Use of heme spin-labeling to probe heme environments of alpha and beta chains of hemoglobin.

A spin label attached to a propionic acid group of the heme has been used to probe the heme environment of the alpha and beta chains of hemoglobin in both the subunit and tetrameric forms. The electron paramagnetic resonance (EPR) studies of hemoglobin hybrids in which the spin label is attached to either the alpha- or beta-heme (alpha2SLbeta 2 or alpha2beta2SL) and spin-labeled isolated chains (alphaSL and betaSL) show that: 1) alpha- and beta-hemes have different environments in the tetrameric forms of oxy-, deoxy-, and methemoglobins as well as in isolated single chains; 2) when isolated subunits associate to form hemoglobin tetramers, the environment of the alpha-heme changes more drastically than that of the beta-heme; 3) upon deoxygenation of hemoglobin, the structure in the vicinity of the alpha-heme changes more drastically than that of the beta-heme; and 4) upon the addition of organic phosphates to methemoglobin, the change in the spin state of the heme irons mainly arises from beta-heme. The results demonstrate conclusively that the alpha and the beta subunits of hemoglobin are structurally nonequivalent as are their structural changes as the result of ligation. The relationship of EPR spectrum and structure of hemoglobin is discussed.     

Esterification of the propionate groups promotes alpha/beta hemoglobin chain homogeneity of CN-hemin binding

This study examines the post-translational role of peripheral propionate groups in the incorporation of the Fe-protoporphryin IX heme into nascent alpha- and beta-globin chains. Human apohemoglobin (a heme-free alpha/beta dimer) in 0.05 M potassium phosphate buffer, pH 7, at 20 degrees C was titrated with either CN-protohemin (native heme with two peripheral propionate groups), or CN-dimethylester hemin (a modified heme with two methyl ester groups in place of the propionate groups). Soret spectrophotometric CN-hemin titrations confirmed that a spectral shift resulted upon binding of protohemin, but no spectral shift occurred upon binding the dimethylester derivative. Recent studies have correlated a Soret spectral shift with the preferential heme binding to the alpha subunit of apohemoglobin. The absence of a Soret wavelength shift (in conjunction with molecular modeling) presented here suggested that the modification of heme propionate groups prevented the formation of an alpha-heme/beta-globin intermediate, a requisite step in the normal assembly of functional hemoglobin.     

Binding of CO to mutant alpha chains of hemoglobin M Iwate; evidence for distal imidazole ligation.

The optical contribution of the beta chains to the spectrum of hemoglobin M Iwate (alpha87his leads to tyr)2beta2a was subtracted with the aid of a computer so that the spectrum of ferric alpha chains was obtained. Tyrosinate binding to the heme is suggested from spectral resemblance to ferric heme phenolate in dimethyl sulfoxide. The slow reduction of the abnormal ferric alpha chains in hemoglobin M Iwate by dithionite was studied spectrophotometrically both in the presence and absence of CO. The rate of reduction was found to be dependent on the state of ligation of the normal beta chains. The CO-ligated form of the reduced alpha chains bears strong spectral resemblance to the CO-ligated form of the reduced beta chains suggesting similar structures for the heme-ligand complex. A model compound with similar optical properties to the CO-ligated protein can be prepared in dimethyl sulfoxide from hemin chloride, imidazole, and CO using chromous acetate as the heme reductant. Substitution of phenolate for imidazole produces a spectral entity so different from that observed in the protein as to rule out tyrosinate ligation to ferrous heme of the alpha chains when CO is bound.     

