Structure of nitric oxide hemoglobin

We have compared the structure of horse nitric oxide hemoglobin (HbNO) and methemoglobin in the oxy quaternary structure by difference Fourier analysis at 2.8 Å resolution. Both nitric oxide and oxygen assume bent co-ordination geometry and form low-spin complexes in binding to heme; on the basis of preferred ligand and heme stereochemistry, HbNO is the closest analog of HbO₂ (oxyhemoglobin) examined to date. To the resolution of the X-ray data, the stereochemistry of the heme-NO complex in hemoglobin and the corresponding free heme complex appears similar. In contrast, the ligand pockets in hemoglobin hinder binding of cyanide and carbon monoxide in their preferred linear axial co-ordination modes and force them to assume a strained off-axis binding stereochemistry. The structural similarity between HbNO and HbO₂ is reflected in their kinetic behavior, which is similar, and distinct from that of carboxyhemoglobin.     

Cyanide binding to the cytochrome c ferric heme octapeptide. A model for anion binding to the active site of high spin ferric heme proteins

Equilibrium constants for the binding of cyanide to the ferric heme c octapeptide in 20% ethylene glycol, 50% buffer were measured spectrophotometrically. The equilibrium constant for cyanide binding at 20 degrees C and pH 7.4 is 3.47 X 10(7), which is approximately 15-fold lower than that observed for cyanide binding to methemoglobin or metmyoglobin. Equilibrium constants at several temperatures exhibited an apparent van't Hoff relationship, yielding thermodynamic values of delta H degrees = -79,000 J/mol (-18,900 cal/mol) and delta S degrees = J/degrees K mol (-30.1 e.u.). Comparison of the ratio of equilibrium constants for cyanide ligation to methemoglobin the heme octapeptide with the ratio of equilibrium constants for azide ligation to methemoglobin and the heme octapeptide suggests that cyanide binding to the methemoproteins is much smaller than expected by comparison to azide binding. The differences in the ratios, the thermodynamic values, and the preferred binding geometries suggest that CN- ligation, like CO ligation, is sterically hindered. A comparison of these ratios to similar ratios for CO, O2, and NO binding suggests that the Fe-CN bond angle is less subject to distortion than the Fe-CO bond and/or additional binding interactions contribute to N3- but not to CN-binding to the protein.     

Contribution of protein conformation to stereochemistry and reactivity of the active center of heme proteins and enzymes. The existence of horseradish peroxidase conformations and their possible role in the catalysis mechanism

In the spectral region 350-800 nm at 4.2 K we measured magnetic circular dichroism (MCD) spectra of the pentacoordinated complex of protcheme with 2-methylimidazole, deoxyleghemoglobin, neutral and alkaline forms of reduced horseradish peroxidase in the equilibrium states, as well as in non-equilibrium states produced by low-temperature photolysis of their carbon monoxide derivatives. Earlier the corresponding results have been obtained for myoglobin, hemoglobin and cytochromes P-450 and P-420. The energies of Fe-N (proximal His) and Fe-N(pyrroles) bonds and their changes upon ligand binding in heme proteins and enzymes were compared with those in the model heme complex thus providing conformational contribution into stereochemistry of the active site. The examples of weak and strong conformational "pressure" on stereochemistry were analysed and observed. If conformational energy contribution into stereochemistry prevails the electronic one the heme stereochemistry remains unchanged on ligand binding as it was observed for leghemoglobin and alkaline horseradish peroxidase. The change of bond energies in myoglobin and hemoglobin on ligand binding are comparable with those in protein free pentacoordinated protoheme, giving an example of weak conformational contribution to heme stereochemistry. The role of protein conformation energy in the modulation of ligand binding properties of heme in leghemoglobin relative to those in myoglobins is discussed. The most striking result were obtained in the study of reduced horseradish peroxidase in the pH region of 6.0-10.2. It was found that such different perturbations as ligand binding and heme-linked ionization of the distal amino acid residue induce identical changes in heme stereochemistry. Neither heme-linked ionization in the carbon monoxide complex nor the geometry of Fe-Co bond affect the heme local structure of photoproducts. These and other findings suggest a very low conformation mobility of horseradish peroxidase whose protein constraints appear to allow only two preferable geometries of specific amino acid residues that form the heme pocket. The role of the two tertiary structure constraints on the heme in the mechanism of horseradish peroxidase function is discussed. It is supposed that one conformation produces a heme environment suitable for two-electron oxidation of the native enzyme to compound I by hydrogen peroxide while another conformation changes the heme stereochemistry in the direction favourable for back reduction of compound I by the substrate to the resting enzyme through two one-electron steps. The switch from one tertiary structure to another is expected to be induced by substrate bind     

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.     

