The functional similarity and structural diversity of human and cartilaginous fish hemoglobins.

Although many descriptions of adaptive molecular evolution of vertebrate hemoglobins (Hb) can be found in physiological text books, they are based mainly on changes of the primary structure and place more emphasis on conservation than alterations at the functional site. Sequence analysis alone, however, does not reveal much about the evolution of new functions in proteins. It was found recently that there are many functionally important structural differences between human and a ray (Dasyatis akajei) Hb even where sequence is conserved between the two. We have solved the structures of the deoxy and CO forms of a second cartilaginous fish (a shark, Mustelus griseus) Hb, and compared it with structures of human Hb, two bony fish Hbs and the ray Hb in order to understand more about how vertebrate Hbs have functionally evolved by the selection of random amino acid substitutions. The sequence identity of cartilaginous fish Hb and human Hb is a little less than 40 %, with many functionally important amino acid replacements. Wider substitutions than usually considered as neutral have been accepted in the course of molecular evolution of Hb. As with the ray Hb, the shark Hb shows functionally important structural differences from human Hb that involve amino acid substitutions and shifts of preserved amino acid residues induced by substitutions in other parts of the molecule. Most importantly, beta E11Val in deoxy human Hb, which overlaps the ligand binding site and is considered to play a key role in controlling the oxygen affinity, moves away about 1 A in both the shark and ray Hbs. Thus adaptive molecular evolution is feasible as a result of both functionally significant mutations and deviations of preserved amino acid residues induced by other amino acid substitutions.

Site-directed mutagenesis in hemoglobin: test of functional homology of the F9 amino acid residues of hemoglobin alpha and beta chains.

The cysteine residue at F9(93) of the human hemoglobin (Hb A) beta chain, conserved in mammalian and avian hemoglobins, is located near the functionally important alpha1-beta2 interface and C-terminal region of the beta chain and is reactive to sulfhydryl reagents. The functional roles of this residue are still unclear, although regulation of local blood flow through allosteric S-nitrosylation of this residue is proposed. To clarify the role of this residue and its functional homology to F9(88) of the alpha chain, we measured oxygen equilibrium curves, UV-region derivative spectra, Soret-band absorption spectra, the number of titratable -SH groups with p-mercuribenzoate and the rate of reaction of these groups with 4, 4'-dipyridine disulfide for three recombinant mutant Hbs with single amino acid substitutions: Ala-->Cys at 88alpha (rHb A88alphaC), Cys-->Ala at 93beta (rHb C93betaA) and Cys-->Thr at 93beta (rHb C93betaT). These Hbs showed increased oxygen affinities and impaired allosteric effects. The spectral data indicated that the R to T transition upon deoxygenation was partially restricted in these Hbs. The number of titratable -SH groups of liganded form was 3.2-3.5 for rHb A88alphaC compared with 2.2 for Hb A, whereas those for rHb C93betaA and rHb C93betaT were negligibly small. The reduction of rate of reaction with 4,4'-dipyridine disulfide upon deoxygenation in rHb A88alphaC was smaller than that in Hb A. Our experimental data have shown that the residues at 88alpha and 93beta have definite roles but they have no functional homology. Structure-function relationships in our mutant Hbs are discussed.

Magnesium(II) and zinc(II)-protoporphyrin IX's stabilize the lowest oxygen affinity state of human hemoglobin even more strongly than deoxyheme.

