work, we use proton nuclear magnetic resonance spectroscopy to assess the effects of structural modifications on the histidyl residues and on the overall conformation of the hemoglobin molecule in solution. The structural perturbations investigated all occur within the tertiary domains around the carboxyl-terminal region of the beta chain as follows: Hb Cowtown (beta 146His----Leu); Hb Wood (beta 97His----Leu); Hb Malmö (beta 97His----Gln); Hb Abruzzo (beta 143His----Arg). Our results demonstrate that the conformational effects of single-site structural modifications upon the conformation and dynamics of hemoglobin depend strongly on their location in the three-dimensional structure of the protein molecule and also on their chemical nature. Furthermore, in normal hemoglobin, the spectral properties of several surface histidyl residues are found to depend, in the ligated state, upon the nature of the ligand. Our present findings do not support the recent spectral assignments proposed by Perutz et al. (1985) for the proton resonances of the beta 146- and beta 97-histidines and their suggestion that the enzymatic removal of the carboxyl-terminal beta 146-histidyl residues induces a conformational equilibrium for the beta 97-histidines in the des-beta 146His hemoglobin molecule in the carbonmonoxy form.

Hemoglobin Sendagi (beta 42 Phe----Val): a new unstable hemoglobin variant having an amino acid substitution at CD1 of the beta-chain

Hb Sendagi, a new unstable hemoglobin variant, was found in a Japanese male and his daughter, who have a moderate hemolytic anemia. The variant showed decreased stability upon heat and isopropanol precipitation tests. The variant did not separate from hemoglobin A by electrophoresis, but the abnormal beta-chain emerged ahead of the normal beta-chain on reverse-phase HPLC. Structural analyses revealed that the phenylalanine beta 42 (CD1), one of the critical amino acid residues in the heme pocket, had been replaced by valine. Oxygen equilibrium studies of the patient's hemolysates indicated that Hb Sendagi had a lowered oxygen affinity and a normal response to 2,3-diphosphoglycerate. Hb Hammersmith (beta 42 Phe----Ser) and Hb Louisville (Bucuresti) (beta 42 Phe----Leu) have previously been reported to have varying degrees of molecular instability and altered oxygen binding function. Hb Sendagi provides an additional model for elucidation of the role of the phenylalanine beta CD1 on the structure and function of hemoglobin.

Regulation of the formation of stable adducts between acetaldehyde and blood proteins

Recent reports have described increased levels of a fast-moving hemoglobin (Hb) fraction in alcoholic patients and formation in vitro of stable adducts between acetaldehyde and Hb as well as between acetaldehyde and albumin. In the present study, we have found that factors other than acetaldehyde concentration can influence the rate of stable adduct formation. HbAo was purified and its 2,3-diPglycerate removed by dialysis. Under anaerobic condition and at 37 degrees, acetaldehyde (5 microM) reacted with deoxyHbAo to form 0.26 +/- 0.02 (+/- SEM) nmol of stable adduct/149 nmol Hb in 2 hr. By comparison, acetaldehyde reacted more slowly with oxyHbAo and carbonylHbAo; the rates were 0.21 +/- 0.01 (p less than 0.001) and 0.18 +/- nmol/149 nmol Hb/2 hr (p less than 0.001), respectively. Pyridoxal 5'-phosphate (50-500 microM), under anaerobic condition, inhibited by 36-56 percent the irreversible binding of acetaldehyde to deoxyHbAo. Ascorbic acid (2.5-10 mM) increased by 31-46 percent (p less than 0.001) the irreversible binding of acetaldehyde to human serum albumin and by 8-10 percent (p less than 0.05) the irreversible reaction of acetaldehyde with serum proteins. We conclude that the nonenzymatic binding of acetaldehyde to Hb, human serum albumin and serum proteins is influenced by factors other than acetaldehyde concentration. These factors include oxygen tension, pyridoxal 5'-phosphate and ascorbic acid. Among these factors, oxygen tension may be the most important in vivo.

Temperature dependent spectral changes of iron and nickel hemoglobins and their derivatives

Temperature dependent absolute and difference spectra for deoxy and oxy human hemoglobin, alpha and beta subunits, NiHbA, carboxypeptidase A treated deoxy HbA and NiHbA have been investigated. It is shown for the first time that the alpha subunits are mainly responsible for the temperature dependent spectral changes in the absorption spectra of Hb in the range from 0 degrees C to 40 degrees C. It has also been found that in the R state the spectral alterations caused by temperature variation are about 85% of those found for the T state of Hb. The value of following the temperature dependence of the porphyrin bands of hemoproteins, as a sensitive probe for subtle changes in the region of the heme, is demonstrated.