Cytochrome P-450scc-substrate interactions. Role of the 3 beta- and side chain hydroxyls in binding to oxidized and reduced forms of the enzyme

The steroid binding specificity of cytochrome P-450scc has been investigated for different oxidation/reduction and ligand-binding states of the enzyme (oxidized, reduced, oxygen-bound, and carbon monoxide-bound forms). The oxygen of the 3 beta-hydroxyl of cholesterol is important for the initial enzyme-substrate interaction. Significant binding requires the correct stereochemistry and appears to be controlled by the electron density on the 3 beta-oxygen. Interactions at this position (located at least 13 A from the heme iron) can modulate the heme midpoint potential. The binding site in this region contains a cleft which can accommodate up to two carbons joined in an ether linkage to the 3 beta-oxygen. The steroid intermediates of side chain cleavage (22R-hydroxycholesterol and 20 alpha,22R-dihydroxycholesterol) bind more tightly to the ferric enzyme than does cholesterol and utilize specific interactions of these side chain hydroxyls with a grouping(s) on the polypeptide chain (i.e. not with the heme iron). The interaction requires the correct stereochemistry; a 22S-hydroxyl cannot be readily accommodated in the binding site. The specificity of the interaction for hydroxyls at the 22R- versus the 20 alpha-position is altered upon reduction of the enzyme, indicating a reduction-induced conformational change in the active site. The specific interference of binding of 22R-hydroxy steroids by heme-bound carbon monoxide (but not oxygen), together with the known bond angles and distances for Fe-C-O and Fe-O-O, allows localization of the 22R-hydroxyl group on a line perpendicular to the heme plane, between 2 and 3 A from the iron.     

Reaction of the microsomal heme oxygenase with cobaltic protoporphyrin IX, and extremely poor substrate.

A reconstituted heme oxygenase system which was composed of a purified heme oxygenase from pig spleen microsomes and a partially purified NADPH-cytochrome c reductase from pig liver microsomes could not catalyze the conversion of cobaltic protoporphyrin IX (Co-heme) to biliverdin, although Co-heme could bind with the heme oxygenase protein to form a complex. The heme oxygenase system in the microsomes from pig spleen, rat spleen, and rat kidney also failed to oxidize Co-heme to biliverdin. Properties of the complex of Co-heme and heme oxygenase closely resembled those of cobalt myoglobin and cobalt hemoglobin; the Co-heme bound to the heme oxygenase protein did not react with cyanide and azide, the Co-heme moiety was reduced but only slowly with sodium dithionite, and the reduced form of the Co-heme did not appear to bind carbon monoxide. The co-heme bound to heme oxygenase was not reduced with the NADPH-cytochrome c reductase system in air. These findings further support the views that heme oxygenase may have a heme-binding crevice similar to those of myoglobin and hemoglobin and that reduction of heme is the prerequisite for the oxidative degradation of heme in the heme oxygenase reaction.     

Interaction of human adult methemoglobin in low-spin state with inositol hexaphosphate. A proton magnetic resonance study

The hyperfine-shifted proton nuclear magnetic resonance (NMR) spectra of the low-spin complexes of human adult methemoglobin were found to be much altered by the addition of inositol hexaphosphate (IHP). The stoichiometry and pH-dependence of IHP binding, and the spin equilibrium of azide methemoglobin are parallel to those of high-spin human methemoglobin and of carp methemoglobin, both of which are proposed to be switched from the R to T states with IHP. The present NMR results show that IHP affects the structure of human methemoglobin regardless of the spin state of the heme iron, suggesting that there is no correspondence between quaternary structure and the spin state of ferric heme iron.     