Studies of oxygen equilibrium properties of Mg(II)-Fe(II) and Zn(II)-Fe(II) hybrid hemoglobins (i.e. alpha2(Fe)beta2(M) and alpha2(M)beta2(Fe); M=Mg(II), Zn(II) (neither of these closed-shell metal ions binds oxygen or carbon monoxide)) are reported along with the X-ray crystal structures of alpha2(Fe)beta2(Mg) with and without CO bound. We found that Mg(II)-Fe(II) hybrids resemble Zn(II)-Fe(II) hybrids very closely in oxygen equilibrium properties. The Fe(II)-subunits in these hybrids bind oxygen with very low affinities, and the effect of allosteric effectors, such as proton and/or inositol hexaphosphate, is relatively small. We also found a striking similarity in spectrophotometric properties between Mg(II)-Fe(II) and Zn(II)-Fe(II) hybrids, particularly, the large spectral changes that occur specifically in the metal-containing beta subunits upon the R-T transition of the hybrids. In crystals, both alpha2(Fe)beta2(Mg) and alpha2(Fe-CO)beta2(Mg) adopt the quaternary structure of deoxyhemoglobin. These results, combined with the re-evaluation of the oxygen equilibrium properties of normal hemoglobin, low-affinity mutants, and metal substituted hybrids, point to a general tendency of human hemoglobin that when the association equilibrium constant of hemoglobin for the first binding oxygen molecule (K1) approaches 0.004 mmHg(-1), the cooperativity as well as the effect of allosteric effectors is virtually abolished. This is indicative of the existence of a distinct thermodynamic state which determines the lowest oxygen affinity of human hemoglobin. Moreover, excellent agreement between the reported oxygen affinity of deoxyhemoglobin in crystals and the lowest affinity in solution leads us to propose that the classical T structure of deoxyhemoglobin in the crystals represents the lowest affinity state in solution. We also survey the oxygen equilibrium properties of various metal-substituted hybrid hemoglobins studied over the past 20 years in our laboratory. The bulk of these data are consistent with the Perutz's trigger mechanism, in that the affinity of a metal hybrid is determined by the ionic radius of the metal, and also by the steric effect of the distal ligand, if present. However, there remains a fundamental contradiction among the oxygen equilibrium properties of the beta substituted hybrid hemoglobins.

Structures of the deoxy and CO forms of haemoglobin from Dasyatis akajei, a cartilaginous fish.

The three-dimensional structures of the deoxy- and carbonmonoxyhaemoglobin (Hb) from Dasyatis akajei, a stingray, have been determined at 1.6 and 1.9 A resolution, respectively. This is one of the most distantly related vertebrate Hbs to human HbA. Both structures resemble the respective forms of HbA, indicating that the alpha2beta2-type tetramer and the mode of the quaternary structure change are common to Hbs of jawed vertebrates. Larger deviations between D. akajei Hb and human HbA are observed in various parts of the molecule, even in the E and F helices. Significant mutations and/or conformational changes are also observed around the haems, in the C-terminal region of the beta subunit, in the alpha1beta2 interface and in the organic phosphate-binding site of HbA. Despite these structural differences, the oxygen affinity, haem-haem interaction, Bohr effect and organic phosphate effect of D. akajei Hb are all only moderately reduced. Compared with human HbA, the overall r.m.s. deviation of main-chain atoms in the helical regions of bony fish Hbs is smaller than that of D. akajei Hb.

Site-directed mutagenesis in hemoglobin: attempts to control the oxygen affinity with cooperativity preserved.

We synthesized three artificial human hemoglobin mutants in which Lys-66(E10)beta was replaced by Ser, Arg or Thr by site-directed mutagenic protein engineering. These engineered hemoglobins were designated as eHb K66betaS, eHb K66betaR and eHb K66betaT, respectively. By synthesizing these mutants we attempted to control the oxygen affinity of hemoglobin with cooperativity preserved and to clarify the functional role of Lys-66(E10)beta, as well. Such attempts may be useful for creating an oxygen carrier suitable as a blood substitute. The oxygen affinities of eHbs K66betaS, K66betaR and K66betaT were 1.3-, 1.5- and 2.3-fold, respectively, lower than that of reconstituted Hb A. Their allosteric properties such as the Bohr effect and the effect of inositol hexaphosphate were well preserved. Since the oxygen affinity of eHb K66betaT is comparable with that of red cells, it may be a potential candidate for a blood substitute. X-Ray crystallographic data for Hb Chico [Lys-66beta-->Thr], which is identical with eHb K66betaT, together with our computer simulation indicate that an interaction between the introduced Thr and the distal His via a water molecule lowers the oxygen affinity for the T state eHb K66betaT.