Binding reaction of hemin to globin

Binding of hemin to globin was studied in the presence of 25 mM caffeine by measuring CD and optical absorption changes in the Soret region. CD and optical absorption spectra after mixing equimolar amounts of hemin and globin were the same as those of ferric hemoglobin. In contrast, addition of excess globin to hemin formed a complex that was distinguishable from ferric hemoglobin in terms of the CD and optical absorption spectra. By comparing the spectra of the complex with those of various hemoglobin derivatives, it was concluded that the complex was globin which carried a hemin exclusively on the alpha chain. This means that the alpha chain of the globin molecule has a greater affinity for hemin than the beta chain, as observed by other investigators using hemin-cyanide. The rate of binding of hemin to globin was estimated by the use of CD and optical absorption stopped-flow apparatus. The rate of hemin binding to the alpha chain of globin was obtained by mixing hemin and excess globin, and that to the beta chain was obtained by mixing equimolar concentrations of hemin and globin. The results showed that hemin was bound to the alpha chain in the globin molecule to form a transient intermediate, followed by its transformation into another intermediate, the transformation was the rate-limiting step, and the beta chain in the globin molecule had a greater affinity for hemin after hemin binding to the alpha chain than before.     

The stability of the heme-globin linkage in some normal, mutant, and chemically modified hemoglobins.

The rates and equilibria of heme exchange between methemoglobin and serum albumin were measured using a simple new spectrophotometric method. It is based on the large difference between the spectrum of methemoglobin and that of methemealbumin at pH 8-9. The rate of heme exchange was found to be independent of the albumin concentration and inversely proportional to the hemoglobin (Hb) concentration. Taken together with the finding that the rate was 10 times greater for Hb Rothschild, which is completely dissociated into alpha beta dimers and 10 times smaller for two cross-linked hemoglobins, the subunits of which cannot dissociate, this showed that the rate of dissociation of heme from alpha beta dimers is very much greater than from tetramers. Conditions were found for the attainment of an equilibrium distribution of hemes between beta globin and albumin. The equilibrium distribution ratio, R = methemealbumin/albumin/methemoglobin/apohemoglobin, for hemoglobin A was 3.4 with human and 0.005 with bovine serum albumin. Both the rates of exchange and the R values of HbS and HbF were the same as that for HbA. The equilibrium distribution ratio for Hb Rothschild was 7 times greater than that for HbA whereas that of one but not the other of the cross-linked hemoglobins was 10 times smaller. The structural bases for these differences are analyzed.     

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.     

Deficient heme synthesis as the cause of noninducibility of hemoglobin synthesis in a Friend erythroleukemia cell line.

Friend cells of the line Fw are not induced to accumulate substantial amounts of hemoglobin and to become benzidine-positive when treated with butyric acid or other inducers, except in the presence of exogenous hemin. The cells are shown to have a deficiency in heme synthesis since they require exogenous hemin during the period of maximal hemoglobin synthesis; since endogenous heme synthesis cannot be induced to the level found in normal inducible Friend cells, even after hemoglobin synthesis has been induced by hemin and butyric acid and the hemin has then been withdrawn; since they are not inducible for ferrochelatase (heme synthetase) activity; and since they accumulate free globin chains after stimulation with butyric acid in the absence of hemlin. Comparison of globin synthesis and globin mRNA content of the cells shows that globin synthesis is not controlled by the hemin-controlled repressor of protein synthesis (HCR) nor by any specific translational control of globin synthesis by hemlin.     

UV resonance Raman studies of alpha-nitrosyl hemoglobin derivatives: relation between the alpha 1-beta 2 subunit interface interactions and the Fe-histidine bonding of alpha heme.