Effect of sheep haptoglobin on the hemoglobin molecule in the Hp-Hb complex

Sheep haptoglobin (HpC) binding hemoglobin increases the stability of the latter to acid denaturation and oxidation by atmospheric O2. HpC is also capable of binding methemoglobin (MetHb) denaturated at pH 3.5 to form a stable complex. This process is accompanied by partial reconstitution of the structural integrity and peroxidase activity of MetHb. Consequently, the formation of a HpC-MetHb complex leads to changes in the tertiary structure of the MetHb molecule. The increase in the peroxidase activity of MetHb at pH less than or equal to 4.0 after its binding to HpC is due to the stabilizing and stimulating activity of HpC.     

Ligand binding and structural perturbations in cytochrome c peroxidase. A crystallographic study

Crystal structures of the complexes formed between cytochrome c peroxidase and cyanide, nitric oxide, carbon monoxide, and fluoride have been determined and refined to 1.85 A. In all four complexes significant changes occur in the distal heme pocket due to movement of Arg-48, His-52, and a rearrangement of active site water molecules. In the cyanide, nitric oxide, and carbon monoxide complexes, Arg-48 moves away from the ligand while in the fluoride complex Arg-48 moves in toward the ligand to form a hydrogen bond or ion pair with the fluoride. More subtle changes occur on the proximal side of the heme. In an earlier study at lower resolution (Edwards, S. L., Kraut, J., and Poulos, T. L. (1988) Biochemistry 27, 8074-8081), we found that nitric oxide binding causes perturbations in the proximal domain involving Trp-191 which has been confirmed by the present study. Trp-191 is stacked parallel to and in contact with the proximal ligand, His-175. Nitric oxide binding results in a slight movement of Trp-191 away from His-175 and a large increase in crystallographic temperature factors indicating increased mobility of these residues on the proximal side of the heme. These proximal-side changes are unique to nitric oxide and are not related strictly to spin-state or oxidation state of the iron atom since similar changes were not observed in the cyanide (low-spin ferric), carbon monoxide (low-spin ferrous), or fluoride (high-spin ferric) complexes.     

The X-ray structure of ferric Escherichia coli flavohemoglobin reveals an unexpected geometry of the distal heme pocket

The x-ray structure of ferric unliganded lipid-free Escherichia coli flavohemoglobin has been solved to a resolution of 2.2 A and refined to an R-factor of 19%. The overall fold is similar to that of ferrous lipid-bound Alcaligenes eutrophus flavohemoglobin with the notable exception of the E helix positioning within the globin domain and a rotation of the NAD binding module with respect to the FAD-binding domain accompanied by a substantial rearrangement of the C-terminal region. An inspection of the heme environment in E. coli flavohemoglobin reveals an unexpected architecture of the distal pocket. In fact, the distal site is occupied by the isopropyl side chain Leu-E11 that shields the heme iron from the residues in the topological positions predicted to interact with heme iron-bound ligands, namely Tyr-B10 and Gln-E7, and stabilizes a pentacoordinate ferric iron species. Ligand binding properties are consistent with the presence of a pentacoordinate species in solution as indicated by a very fast second order combination rates with imidazole and azide. Surprisingly, imidazole, cyanide, and azide binding profiles at equilibrium are not accounted for by a single site titration curve but are biphasic and strongly suggest the presence of two distinct conformers within the liganded species.     

The spin-state transition of the hemochrome non-equilibrium conformation in partially reduced human methemoglobin. A pulse-radiolysis study of aqueous-methanol solutions of methemoglobin.

The effect of external parameters on the relaxation process of the hemochrome-type non-equilibrium conformation in partially reduced methemoglobin has been investigated. The relaxation of the intermediate ferrous low-spin state to the high-spin equilibrium conformation of hemoglobin appears to be facilitated particularly by protons and phosphate ions. In addition to studying the spin-state transition in aquomethemoglobin we have also studied it in complexes of the heme group in methemoglobin with fluoride, azide and cyanide anions.     