The artificial alpha1beta1-contact mutant hemoglobin, Hb Phe-35beta, shows only small functional abnormalities.

It was previously reported that Hb Philly with a mutation of Phe for Tyr at 35(C1)beta showed non-cooperative oxygen binding with a very high affinity and instability leading to hemolysis. Further, it lacked the 1H-NMR signal at 13.1 ppm from 2,2-dimethyl-2-silapentane-5-sulfonate in normal hemoglobin (Hb A), so that this signal was assigned to a hydrogen bond formed by Tyr-35(C1)beta. Surprisingly, our artificial mutant hemoglobin with the same mutation as Hb Philly showed slightly lowered oxygen affinity, almost normal cooperativity, the 1H-NMR signal at 13.1 ppm and no sign of instability. Our results indicate that the mutation reported for Hb Philly and the assignment of the 13.1 ppm signal need reexamination.

Oxygen equilibrium properties of chromium (III)-iron (II) hybrid hemoglobins.

Cr(III)-Fe(II) hybrid hemoglobins, alpha 2(Cr) beta 2(Fe) and alpha 2(Fe) beta 2(Cr), in which hemes in either the alpha- or beta-subunits were substituted with chromium(III) protoporphyrin IX (Cr(III)(PPIX), were prepared and characterized by oxygen equilibrium measurements. Because Cr(III)PPIX binds neither oxygen molecules nor carbon monoxide, the oxygen equilibrium properties of Fe(II) subunits within these hybrids can be analyzed by a two-step oxygen equilibrium scheme. The oxygen equilibrium constants for both hybrids at the second oxygenation step agree with those for human adult hemoglobin at the last oxygenation step (at pH 6.5-8.4 with an without inositol hexaphosphate at 25 degrees C). The similarity between the effects of the Cr(III)PPIX and each subunits' oxygeme on the oxygen equilibrium properties of the counterpart Fe(II) subunits within hemoglobin indicate the utility of Cr(III)PPIX as a model for a permanently oxygenated heme within the hemoglobin molecule. We found that Cr(III)-Fe(II) hybrid hemoglobins have several advantages over cyanomet valency hybrid hemoglobins, which have been frequently used as a model system for partially oxygenated hemoglobins. In contrast to cyanomet heme, Cr(III)PPIX within hemoglobin is not subject to reduction with dithionite or enzymatic reduction systems. Therefore, we could obtain more accurate and reasonable oxygen equilibrium curves of Cr(III)-Fe(II) hybrids in the presence of an enzymatic reduction system, and we could obtain single crystals of deoxy-alpha 2(Cr) beta 2(Fe) when grown in low salt solution in the presence of polyethylene glycol 1000 and 50 mM dithionite.

Transplanting a unique allosteric effect from crocodile into human haemoglobin.

Crocodiles are able to remain under water for more than one hour without surfacing to breathe and often kill their prey by drowning it. How do crocodiles stay under water for a long time? When they hold their breath, bicarbonate ions, the final product of respiration, accumulate and drastically reduce the oxygen affinity of haemoglobin, releasing a large fraction of haemoglobin-bound oxygen into the tissues. We have now located the bicarbonate-ion-binding site at the alpha 1 beta 2-subunit interface by making various human-crocodile chimaeric haemoglobins. Furthermore, we have been able to transplant the bicarbonate effect into human haemoglobin by replacing only a few residues, even though the amino-acid sequence identity between crocodile (Crocodylus niloticus) and human haemoglobins is only 68% for the alpha- and 51% for the beta-subunit. These results indicate that an entirely new function which enables species to adapt to a new environment could evolve in a protein by a relatively small number of amino-acid substitutions in key positions.

Site-directed mutagenesis in hemoglobin: functional and structural role of the penultimate tyrosine in the alpha subunit.