The oxygen affinity of mammalian hemoglobins in the absence of 2,3-diphosphoglycerate in relation to body weight

We studied the oxygenation of mammalian hemoglobins: mouse (Mus musculus molossinus), rabbit (Oryctolagus cuniculus domesticus), Japanese monkey (Macaca fuscata), man (Homo sapiens), sheep (Ovis aries), llama (Lama glama), pig (Sus scrofa domesticus), cow (Bos taurus domesticus) and horse (Equus caballus), in the absence of 2,3-diphosphoglycerate (DPG) and compared their oxygen affinity in relation to the body weight. The negative correlation between body weight and the oxygen affinity of the whole blood, observed by Schmidt-Nielsen and Larimer (1958), was not observed in the absence of DPG. Our results indicated that an adaptive evolution proposed for hemoglobin in terms of its oxygen affinity vs body weight of the animal can only be appreciated with DPG.

Binding of a spin-labeled phenylalanine analog to sickle hemoglobin: EPR and NMR studies

We have synthesized a spin-label analog of phenylalanine as a competitive inhibitor probe of the sickle hemoglobin aggregation process. Sickle hemoglobin gelation measurements indicate that the spin-label phenylalanine analog is a potent inhibitor of deoxy sickle hemoglobin aggregation. We have also used spin label EPR and high-resolution proton NMR to study the interaction of the phenylalanine analog with hemoglobin, and find that the kinetic off-rate is comparable to, or slower than the hemoglobin rotational rate (i.e., greater than or equal to 10(8) s-1), and that at least one, and perhaps two significant localized interaction region(s) exist within a few angstroms of the beta chain N- and C-termini. Correlation with other known structural information suggests that the observed interaction sites may be relevant to the mechanism for inhibition of sickle hemoglobin aggregation.

High pressure NMR studies of hemoproteins. The effect of pressure on the quaternary structure of hemoglobin

Proton NMR spectra for nitrosyl-, aquomet - and deoxy des-Arg (alpha 141)-hemoglobin in H2O were studied at high pressures up to 1400 atm with attention to the exchangeable proton resonances due to the intra- and intersubunit hydrogen bonds. For aquomethemoglobin , the T state marker signal at 6.4 ppm is insensitive to pressure while the R state marker signal at 6.0 ppm exhibits progressive upfield shift upon pressurization . For nitrosylhemoglobin, the T state signals at 9.6 and 6.5 ppm decrease their intensities upon pressurization while the R state marker signal at 6. 0 ppm remains unchanged. Pressure-induced spectral changes for some of exchangeable resonances are also encountered for deoxy des-Arg (alpha 141)-hemoglobin while the R and T quaternary structural indicators at 6.0 and 9.4 ppm are insensitive to pressure. These pressure-induced spectral changes for these hemoglobin derivatives are significantly distinguished from those associated with the R-T transition induced by addition of IHP or by variation of pH. It is therefore concluded that pressure induces subtle quaternary structural changes in these hemoglobin derivatives without causing the R-T transition.

Proton nuclear magnetic resonance investigation of cross-linked asymmetrically modified hemoglobins: influence of the salt bridges on tertiary and quaternary structures of hemoglobin