Intermediates detected by visible spectroscopy during the reaction of nitrite with deoxyhemoglobin: the effect of nitrite concentration and diphosphoglycerate

The reaction of nitrite with deoxyhemoglobin (deoxyHb) results in the reduction of nitrite to NO, which binds unreacted deoxyHb forming Fe(II)-nitrosylhemoglobin (Hb(II)NO). The tight binding of NO to deoxyHb is, however, inconsistent with reports implicating this reaction with hypoxic vasodilation. This dilemma is resolved by the demonstration that metastable intermediates are formed in the course of the reaction of nitrite with deoxyHb. The level of intermediates is quantitated by the excess deoxyHb consumed over the concentrations of the final products formed. The dominant intermediate has a spectrum that does not correspond to that of Hb(III)NO formed when NO reacts with methemoglobin (MetHb), but is similar to metHb resulting in the spectroscopic determinations of elevated levels of metHb. It is a delocalized species involving the heme iron, the NO, and perhaps the beta-93 thiol. The putative role for red cell reacted nitrite on vasodilation is associated with reactions involving the intermediate. (1) The intermediate is less stable with a 10-fold excess of nitrite and is not detected with a 100-fold excess of nitrite. This observation is attributed to the reaction of nitrite with the intermediate producing N2O3. (2) The release of NO quantitated by the formation of Hb(II)NO is regulated by changes in the distal heme pocket as shown by the 4.5-fold decrease in the rate constant in the presence of 2,3-diphosphoglycerate. The regulated release of NO or N2O3 as well as the formation of the S-nitroso derivative of hemoglobin, which has also been reported to be formed from the intermediates generated during nitrite reduction, should be associated with any hypoxic vasodilation attributed to the RBC.     

Covalent heme attachment in Synechocystis hemoglobin is required to prevent ferrous heme dissociation

Synechocystis hemoglobin contains an unprecedented covalent bond between a nonaxial histidine side chain (H117) and the heme 2-vinyl. This bond has been previously shown to stabilize the ferric protein against denaturation, and also to affect the kinetics of cyanide association. However, it is unclear why Synechocystis hemoglobin would require the additional degree of stabilization accompanying the His117-heme 2-vinyl bond because it also displays endogenous bis-histidyl axial heme coordination, which should greatly assist heme retention. Furthermore, the mechanism by which the His117-heme 2-vinyl bond affects ligand binding has not been reported, nor has any investigation of the role of this bond on the structure and function of the protein in the ferrous oxidation state. Here we report an investigation of the role of the Synechocystis hemoglobin His117-heme 2-vinyl bond on structure, heme coordination, exogenous ligand binding, and stability in both the ferrous and ferric oxidation states. Our results reveal that hexacoordinate Synechocystis hemoglobin lacking this bond is less stable in the ferrous oxidation state than the ferric, which is surprising in light of our understanding of pentacoordinate Hb stability, in which the ferric protein is always less stable. It is also demonstrated that removal of the His117-heme 2-vinyl bond increases the affinity constant for intramolecular histidine coordination in the ferric oxidation state, thus presenting greater competition for the ligand binding site and lowering the observed rate and affinity constants for exogenous ligands.     

Cyanide binding to hexacoordinate cyanobacterial hemoglobins: hydrogen-bonding network and heme pocket rearrangement in ferric H117A Synechocystis hemoglobin

The truncated hemoglobin (Hb) from the cyanobacterium Synechocystis sp. PCC 6803 is a bis-histidyl hexacoordinate complex in the absence of exogenous ligands. This protein can form a covalent cross-link between His117 in the H-helix and the heme 2-vinyl group. Cross-linking, the physiological importance of which has not been established, is avoided with the His117Ala substitution. In the present work, H117A Hb was used to explore exogenous ligand binding to the heme group. NMR and thermal denaturation data showed that the replacement was of little consequence to the structural and thermodynamic properties of ferric Synechocystis Hb. It did, however, decelerate the association of cyanide ions with the heme iron. Full complexation required hours, instead of minutes, of incubation at optical and NMR concentrations. At neutral pH and in the presence of excess cyanide, binding occurred with a first-order dependence on cyanide concentration, eliminating distal histidine decoordination as the rate-limiting step. The cyanide complex of the H117A variant was characterized for the conformational changes occurring as the histidine on the distal side, His46 (E10), was displaced. Extensive rearrangement allowed Tyr22 (B10) to insert in the heme pocket and Gln43 (E7) and Gln47 (E11) to come in contact with it. H-bond formation to the bound cyanide was identified in solution with the use of (1)H(2)O/(2)H(2)O mixtures. Cyanide binding also resulted in a change in the ratio of heme orientational isomers, in a likely manifestation of heme environment reshaping. Similar observations were made with the related Synechococcus sp. PCC 7002 H117A Hb, except that cyanide binding was rapid in this protein. In both cases, the (15)N chemical shift of bound cyanide was reminiscent of that in peroxidases and the orientation of the proximal histidine was as in other truncated Hbs. The ensemble of the data provided insight into the structural cooperativity of the heme pocket scaffold and pointed to the reactive 117 site of Synechocystis Hb as a potential determinant of biophysical and, perhaps, functional properties.     