The penultimate tyrosine in the hemoglobin subunit is considered to be one of the most important residues for the normal structure and function of hemoglobin. To elucidate the functional and structural role of the penultimate residue in the alpha-subunit, we prepared new artificial mutants; Hb Y140 alpha Q, in which Tyr-140 alpha is replaced by a nonaromatic residue, Gln, and Hb Y140 alpha F, which loses its hydrogen bond to Val-93 alpha by the substitution of Phe for Tyr. HB Y140 alpha Q exhibited a markedly increased oxygen affinity and almost completely diminished cooperativity, whereas Hb Y140 alpha F showed similar but less extensively impaired function, indicating that the aromatic residue at the penultimate position in the alpha-subunit contributes to the stabilization of the T-quaternary structure as does the corresponding residue in the beta-subunit. However, the deoxygenated forms of these mutants bear significant T-state character in their spectroscopic properties observed at high protein concentrations. The tetramer-dimer equilibrium data of the mutants suggested that a significant part of the functional alterations observed for dilute solution appears to result from partial dissociation into alpha beta dimers rather than direct destabilization of the T-quaternary structure in the deoxygenated form. Therefore, we can conclude that the penultimate tyrosine in the alpha-chain plays a key role not only in the stabilization of the T-state but also in the subunit assembly.(ABSTRACT TRUNCATED AT 250 WORDS)

Site-directed mutagenesis in hemoglobin: functional and structural study of the intersubunit hydrogen bond of threonine-38(C3)alpha at the alpha 1-beta 2 interface in human hemoglobin.

To clarify the functional and structural roles of Thr-38 alpha at the alpha 1-beta 2 interface, two artificial alpha-chain mutants, in which Thr-38 alpha is replaced by Ser (Hb T38 alpha S) or Val (Hb T38 alpha V), were prepared. Thr-38 alpha is one of the highly conserved amino acid residues in hemoglobins and forms a hydrogen bond to Asp-99 beta, which is a crucial residue to stabilize the T state, via a water molecule in the deoxygenated form. We investigated their oxygen binding properties together with structural consequences of the mutations by using various spectroscopic probes. Their oxygen equilibrium curves showed small changes in the oxygen binding properties. Structural probes such as ultraviolet-region derivative and oxy-minus-deoxy difference spectra, resonance Raman scattering, and 1H-NMR spectra also indicated that the oxy and deoxy forms of these mutants show spectra characteristic of the R and T states, respectively, and the R-T transition is not very disturbed. The present structural and functional data of the mutants imply that the hydrogen bond between Thr-38 alpha and Asp-99 beta does not play a key role in stabilizing the deoxy T structure, which is in sharp contrast to the role of the hydrogen bond between Tyr-42 alpha and Asp-99 beta, and suggest that the interactions via the intersubunit hydrogen bonds are highly site-specific, depending on the amino acid residue which participates in them.

Effects of intra- and intersubunit hydrogen bonds on the R-T transition in human hemoglobin as studied with alpha 42(C7) and beta 145(HC2) mutations.

To clarify the effects of specific inter- and intrasubunit hydrogen bonds on the R-T transition in human hemoglobin (Hb A), the recombination reaction of carbon monoxide with artificial mutant Hbs was measured and analyzed. One of the hydrogen bonds we focused on is formed between Tyr-42 alpha and Asp-99 beta in the alpha 1-beta 2 interface of Hb A, which is one of the hydrogen bonds characteristic of the T state. Hb His-42 alpha, in which Tyr-42 alpha is replaced by His to perturb this hydrogen bond, showed that the ligand-free R to T transition rate was decreased by 20-fold compared with that for Hb A. This mutation caused the destabilization of the transition state in the R to T quaternary structure change by about 7 kJ mol-1, indicating that the hydrogen bond between Tyr-42 alpha and Asp-99 beta plays a definite role in the R-T transition as well as in stabilization of the equilibrium T state. Hb Phe-145 beta, in which Tyr-145 beta is replaced by Phe and the intrasubunit hydrogen bond between Tyr-145 beta and Val-98 beta is lacking, also showed a slow R-T transition rate as observed in Hb His-42 alpha. The published crystallographic data suggest that this intrasubunit hydrogen bond stabilizes the transition state by reducing the freedom of motion of the C-terminus of the beta subunit and, thereby, facilitates the R-T transition.