Asymmetrically modified hemoglobins, [alpha(des-Arg)beta]A[alpha beta]cXL, [alpha(des-Arg-Tyr)beta]A[alpha beta]cXL, [alpha(des-Arg)beta(NES)]A[alpha beta]cXL, and [alpha(des-Arg)beta]A[alpha beta(NES)]cXL, have been prepared from chemically modified human normal adult hemoglobin (Hb A) and mutant hemoglobin C (beta 6Glu----Lys), where the subscript A or C denotes that the alpha beta dimer is from either Hb A or Hb C, respectively, and XL symbolizes a cross-linked hemoglobin prepared by reaction with a bifunctional cross-linking reagent, bis(3,5-dibromosalicyl) fumarate. It has been shown by X-ray crystallography that this bifunctional reagent cross-links the epsilon-amino group of the lysyl residue at position 82 of the two beta chains [Walder, J. A., Walder, R. Y., & Arnone, A. (1980) J. Mol. Biol. 141, 195]. Proton nuclear magnetic resonance spectra of these asymmetrically modified hemoglobins together with their parent hemoglobins, des-Arg(alpha 141) Hb A, des-Arg(alpha 141)-Tyr(alpha 140) Hb A, NES-Hb A and NES-des-Arg(alpha 141) Hb A, have been obtained over the spectral region 5-10 ppm downfield from H2O for the exchangeable proton resonances and 50-80 ppm downfield from H2O for the hyperfine-shifted proximal histidyl N delta H exchangeable proton resonances. The experimental results indicate that the effects on the hyperfine-shifted proximal histidyl N delta H exchangeable proton resonances at pH 6.0 of removing Arg(alpha 141) or Arg(alpha 141)-Tyr(alpha 140) from one of the two alpha subunits are limited to within the alpha subunit from which the carboxyl-terminal amino acids are specifically removed.(ABSTRACT TRUNCATED AT 250 WORDS)

A proton nuclear magnetic resonance investigation of human hemoglobin A2. Implications on the intermolecular contacts in sickle hemoglobin fibers and on the Bohr effect of human normal adult hemoglobin

High-resolution proton nuclear magnetic resonance spectroscopy at 300 and 600 MHz has been used to investigate the conformation of a minor hemoglobin component of human blood, hemoglobin A2 (alpha 2 delta 2), in solution. We have found that (i) the replacement of the beta chains by the delta chains in hemoglobin A2 conserves the alpha 1 delta 2 interface but slightly perturbs the alpha 1 delta 1 interface, and (ii) one surface histidine residue in the deoxy form and one in the carbonmonoxy form of hemoglobin A2 have local conformations and/or electrostatic environments which are different from the corresponding ones in human normal adult hemoglobin. By comparing the proton nuclear magnetic resonance titration of individual histidine residues in hemoglobin A2 and in human normal adult hemoglobin, we can conclude that in human normal adult hemoglobin, both beta 116 and beta 117 histidine residues are titratable in both the deoxy and the carbonmonoxy forms. Thus, these two histidine residues can contribute to the Bohr effect of human normal adult hemoglobin. The present nuclear magnetic resonance data on hemoglobin A2 and those previously obtained in our laboratory on sickle hemoglobin suggest that the antisickling property of hemoglobin A2 does not originate from an alteration of the intermolecular contact site at the beta 6 position, but involves additional amino-acid residues which are different in the beta and delta chains. We have found that the replacement of the beta 116 and beta 117 histidine residues in the delta chains does not play a significant role in the antisickling effect of hemoglobin A2 and, thus, these amino-acid residues do not participate in the intermolecular interactions responsible for the polymerization of sickle hemoglobin.

Molecular aspects of embryonic mouse haemoglobin ontogeny

Embryos from C57BL/6J mice between the gestational ages of 9 and 16 days possess three embryonic haemoglobins EI, EII and EIII, the proportions of which change as a function of gestational age. Component EI, originally present at approx. 65% at day 9, decreases to approx. 20% by day 16, while component EII increases in an inverse manner to that of component EI. During this period component EIII remains essentially constant at approx. 25%. Separation of these species by ion-exchange chromatography has allowed the characterization of the Hill coefficient, Bohr effect, heat of oxygenation and binding of allosterically active organic phosphates for each component. The three components show marked functional heterogeneity and also differ from maternal haemoglobin. Oxygenation curves for whole embryonic blood show distinct deviations from simple binding behaviour. The presence of a high-affinity component within the blood samples may be accounted for by the presence of haemoglobin EI. By using parameters obtained from the study of the isolated components it has been possible to synthesize mathematically the O2-binding curves, obtained experimentally, throughout the gestational period. The characteristics of the isolated haemoglobin components of embryonic mouse blood are discussed in terms of the changing demands for O2 likely to be encountered by the developing embryo.