Interactions among substrates and inhibitors of nitrogenase.

Examination of interactions among various substrates and inhibitors reacting with a partially purified nitrogenase from Azotobacter vinelandii has shown that: nitrous oxide is competitive with N2; carbon monixide and acetylene are noncompetitive with N2; carbon monoxide, cyanide, and nitrous oxide are noncompetitive with acetylene, whereas N2 is competitive with acetylene; carbon monoxide is noncompetitive with cyanide, whereas azide is competitive with cyanide; acetylene and nitrous oxide increase the rate of reduction of cyanide. The results are understandable if nitrogenase serves as an electron sink and substrates and inhibitors bind at multiple modified sites on reduced nitrogenase. It is suggested that substrates such as acetylene may be reduced by a less completely reduced electron sink than is required for the six-electron transfer necessary to reduce N2.     

Spectroscopic and ligand-binding properties of an oxygen-binding heme protein from Chromatium vinosum

Magnetic circular dichroism spectra were obtained for the oxidized and reduced forms of cyanide, azide and carbon monoxide complexes of an O2-binding hemeprotein isolated from the photosynthetic purple sulfur bacterium, Chronatium vinosum. Cyanide binding to the protein, which results in formation of a low-spin complex, was highly pH dependent with little complex formation observed at pH values near or below 7.     

Coordination structure of the ferric heme iron in engineered distal histidine myoglobin mutants.

Recombinant human myoglobin mutants with the distal His residue (E7, His64) replaced by Leu, Val, or Gln residues were prepared by site-directed mutagenesis and expression in Escherichia coli. Electronic and coordination structures of the ferric heme iron in the recombinant myoglobin proteins were examined by optical absorption, EPR, 1H NMR, magnetic circular dichroism, and x-ray spectroscopy. Mutations, His-->Val and His-->Leu, remove the heme-bound water molecule resulting in a five-coordinate heme iron at neutral pH, while the heme-bound water molecule appears to be retained in the engineered myoglobin with His-->Gln substitution as in the wild-type protein. The distal Val and distal Leu ferric myoglobin mutants at neutral pH exhibited EPR spectra with g perpendicular values smaller than 6, which could be interpreted as an admixture of intermediate (S = 3/2) and high (S = 5/2) spin states. At alkaline pH, the distal Gln mutant is in the same so-called "hydroxy low spin" form as the wild-type protein, while the distal Leu and distal Val mutants are in high spin states. The ligand binding properties of these recombinant myoglobin proteins were studied by measurements of azide equilibrium and cyanide binding. The distal Leu and distal Val mutants exhibited diminished azide affinity and extremely slow cyanide binding, while the distal Gln mutant showed azide affinity and cyanide association rate constants similar to those of the wild-type protein.     

Structural characterization of lactoperoxidase in the heme environment by proton NMR spectroscopy

The heme environmental structures of lactoperoxidase (LP) have been studied by the use of hyperfine-shifted proton NMR and optical absorption spectra. The NMR spectra of the enzyme in native and cyanide forms in H2O indicated that the fifth ligand of the heme iron is the histidyl imidazole with an anionic character and that the sixth coordination site is possibly vacant. These structural characteristics are quite similar to those of horseradish peroxidase (HRP), suggesting that these may be prerequisite to peroxidase activity. The pH dependences of the spectra of LP in cyanide and azide forms showed the presence of two ionizable groups with pK values of 6 and 7.4 in the heme vicinity, which is consistent with the kinetic results. The group with pK = 7.4 is associated with azide binding to LP in a slow NMR exchange limit, which is in contrast to the fast entry of azide to HRP.     