The porphyrin-iron hybrid hemoglobins. Absence of the Fe-His bonds in one type of subunits favors a deoxy-like structure with low oxygen affinity.

Protoporphyrin-protoheme hybrid hemoglobins (Hb), in which the protohemes (Fe) in either the alpha- or beta-subunits were substituted with protoporphyrins IX (PP) alpha(PP)2 beta(Fe)2 and alpha(Fe)2 beta(PP)2 have been prepared. The structural and functional properties of these hybrid Hbs were investigated by measuring oxygen equilibrium curves and proton nuclear magnetic resonance spectra. The equilibrium constants of the first ligand, K1, observed for alpha(PP)2 beta(Fe)2 were much smaller than K1 values of HbA. The effects of pH and inositol hexaphosphate on K1 were substantially diminished. On the other hand, K1 values of alpha(Fe)2 beta(PP)2 were similar to those of HbA, including the pH and inositol hexaphosphate effects. The deoxy forms of alpha(PP)2 beta(Fe)2 and alpha(Fe)2 beta(PP)2 showed exchangeable proton resonances at 11 and 14 parts/million arising from the hydrogen bonds at the alpha 1 beta 2 contact in a deoxy-like structure. In the liganded form, these signals were dependent upon solution conditions. As K1 became larger, the reduction in the intensity of these signals was observed for both liganded forms. The resonance position of E11 Val originating from the beta subunits of alpha(PP)2 beta(Fe-CO)2 also varied in accordance with K1. We compare properties of PP-Fe hybrids with those of Co-Fe and Ni-Fe hybrids and conclude that the first oxygen binding to the beta heme may be linked to the metal-proximal His interaction in the alpha subunits. However, the first oxygen binding to the alpha heme is linked minimally to the metal-proximal His interaction in the beta subunits but may be correlated instead to the position of E11 Val relative to the porphyrin plane in the beta subunits.

A mutagenic study of the allosteric linkage of His(HC3)146 beta in haemoglobin.

We have examined the contribution of His(HC3)146 beta to the alkaline Bohr effect of human haemoglobin (HbA) by replacing it with Gln, using site-directed mutagenesis, and studying the structural and functional consequences. Oxygen equilibrium curves of the mutant show that the effect of pH on the oxygen affinity, the alkaline Bohr effect, is half that of HbA in the presence of chloride ion and less than 10% in its absence. Crystallographic analysis shows that the mutation introduced only small structural changes localized to the site of substitution, proving that the replacement of the hydrogen bond between the ionizable side-chain of His146 beta and Asp94 beta by a hydrogen bond between the unionizable side-chain of Gln146 beta and the same aspartate is solely responsible for the reduction of the alkaline Bohr effect. Our data confirm that His(HC3)146 beta is predominantly responsible for the chloride-independent component of the alkaline Bohr effect which results from the breaking of the hydrogen bond between His(HC3)146 beta and Asp(FG1)94 beta accompanying the transition from the quaternary deoxy to oxy-structure.

Site-directed mutagenesis in hemoglobin: functional and structural role of inter- and intrasubunit hydrogen bonds as studied with 37 beta and 145 beta mutations.