Human alpha-nitrosyl beta-deoxy hemoglobin A, alpha(NO)beta(deoxy), is considered to have a T (tense) structure with the low O(2) affinity extreme and the Fe-histidine (His87) (Fe-His) bond of alpha heme cleaved. The Fe-His bonding of alpha heme and the intersubunit interactions at the alpha 1-beta 2 contact of alpha(NO)-Hbs have been examined under various conditions with EPR and UV resonance Raman (UVRR) spectra excited at 235 nm, respectively. NOHb at pH 6.7 gave the UVRR spectrum of the R structure, but in the presence of inositol-hexakis-phosphate (IHP) for which the Fe-His bond of the alpha heme is broken, UVRR bands of Trp residues behaved half-T-like while Tyr bands remained R-like. The half-ligated nitrosylHb, alpha(NO)beta(deoxy), in the presence of IHP at pH 5.6, gave T-like UVRR spectra for both Tyr and Trp, but binding of CO to its beta heme (alpha(NO)beta(CO)) changed the UVRR spectrum to half-T-like. Binding of NO to its beta heme (NOHb) changed the UVRR spectrum to 70% T-type for Trp but almost R-type for Tyr. When the pH was raised to 8.2 in the presence of IHP, the UVRR spectrum of NOHb was the same as that of COHb. EPR spectra of these Hbs indicated that the Fe-His bond of alpha(NO) heme is partially cleaved. On the other hand, the UVRR spectra of alpha(NO)beta(deoxy) in the absence of IHP at pH 8.8 showed the T-like UVRR spectrum, but the EPR spectrum indicated that 40-50% of the Fe-His bond of alpha hemes was intact. Therefore, it became evident that there is a qualitative correlation between the cleavage of the Fe-His bond of alpha heme and T-like contact of Trp-beta 37. We note that the behaviors of Tyr and Trp residues at the alpha 1-beta 2 interface are not synchronous. It is likely that the behaviors of Tyr residues are controlled by the ligation of beta heme through His-beta 92(F8)-->Val-beta 98(FG5)-->Asp-beta 99(G1 )-->Tyr-alpha 42(C7) or Tyr-beta 145(HC2).     

The interaction of hemoglobin with phosphatidylserine vesicles

The interaction of hemoglobin with phosphatidylserine vesicles at low ionic strength and pH conditions was studied. The fluorescence intensity of a lipid embedded probe was quenched by bound Hb but could not be reversed by an elevation of ionic strength and pH. The irreversibility of the fluorescence quenching is a time-dependent process associated with changes in the heme Soret and visible spectra. The rate of these changes was much faster for methemoglobin than for either cyanomethemoglobin or oxyhemoglobin. Elevation of ionic strength released out of the bound hemoglobin into the water phase most of the globin but only a small fraction of the heme. The data are interpreted as demonstrating the ability of phosphatidylserine vesicles to compete with globin for the heme group. When Hb binds to the liposome, heme is being transferred into the lipid phase and the rate-limiting step is the dissociation of the heme-globin complex. The fact that binding of heme to the lipid vesicles is very strong was demonstrated by the failure of hemin to interact with globin when the two were rapidly mixed in the presence of phosphatidylserine vesicles. A multi-step process is suggested to explain the results of Hb phosphatidylserine interaction.     

Structure of cyanide methemoglobin

X-ray difference Fourier analysis at 2.8 Å resolution shows that the tertiary structures of horse cyanide methemoglobin and methemoglobin differ significantly. The conformations of the heme groups and their interactions with the globin are altered. Short contacts with globin side chains affect cyanide binding to the hemes, and the changes in globin-ligand contact upon substitution of cyanide for water in turn directly affect globin structure. Although the ligand peaks lie off the heme axes, the atoms FeCN may still lie on a straight line (as they do in small iron cyanide complexes), with this line not normal to the mean heme plane. This linear binding configuration is consistent with the observed motion and deformation of the porphyrin. Although motion of the iron atoms is not directly apparent, there is evidence that some changes in tertiary structure are induced by shortening of the iron-pyrrol nitrogen bond lengths. This and other studies suggest that the structural changes responsible for co-operativity in hemoglobin may be initiated not merely by an alteration in the covalent porphyrin-proximal histidine linkage, but by changes in the noncovalent interactions of the globin with the ligand and porphyrin as well.     