Anticooperative ligand binding properties of recombinant ferric Vitreoscilla homodimeric hemoglobin: a thermodynamic, kinetic and X-ray crystallographic study.

Thermodynamics and kinetics for cyanide, azide, thiocyanate and imidazole binding to recombinant ferric Vitreoscilla sp. homodimeric hemoglobin (Vitreoscilla Hb) have been determined at pH 6.4 and 7.0, and 20.0 degrees C, in solution and in the crystalline state. Moreover, the three-dimensional structures of the diligated thiocyanate and imidazole derivatives of recombinant ferric Vitreoscilla Hb have been determined by X-ray crystallography at 1.8 A (Rfactor=19.9%) and 2.1 A (Rfactor=23.8%) resolution, respectively. Ferric Vitreoscilla Hb displays an anticooperative ligand binding behaviour in solution. This very unusual feature can only be accounted for by assuming ligand-linked conformational changes in the monoligated species, which lead to the observed 300-fold decrease in the affinity of cyanide, azide, thiocyanate and imidazole for the monoligated ferric Vitreoscilla Hb with respect to that of the fully unligated homodimer. In the crystalline state, thermodynamics for azide and imidazole binding to ferric Vitreoscilla Hb may be described as a simple process with an overall ligand affinity for the homodimer corresponding to that for diligation in solution. These data suggest that the ligand-free homodimer, observed in the crystalline state, is constrained in a low affinity conformation whose ligand binding properties closely resemble those of the monoligated species in solution. From the kinetic viewpoint, anticooperativity is reflected by the 300-fold decrease of the second-order rate constant for cyanide and imidazole binding to the monoligated ferric Vitreoscilla Hb with respect to that for ligand association to the ligand-free homodimer in solution. On the other hand, values of the first-order rate constant for cyanide and imidazole dissociation from the diligated and monoligated derivatives of ferric Vitreoscilla Hb in solution are closely similar. As a whole, ligand binding and structural properties of ferric Vitreoscilla Hb appear to be unique among all Hbs investigated to date.     

Oligomerization and ligand binding in a homotetrameric hemoglobin: two high-resolution crystal structures of hemoglobin Bart's (gamma(4)), a marker for alpha-thalassemia

Hemoglobin (Hb) Bart's is present in the red blood cells of millions of people worldwide who suffer from alpha-thalassemia. alpha-Thalassemia is a disease in which there is a deletion of one or more of the four alpha-chain genes, and excess gamma and beta chains spontaneously form homotetramers. The gamma(4) homotetrameric protein known as Hb Bart's is a stable species that exhibits neither a Bohr effect nor heme-heme cooperativity. Although Hb Bart's has a higher O(2) affinity than either adult (alpha(2)beta(2)) or fetal (alpha(2)gamma(2)) Hbs, it has a lower affinity for O(2) than HbH (beta(4)). To better understand the association and ligand binding properties of the gamma(4) tetramer, we have solved the structure of Hb Bart's in two different oxidation and ligation states. The crystal structure of ferrous carbonmonoxy (CO) Hb Bart's was determined by molecular replacement and refined at 1.7 A resolution (R = 21.1%, R(free) = 24.4%), and that of ferric azide (N(3)(-)) Hb Bart's was similarly determined at 1.86 A resolution (R = 18.4%, R(free) = 22.0%). In the carbonmonoxy-Hb structure, the CO ligand is bound at an angle of 140 degrees, and with an unusually long Fe-C bond of 2.25 A. This geometry is attributed to repulsion from the distal His63 at the low pH of crystallization (4.5). In contrast, azide is bound to the oxidized heme iron in the methemoglobin crystals at an angle of 112 degrees, in a perfect orientation to accept a hydrogen bond from His63. Compared to the three known quaternary structures of human Hb (T, R, and R2), both structures most closely resemble the R state. Comparisons with the structures of adult Hb and HbH explain the association and dissociation behaviour of Hb homotetramers relative to the heterotetrameric Hbs.