In order to clarify the functional and structural role of intra- and intersubunit hydrogen bonds in human hemoglobin (Hb A), we prepared two artificial beta chain mutant hemoglobins by site-directed mutagenesis. The mutant Hb Phe-37 beta, in which Trp-37 beta is replaced by Phe to remove the intersubunit hydrogen bond between Asp-94 alpha and Trp-37 beta at the alpha 1-beta 2 interface in deoxy Hb A, showed a markedly increased oxygen affinity and almost completely diminished Bohr effect and cooperativity. However, 1H-NMR data indicated that the structure of deoxy Hb Phe-37 beta is rather similar to that of deoxy Hb A. The enhanced tetramer-to-dimer dissociation previously observed in Hb Hirose (Trp-37 beta----Ser) together with our observation of the effects of organic phosphate on the structure and function of Hb Phe-37 beta suggested that a large part of the abnormal properties of Hb Phe-37 beta observed for dilute solutions appears to result from partial dissociation into alpha beta dimers rather than direct destabilization of the T-quaternary structure in the deoxygenated state. Thus, the primary and direct role of the hydrogen bond between Asp-94 alpha and Trp-37 beta is to stabilize the tetrameric assembly, and thereby this hydrogen bond indirectly contributes to stabilization of the T-quaternary structure. The other mutant Hb Phe-145 beta has a Phe residue at the 145 beta site and lacks the intrasubunit hydrogen bond formed between Tyr-145 beta and the carbonyl group of Val-98 beta in deoxy Hb A.(ABSTRACT TRUNCATED AT 250 WORDS)

Site-directed mutagenesis in haemoglobin. Functional role of tyrosine-42(C7) alpha at the alpha 1-beta 2 interface.

To clarify the functional role of Tyr-42(C7) alpha, which forms a hydrogen bond with Asp-99(G1) beta at the alpha 1-beta 2 interface of human deoxyhaemoglobin, we engineered two artificial mutant haemoglobins (Hb), in which Tyr-42 alpha was replaced by Phe (Hb Phe-42 alpha) or His (Hb His-42 alpha), and investigated their oxygen binding properties together with structural consequences of the mutations by using various spectroscopic probes. Like most of the natural Asp-99 beta mutants, Hb Phe-42 alpha showed a markedly increased oxygen affinity, a reduced Bohr effect and diminished co-operativity. Structural probes such as ultraviolet-region derivative and oxy-minus-deoxy difference spectra, resonance Raman scattering and proton nuclear magnetic resonance spectra indicate that, in Hb Phe-42 alpha, the deoxy T quaternary structure is highly destabilized and the strain imposed on the Fe-N epsilon (proximal His) bond is released, stabilizing the oxy tertiary structure. In contrast with Hb Phe-42 alpha, Hb His-42 alpha showed an intermediately impaired function and only moderate destabilization of the T-state, which can be explained by the formation of a new, weak hydrogen bond between His-42 alpha and Asp-99 beta. Spectroscopic data were consistent with this assumption. The present study proves that the hydrogen bond between Tyr-42 alpha and Asp-99 beta plays a key role in stabilizing the deoxy T structure and consequently in co-operative oxygen binding.

NMR study of human mutant hemoglobins synthesized in Escherichia coli. Consequences of tyrosine alpha 42 substitutions.

The hydroxyl group of Tyr alpha 42 in human hemoglobin forms a hydrogen bond with the carboxylate of Asp beta 99 which is considered to be one of the most important hydrogen bonds for stabilizing the "T-state." However, no spontaneous mutation at position 42 of the alpha subunit has been reported, and the role of the tyrosine has not been tested experimentally. Two artificial human mutant hemoglobins in which Tyr alpha 42 was replaced by phenylalanine or histidine were synthesized in Escherichia coli, and their proton NMR spectra were studied with particular attention to the hyperfine-shifted and hydrogen-bonded proton resonances. The site-directed mutagenesis of the Tyr alpha 42----Phe removes the hydrogen bond described above and prevents transition to the T-state so that the mutant Hb is rather similar to the "R-state" even when deoxygenated. On the other hand, the mutation from tyrosine to histidine causes less drastic structural changes, and its quaternary and tertiary structures are almost the same as native deoxy-Hb A. This may be attributed to the formation of a new hydrogen bond between His alpha 1(42) and Asp beta 2(99). These observations indicate that the hydrogen bond formed between Tyr alpha 42 and Asp beta 99 is required to convert unliganded Hb to the T-state.

Structural and functional consequences of amino acid substitutions in hemoglobin as manifested in natural and artificial mutants.