Significance of beta116 His (G18) at alpha1beta1 contact sites for alphabeta assembly and autoxidation of hemoglobin

The role of heterotetramer interaction sites in assembly and autoxidation of hemoglobin is not clear. The importance of beta(116His) (G-18) and gamma(116Ile) at one of the alpha1beta1 or alpha1gamma1 interaction sites for homo-dimer formation and assembly in vitro of beta and gamma chains, respectively, with alpha chains to form human Hb A and Hb F was assessed using recombinant beta(116His)(-->)(Asp), beta(116His)(-->)(Ile), and beta(112Cys)(-->)(Thr,116His)(-->)(Ile) chains. Even though beta chains (e.g., 116 His) are in monomer/tetramer equilibrium, beta(116Asp) chains showed only monomer formation. In contrast, beta(116Ile) and beta(112Thr,116Ile) chains showed homodimer and homotetramer formation like gamma-globin chains which contain 116 Ile. Assembly rates in vitro of beta(116Ile) or beta(112Thr,116Ile) chains with alpha chains were 340-fold slower, while beta(116Asp) chains promoted assembly compared to normal beta-globin chains. These results indicate that amino acid hydrophobicity at the G-18 position in non-alpha chains plays a key role in homotetramer, dimer, and monomer formation, which in turn plays a critical role in assembly with alpha chains to form Hb A and Hb F. These results also suggest that stable dimer formation of gamma-globin chains must not occur in vivo, since this would inhibit association with alpha chains to form Hb F. The role of beta(116His) (G-18) in heterotetramer-induced stabilization of the bond with oxygen in hemoglobin was also assessed by evaluating autoxidation rates using recombinant Hb tetramers containing these variant globin chains. Autoxidation rates of alpha(2)beta(2)(116Asp) and alpha(2)beta(2)(116Ile) tetramers showed biphasic kinetics with the faster rate due to alpha chain oxidation and the slower to the beta chain variants whose rates were 1.5-fold faster than that of normal beta-globin chains. In addition, NMR spectra of the heme area of these two hemoglobin variant tetramers showed similar resonance peaks, which are different from those of Hb A. Oxygen-binding properties of alpha(2)beta(2)(116His)(-->)(Asp) and alpha(2)beta(2)(116His)(-->)(Ile), however, showed slight alteration compared to Hb A. These results suggest that the beta116 amino acid (G18) plays a critical role in not only stabilizing alpha1beta1 interactions but also in inhibiting hemoglobin oxidation. However, stabilization of the bonds between oxygen and heme may not be dependent on stabilization of alpha1beta1 interactions. Tertiary structural changes may lead to changes in the heme region in beta chains after assembly with alpha chains, which could influence stability of dioxygen binding of beta chains.     

Studies on cobalt myoglobins and hemoglobins. Preparation of isolated chains containing cobaltous protoporphyrin IX and characterization of their equilibrium and kinetic properties of oxygenation and EPR spectra.

Human hemoglobin containing cobalt protoporphyrin IX or cobalt hemoglobin has been separated into two functionally active alpha and beta subunits using a new method of subunit separation, in which the -SH groups of the isolated subunits were successfully regenerated by treatment with dithiothreitol in the presence of catalase. Oxygen equilibria of the isolated subunit chains were examined over a wide range of temperature using Imai's polarographic method (Imai, K., Morimoto, H., Kotani, M., Watari, H., and Kuroda, M. (1970) Biochim. Biophys. Acta 200, 189-196). Kinetic properties of their reversible oxygenation were investigated by the temperature jump relaxation method at 16 degrees. Electron paramagnetic resonance characteristics of the molecules in both deoxy and oxy states were studies at 77K. The oxygen affinity of the individual regenerated chains was higher than that of the tetrameric cobalt hemoglobin and was independent of pH. The enthalpy changes of the oxygenation have been determined as -13.8 kcal/mol and -16.8 kcal/mol for the alpha and beta chains, respectively. The rates of oxygenation were similar to those reported for iron hemoglobin chains, whereas those of deoxygenation were about 10(2) times larger. The effects of metal substitution on oxygenation properties of the isolated chains were correlated with the results obtained previously on cobalt hemoglobin and cobalt myoglobin. The EPR spectrum of the oxy alpha chain showed a distinctly narrowed hyperfine structure in comparison with that of the oxy beta chain, indicating that the environment around the paramagnetic center (the bound oxygen) is different between these chains. In the deoxy form, EPR spectra of alpha and beta chains were indistinguishable. These observations suggest that one of the inequivalences between alpha and beta chains might exist near the distal histidine group.     