A pteroylpolyglutamate binds to tetramers in deoxyhemoglobin but to dimers in oxyhemoglobin

The binding of a physiological concentration of pteroylhepta(glutamate) to oxy- and deoxyhemoglobin in large excess was measured by ultrafiltration. The variation of free to bound folate with hemoglobin concentration showed that a single molecule of the pteroylpolyglutamate is bound by deoxyhemoglobin tetramers and by alpha beta dimers in oxyhemoglobin. Although the binding sites are different, the affinity constants are the same and very similar to the 2,3-bisphosphoglycerate binding energy. Nevertheless, in view of the small proportion of dimers in oxyhemoglobin much more pteroylhepta(glutamate) is bound by deoxyhemoglobin over a wide range of hemoglobin concentrations. Because even 2% deoxyhemoglobin is enough to bind all of the erythrocyte folate as polyglutamate, the bulk of it will be bound at physiological oxygen pressures. Free folate could only be expected in fully oxygenated erythrocytes. Therefore, the reaction of pteroylpolyglutamates with hemoglobin represents an oxygenation-dependent storage mechanism that can account for the 40-fold excess of the vitamin in the erythrocyte over the amounts in the serum. Because methotrexate is also converted to polyglutamate derivatives in the erythrocyte, this drug is likely to be concentrated and stored there by the same mechanism.

A proton nuclear magnetic resonance investigation of histidyl residues in sickle hemoglobin

Using high-resolution proton nuclear magnetic resonance spectroscopy at 250 MHz, we have determined the individual pK values of 22 surface histidyl residues (11 per alpha beta dimer) of sickle hemoglobin in both deoxy and carbon monoxy forms. Seven histidyl residues in the deoxy form and three in the carbon monoxy form are found to have pK values and chemical shifts different from the corresponding ones in human normal adult hemoglobin. Two of these histidyl residues are the beta 2 histidine and the beta 146 histidine, indicating that the conformations of the amino- and carboxyl-terminal regions of the beta chain in sickle hemoglobin are altered compared to those in human normal adult hemoglobin. The differences in the pK values of the additional surface histidyl residues between sickle and normal hemoglobins suggest that the effect of the amino acid substitution at the sixth position of the beta chain in sickle hemoglobin, namely, glutamic acid replaced by valine, is not restricted to the region around the mutation site but can extend to other regions in the protein molecule. In the deoxy form, the histidyl residues of sickle hemoglobin that have altered pK values and chemical shifts compared to the corresponding ones in human normal adult hemoglobin have been found to be sensitive to the early stages of the polymerization process [Russu, I.M., & Ho, C. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 6577-6581].

A proton nuclear magnetic resonance investigation of histidyl residues in human normal adult hemoglobin

High-resolution proton nuclear magnetic resonance (NMR) spectroscopy at 250 MHz has been used to titrate 22 individual surface histidyl residues (11 per alpha beta dimer) of human normal adult hemoglobin in both the deoxy and the carbon monoxy forms. The proton resonances of beta 2, beta 143, and beta 146 histidyl residues are assigned by a parallel 1H NMR titration of appropriate mutant and chemically modified hemoglobins. The pK values of the 22 histidyl residues investigated are found to range from 6.35 to 8.07 in the deoxy form and from 6.20 to 7.87 in the carbon monoxy form, in the presence of 0.1 M Bis-Tris or 0.1 M Tris buffer in D2O with chloride ion concentrations varying from 5 to 60 mM at 27 degrees C. Four histidyl residues in the deoxy form and one histidyl residue in the carbon monoxy form are found to have proton nuclear magnetic resonance titration curves that deviate greatly from that predicted by the simple proton dissociation equilibrium of a single ionizable group. The proton nuclear magnetic resonance data are used to ascertain the role of several surface histidyl residues in the Bohr effect of hemoglobin under the above-mentioned experimental conditions. Under these experimental conditions, we have found that (i) the beta 146 histidyl residues do not change their electrostatic environments significantly upon binding of ligand to deoxyhemoglobin and, thus, their contribution to the Bohr effect is negligible, (ii) the beta 2 histidyl residues have a negative contribution to the Bohr effect, and (iii) the total contribution of the 22 histidyl residues investigated here to the Bohr effect is, in magnitude, comparable to the Bohr effect observed experimentally. These results suggest that the molecular mechanism of the Bohr effect proposed by Perutz [Perutz, M.F. (1970) Nature (London) 228, 726-739] is not unique and that the detailed mechanism depends on experimental conditions, such as the solvent composition.