Compiled data for more than 440 natural human hemoglobin mutants with single amino acid substitutions indicate that molecular properties (oxygen binding, structural stability, ease of autooxidization, etc.) of more than half of them are altered in some way and that the mode of alteration is closely related to the region within the hemoglobin molecule in which the substitution takes place. The present study gives a quantitative basis for the correlations. By means of protein engineering, including site-directed mutagenesis, several artificial mutants of human hemoglobin were prepared and their oxygen binding properties were studied to investigate the functional consequences of the amino acid substitutions which have not yet been isolated in natural mutants. These artificial mutants gave straight-forward information regarding the major factors regulating the oxygen affinity of heme and the identification of a Bohr group in the alpha chain. On the other hand the mutants, which were designed to test some hypotheses for the molecular evolution in hemoglobin, did not necessarily give the results predicted from accumulated structure-function data obtained from the study of natural mutants and X-ray crystallographic analyses.

Distal residues in the oxygen binding site of haemoglobin studied by protein engineering.

The geometries of the Fe-O2 and Fe-CO bonds in myoglobin and haemoglobin differ significantly from those in free porphyrin model compounds. It has been suggested that steric hindrance by Val-E11 and His-E7 and a hydrogen bond between His-E7 and oxygen affect the geometry and electronic state of the Fe-ligand bond, and that these interactions may be important in controlling oxygen affinity. We have produced mutant haemoglobins in E. coli having Val(67 beta)E11 replaced by Ala, Met, Leu or Ile and His(58 beta)E7 by Gln, Val or Gly. We have studied the effect of these mutations on the equilibrium and kinetics of ligand binding. The conformation of the new side chains and their effect on the protein structure have been examined by X-ray crystallography, and the vibrational properties of the Fe-CO bond observed by resonance Raman spectroscopy. We found that the steric hindrance of ligand binding by the E11 residue and the polarity of the E7 residue in the beta subunit are critical for fine-tuning ligand affinity.

Oxygen equilibrium study and light absorption spectra of Ni(II)-Fe(II) hybrid hemoglobins.

Ni(II)-Fe(II) hybrid hemoglobins, in which hemes in either the alpha or beta subunit are substituted with Ni(II) protoporphyrin IX, have been prepared and characterized. Since Ni(II) protoporphyrin IX binds neither oxygen nor carbon monoxide, the oxygen equilibrium properties of the Fe subunit in these hybrid hemoglobins were specifically determined. K1 values, namely the equilibrium constants for the first oxygen molecule to bind to hemoglobin, agreed well for these hybrid hemoglobins with the K1 value of native hemoglobin A in various conditions. Therefore, Ni(II) protoporphyrin IX in these hybrid hemoglobins behaves like a permanently deoxygenated heme. Both Ne-Fe hybrid hemoglobins bound oxygen non-co-operatively at low pH values. When the pH was raised, alpha 2 (Fe) beta 2 (Ni) showed co-operativity, but the complementary hybrid, alpha 2 (Ni) beta 2 (Fe), did not show co-operativity even at pH 8.5. The light absorption spectra of Ni(II)-Fe(II) hybrid hemoglobins indicated that the coordination states of Ni(II) protoporphyrin IX in the alpha subunits responded to the structure of the hybrid, whereas those in the beta subunits were hardly changed. In a deoxy-like structure (the structure that looks like that observed in deoxyhemoglobin), four-co-ordinated Ni(II) protoporphyrin IX was dominant in the alpha (Ni) subunits, while under the conditions that stabilized an oxy-like structure (the structure that looks like that observed in oxyhemoglobin), five-co-ordinated Ni(II) protoporphyrin IX increased. The small change observed in the absorption spectrum of the beta (Ni) subunits is not related to the change of the co-ordination number of Ni(II) protoporphyrin IX. Non-co-operative binding of oxygen to the beta subunits in alpha 2 (Ni) beta 2 (Fe) accompanied the change of absorption spectrum in the alpha (Ni) subunits. We propose a possible interpretation of this unique feature.