Perissodactyla: the primary structure of hemoglobins from the lowland tapir (Tapirus terrestris): glutamic acid in position 2 of the beta chains

The hemoglobins from a lowland tapir (Tapirus terrestris) were analysed and the complete primary structure is described. The globin chains were separated on CM cellulose column in 8M urea and the amino-acid sequences were determined in the liquid phase sequenator. The results show that globin consists of two alpha chains (alpha I and alpha II) and beta major and beta minor components. The alpha chains differ only at one position: alpha I contains aspartic acid and alpha II glycine. The beta chains are heterogeneous: aspartic and glutamic acid were found at position beta 21 and beta 73 of the beta major components and asparagine and serine at position beta 139. In the beta minor components four positions were found with more than one amino acid, namely beta 2, beta 4, beta 6 and beta 56. The sequences are compared with those of man, horse and rhinoceros. Four residues of horse methemoglobin, which are involved in the alpha 1 beta 1 contacts are substituted in tapir hemoglobins. In the alpha chains: alpha 107(G14)Ser----Val, alpha 111-(G18) Val----Leu, alpha 115(GH3) Asn----Asp or Gly; in the beta chains: beta 116(G18) Arg----Gln. The amino acid at beta 2 of the major components is glutamic acid while glutamine and histidine are found in the minor components. Although glutamic acid, a binding site for ATP, does not interact with 2,3-bisphosphoglycerate, glutamine and histidine in the minor components are responsible for the slight effect of 2,3-bisphosphoglycerate on tapir hemoglobin.     

Expression of functional soluble human alpha-globin chains of hemoglobin in bacteria

Individual, soluble human alpha-globin chains were expressed in bacteria with exogenous heme and methionine aminopeptidase. The yields of soluble alpha chains in bacteria were comparable to those of recombinant non-alpha chains expressed under the same conditions. Molecular mass and gel-filtration properties of purified recombinant alpha chains were the same as those of authentic human alpha chains. Biochemical and biophysical properties of isolated alpha chains were identical to those of native human alpha chains as assessed by UV/vis, circular dichroism (CD), and nuclear magnetic resonance (NMR) spectroscopy which contrasts with previous results of refolded precipitated alpha chains made in the presence of heme in vitro (M. T. Sanna et al., J. Biol. Chem. 272, 3478-3486, 1997). Mixtures of purified, soluble recombinant alpha-globin and native beta-globin chains formed heterotetramers in vitro, and oxygen- and CO-binding properties as well as the heme environment of the assembled tetramers were experimentally indistinguishable from those of native human Hb A. UV/vis, CD, and NMR spectra of assembled Hb A were also the same as those of human Hb A. These results indicate that individual expressed alpha chains are stable in bacteria and fold properly in vivo and that they then can assemble with free beta chains to form hemoglobin heterotetramers in vivo as well as in vitro.     

A proton nuclear magnetic resonance study of the quaternary structure of human homoglobins in water.