A proton nuclear magnetic resonance investigation of proximal histidyl residues in human normal and abnormal hemoglobins. A probe for the heme pocket

Proton nuclear magnetic resonance spectroscopy at 250 MHz has been used to investigate the conformations of proximal histidyl residues of human normal adult hemoglobin, hemoglobin Kempsey [beta 99(G1) Asp leads to Asn], hemoglobin Osler [beta 145(HC2) Tyr leads to Asp], and hemoglobin McKees Rocks [beta 145(HC2) Tyr leads to Term] around neutral pH in H2O at 27 degrees C, all in the deoxy form. Two resonances that occur between 58 and 76 ppm downfield from the water proton signal have been assigned to the hyperfine shifted proximal histidyl NH-exchangeable protons of the alpha- and beta-chains of deoxyhemoglobin. These two resonances are sensitive to the quaternary state of hemoglobin, amino acid substitutions in the alpha 1 beta 2-subunit interface and in the carboxy-terminal region of the beta-chain, and the addition of organic phosphates. The experimental results show that there are differences in the heme pockets among these four hemoglobins studied. The structural and dynamic information derived from the hyperfine shifted proximal histidyl NH-exchangeable proton resonances complement that obtained from the ferrous hyperfine shifted and exchangeable proton resonances of deoxyhemoglobin over the spectral region from 5 to 20 ppm downfield from H2O. The relationship between these findings and Perutz's stereochemical mechanism for the cooperative oxygenation of hemoglobin is discussed.

Structural, functional and conformational properties of rat hemoglobins

The oxygen equilibrium properties of rat total hemoglobin show pH dependence. Thus oxygen affinity and cooperativity, which are significantly reduced at pH 6.0, show increase with increasing pH. Conformational studies using nitrosyl derivatives indicate that in rat nitrosyl hemoglobin the R to T equilibrium is shifted towards the T state in going from pH 7.0 to pH 6.0. Under similar conditions human hemoglobin A shows no significant changes in cooperativity or conformation. These results indicate that a destabilized oxy structure (R) exist in rat hemoglobins at pH 6.0. Alterations in the heme pockets and alpha 1 beta 2 contact points could lead to these structural characteristics. Crystallization of rat hemoglobins is dependent on an oxy-like structure since all liganded ferrous derivatives and methemoglobin form crystals in the pH range of 7.0-8.0. Deoxygenation of oxyhemoglobin crystals or addition of inositol hexakisphosphate to nitrosyl or methemoglobin derivatives result in solubilization of the crystals. Thus the quaternary and/or tertiary structural changes involved in the transition of a R to T state disrupt the crystal structure. The precise positioning of the complementary sites involved in the interaction of amino acids between rat hemoglobin tetramers seems to occur only when the molecules are in the quaternary or tertiary R conformation. This is in contrast to the polymerization of human deoxyhemoglobin S, where gel formation occurs only in the T state.

Functional and conformational properties of mouse hemoglobins

Hemoglobins from four strains of mice (C3H/SW, DBA/2J, C57BL6/Kh and A.TH) examined showed pH-dependent heme-heme interactions. The oxygen affinity and cooperativity are reduced at acidic pH. The oxygen equilibrium parameters increase as a function of increasing pH and at physiological pH values they are similar to the corresponding values of human hemoglobin A. The nitrosyl derivatives of these mouse hemoglobins undergo a quaternary structural transition to the T state in going from pH 7.0 to 6.0. These functional and conformational properties are indicative of destabilised oxy structures of mouse hemoglobins at acidic pH. This study also confirms that the cysteine residue at beta 13(A10) position has no influence on the oxygen equilibrium properties or conformation of the molecule.

Spectral, conformational and chemical properties of opossum methemoglobin

Opossum methemoglobin differs from methemoglobin A in spectral, spin state, conformational and chemical properties. The primary structural alterations in opossum hemoglobin, including the critical substitution at alpha 58 (E7) His leads to Gln result in the following properties. (a) Major contribution of the spectral transitions due to inositol hexakisphosphate binding arises from the alpha chains. (b) The aquomet to hydroxymet (high-spin to low-spin) transition as a function of pH is slightly retarded resulting in considerable high spin at alkaline pH. (c) The tertiary conformation (t) around the beta hemes, upon transition to a T quaternary state, differs from the known hemoglobin t tertiary structure. (d) Both alpha and beta hemes are susceptible to rapid reduction by ascorbic acid (the reduction rate being tenfold faster than that of methemoglobin A). These properties suggest that the heme environments in both the alpha and beta subunits of opossum hemoglobin are different from those of human hemoglobin A.