Proton nuclear magnetic resonance spectra of human hemoglobins in water reveal several exchangeable protons which are indicators of the quaternary structures of both the liganded and unliganded molecules. A comparison of the spectra of normal human adult hemoglobin with those of mutant hemoglobins Chesapeake (FG4alpha92 Arg yields Leu), Titusville (G1alpha94 Asp yields Asn), M Milwaukee (E11beta67 Val yields Glu), Malmo (FG4beta97 His yields Gln), Kempsey (G1beta99 Asp yields Asn), Yakima (G1beta99 Asp yields His), and New York (G15beta113 Val yields Glu), as well as with those of chemically modified hemoglobins Des-Arg(alpha141), Des-His(beta146), NES (on Cys-beta93)-Des-Arg(alpha141), and spin-labeled hemoglobin [Cys-beta93 reacted with N-(1-oxyl-2,2,6,6-tetramethyl-4-piperidinyl)iodoacetamide], suggests that the proton in the important hydrogen bond between the tyrosine at C7alpha42 and the aspartic acid at G1beta99, which anchors the alpha1beta2 subunits of deoxyhemoglobin (a characteristic feature of the deoxy quaternary structure), is responsible for the resonance at -9.4 ppm from water at 27 degrees. Another exchangeable proton resonance which occurs at -6.4 ppm from H2O is a spectroscopic indicator of the deoxy structure. A resonance at -5.8 ppm from H2O, which is an indicator of the oxy conformation, is believed to originate from the hydrogen bond between the aspartic acid at G1alpha94 and the asparagine at G4beta102 in the alpha1beta2 subunit interface (a characteristic feature of the oxy quaternary structure). In the spectrum of methemoglobin at pH 6.2 both the -6.4- and the -5.8ppm resonances are present but not the -9.4-ppm resonance. Upon the addition of inositol hexaphosphate to methemoglobin at pH 6.2, the usual resonance at -9.4 ppm is shifted to -10 ppm and the resonance at 6.4 ppm is not observed. In the spectrum of methemoglobin at pH greater than or equal to 7.6 with or without inositol hexaphosphate, the resonance at -5.8 ppm is present, but not those at -10 and -6.4 ppm, suggesting that methemoglobin at high pH has an oxy-like structure. Two resonances (at -8.2 and -7.3 ppm) which remain invariant in the two quaternary structures could come from exchangeable protons in the alpha1beta1 subunit interface and/or other exchangeable protons in the hemoglobin molecule which undergo no conformational changes during the oxygenation process. These exchangeable proton resonances serve as excellent spectroscopic probes of the quaternary structures of the subunit interfaces in studies of the molecular mechanism of cooperative ligand binding to hemoglobin.     

Nitric oxide-mediated heme oxidation and selective beta-globin nitrosation of hemoglobin from normal and sickle erythrocytes

Nitric oxide (NO) has been reported to modulate the oxygen affinity of blood from sickle cell patients (SS), but not that of normal adult blood (AA), with little or no heme oxidation. However, we had found that the NO donor compounds 2-(N, N-diethylamino)-diazenolate-2-oxide (DEANO) and S-nitrosocysteine (CysNO) caused increased oxygen affinity of red cells from both AA and SS individuals and also caused significant methemoglobin (metHb) formation. Rapid kinetic experiments in which HbA(0), AA, or SS erythrocytes were mixed with CysNO or DEANO showed biphasic time courses indicative of initial heme oxidation followed by reductive heme nitrosylation, respectively. Hemolysates treated with CysNO showed by electrospray mass spectrometry a peak corresponding to a 29 mass unit increase (consistent with NO binding) of both the beta(A) and beta(S) chains but not of the alpha chains. Therapeutic use of NO in sickle cell disease may ultimately require further optimization of these competing reactions, i.e., heme reactivity (nitrosylation or oxidation) versus direct S-nitrosation of hemoglobin on the beta-globin.     

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)     

Studies on Scapharca hemoglobins. Properties of the dimeric protein reconstituted with Fe- or Co-porphyrin

A native globin from the dimeric hemoglobin, hemoglobin I, of the mollusc Scapharca inaequivalvis has been obtained with the acid-acetone method. The globin has a lower sedimentation coefficient than the native protein at neutral pH; its reconstitution product with natural heme has the same physicochemical and functional properties as the native protein. proto- and meso-cobalt hemoglobin I have been prepared and characterized. proto-Cobalt hemoglobin I binds oxygen reversibly with a lower affinity and a lower cooperativity than native hemoglobin I; thus, the changes in the functional properties brought about by substitution of iron with cobalt are similar to those observed in human hemoglobin A. The EPR spectra of deoxy-proto-cobalt hemoglobin I and of the photolysis product of oxy-meso-cobalt hemoglobin I indicate that two histidine residues are the apical heme ligands. The broad signal at g = 2.38 in deoxy-proto-cobalt hemoglobin I points to a constrained structure of the heme site in this derivative which results from a distorted coordination of the hindered proximal histidine. A similar structure has been proposed previously for the alpha chains in deoxy-cobalt hemoglobin A.     

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

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