Proton longitudinal relaxation investigation of histidyl residues of normal human adult and sickle deoxyhemoglobin: evidence for the existence of pregelation aggregates in sickle deoxyhemoglobin solutions

Proton nuclear magnetic resonance longitudinal-relaxation-rate measurements have been used to investigate the molecular events that occur during the early stages of the polymerization process of sickle hemoglobin. The longitudinal relaxation rates (T1-1) of the C2 protons of 11 observable surface histidyl residues in normal human adult and sickle hemoglobin in the deoxy state were measured in 0.1 M bis[(2-hydroxyethyl)imino]tris(hydroxymethyl)methane (pH 6.8) in 2H2O. These proton resonances in hemoglobin occur at a position 1.5-5.0 ppm downfield from that of residual water in 2H2O. The T1-1 values for the C2 protons of several surface histidyl residues in sickle hemoglobin in the deoxy state were sensitive to the temperature and the concentration of hemoglobin, factors known to have a profound effect on the polymerization process of sickle hemoglobin. For hemoglobin concentrations of 13.5% or less and temperatures of 25 degrees C or less, the T1-1 values in sickle hemoglobin solutions were the same as the corresponding values in normal hemoglobin, except for the C2 proton of beta 2 histidine, which had a larger T1-1 value. When the temperature or the hemoglobin concentration was increased (i) several additional histidine resonances in sickle hemoglobin solutions had larger T1-1 values than the corresponding ones in normal hemoglobin and (ii) the differences between the T1-1 values (sickle versus normal hemoglobin) of these histidine resonances as well as that of the beta 2 histidine resonance gradually increased. It is proposed that these results reflect the formation of small aggregates in the deoxygenated sickle hemoglobin solutions before gelation. In this model, the histidyl residues for which the T1-1 values are greatly increased in sickle hemoglobin solutions as compared with those in normal hemoglobin are viewed as being located in or near the "contact" areas between sickle hemoglobin molecules within the pregelation aggregates. Thus, this magnetic resonance technique can also be used to identify the intermolecular contacts in the polymerization of sickle hemoglobin.

Role of the beta 146 histidyl residue in the alkaline Bohr effect of hemoglobin

High-resolution proton nuclear magnetic resonance spectroscopy has been used to investigate the effects of inorganic anions, such as phosphate or chloride, on the alkaline Bohr effect of normal human adult hemoglobin. By monitoring the chemical shift of the C2 proton of the beta 146 histidyl residue as a function of pH, we have determined its pK values in both ligated and unligated forms. In the presence of 0.1 M Bis-Tris buffer (with chloride ion concentration ranging from 0.005 to 0.06 M) in D2O at 27 degrees C, the pK value of the beta 146 histidine of deoxyhemoglobin is 7.98 +/- 0.03 and that of (carbon monoxy)hemoglobin is 7.85 +/- 0.03. However, in the presence of 0.2 M phosphate and 0.2 M NaCl in D2O at 27 degrees C, the corresponding pK values are 8.08 and 7.14, as previously reported by this laboratory [Kilmartin, J. V., Breen, J. J., Roberts, G. C. K., & Ho, C. (1973) Proc. Natl. Acad. Sci. U.S.A. 70, 1246-1249]. This large difference in the pK value between the deoxy and carbon monoxy forms in the presence of 0.2 M phosphate and 0.2 M NaCl was interpreted as direct support for (1) the breaking of an intrasubunit salt bridge between beta 146 histidine and beta 94 aspartate when the hemoglobin molecule undergoes the quaternary structural transition as proposed by Perutz [Perutz, M. F. (1970) Nature (London) 228, 726-739] and (2) Perutz's suggestion that the beta 146 histidine is one of the amino acid residues responsible for the alkaline Bohr effect. The absence of a large change in the pK value of the beta 146 histidine in the presence of 0.1 M Bis-Tris buffer implies that (1) the above-mentioned intrasubunit salt bridge is not broken in going from the deoxy to the carbon monoxy form and (2) the beta 146 histidyl residue does not contribute significantly to the alkaline Bohr effect under these conditions. We have also found that in measuring the oxygen affinity of hemoglobin as a function of pH in the presence of 0.1 M Bis-Tris or 0.2 M phosphate plus 0.2 M NaCl (both in D2O), there is no significant difference in the alkaline Bohr effect in these two media. Hence, our results suggest that the detailed molecular mechanism for the Bohr effect depends on the experimental conditions.