Effects of substitutions of lysine and aspartic acid for asparagine at beta 108 and of tryptophan for valine at alpha 96 on the structural and functional properties of human normal adult hemoglobin: roles of alpha 1 beta 1 and alpha 1 beta 2 subunit interfaces in the cooperative oxygenation process.

Using our Escherichia coli expression system, we have produced five mutant recombinant (r) hemoglobins (Hbs): r Hb (alpha V96 W), r Hb Presbyterian (beta N108K), r Hb Yoshizuka (beta N108D), r Hb (alpha V96W, beta N108K), and r Hb (alpha V96W, beta N108D). These r Hbs allow us to investigate the effect on the structure-function relationship of Hb of replacing beta 108Asn by either a positively charged Lys or a negatively charged Asp as well as the effect of replacing alpha 96Val by a bulky, nonpolar Trp. We have conducted oxygen-binding studies to investigate the effect of several allosteric effectors on the oxygenation properties and the Bohr effects of these r Hbs. The oxygen affinity of these mutants is lower than that of human normal adult hemoglobin (Hb A) under various experimental conditions. The oxygen affinity of r Hb Yoshizuka is insensitive to changes in chloride concentration, whereas the oxygen affinity of r Hb Presbyterian exhibits a pronounced chloride effect. r Hb Presbyterian has the largest Bohr effect, followed by Hb A, r Hb (alpha V96W), and r Hb Yoshizuka. Thus, the amino acid substitution in the central cavity that increases the net positive charge enhances the Bohr effect. Proton nuclear magnetic resonance studies demonstrate that these r Hbs can switch from the R quaternary structure to the T quaternary structure without changing their ligation states upon the addition of an allosteric effector, inositol hexaphosphate, and/or by reducing the temperature. r Hb (alpha V96W, beta N108K), which has the lowest oxygen affinity among the hemoglobins studied, has the greatest tendency to switch to the T quaternary structure. The following conclusions can be derived from our results: First, if we can stabilize the deoxy (T) quaternary structure of a hemoglobin molecule without perturbing its oxy (R) quaternary structure, we will have a hemoglobin with low oxygen affinity and high cooperativity. Second, an alteration of the charge distribution by amino acid substitutions in the alpha 1 beta 1 subunit interface and in the central cavity of the hemoglobin molecule can influence the Bohr effect. Third, an amino acid substitution in the alpha 1 beta 1 subunit interface can affect both the oxygen affinity and cooperativity of the oxygenation process. There is communication between the alpha 1 beta 1 and alpha 1 beta 2 subunit interfaces during the oxygenation process. Fourth, there is considerable cooperativity in the oxygenation process in the T-state of the hemoglobin molecule.     

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.     

Analysis of proton release in oxygen binding by hemoglobin: implications for the cooperative mechanism

The relationship in hemoglobin between cooperativity (dependence of the Hill constant on pH0 and the Bohr effect (dependence of the mean oxygen affinity on pH) can be described by a statistical thermodynamic model [Szabo, A., & Karplus, M. (1972) J. Mol. Biol. 72, 163-197; Lee, A., & Karplus, M. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 7055-759]. In this model, salt bridges and other interactions serve to couple tertiary and quaternary structural changes. To test and refine the model, it is applied to the analysis of the pH dependence of the tetramer Adair constants corrected for statistical factors (K4i', i = 1-4). Attention is focused on the proton release of the first (delta H1+ = alpha log K41'/alpha pH) and last (delta H4+ = alpha log K44'/alpha pH) oxygenation steps, where K4i' are the Adair constants corrected for statistical factors. Measurements of delta H1+ and delta H4+ under carefully controlled conditions are reported, and good agreement between the model calculation and these experimental results is obtained. The salt bridges are found to be partially coupled to the ligation state in the deoxy quaternary structure; it is shown that a Monod-Wyman-Changeux-type model, in which the salt bridges are coupled only to quaternary structural change, is inconsistent with the data for delta H1. The significance of the present analysis for an evaluation of the Perutz mechanism [Perutz, M.F. (1970) Nature (London) 228, 726-734, 734-739] and other models for hemoglobin cooperativity is discussed.     

Recombinant hemoglobins with low oxygen affinity and high cooperativity

By introducing an additional H-bond in the alpha(1)beta(2) subunit interface or altering the charge properties of the amino acid residues in the alpha(1)beta(1) subunit interface of the hemoglobin molecule, we have designed and expressed recombinant hemoglobins (rHbs) with low oxygen affinity and high cooperativity. Oxygen-binding measurements of these rHbs under various experimental conditions show interesting properties in response to pH (Bohr effect) and allosteric effectors. Proton nuclear magnetic resonance studies show that these rHbs can switch from the oxy (or CO) quaternary structure (R) to the deoxy quaternary structure (T) without changing their ligation states upon addition of an allosteric effector, inositol hexaphosphate, and/or reduction of the ambient temperature. These results indicate that if we can provide extra stability to the T state of the hemoglobin molecule without perturbing its R state, we can produce hemoglobins with low oxygen affinity and high cooperativity. Some of these rHbs are also quite stable against autoxidation compared to many of the known abnormal hemoglobins with altered oxygen affinity and cooperativity. These results have provided new insights into the structure-function relationship in hemoglobin.     

Allosteric effectors do not alter the oxygen affinity of hemoglobin crystals.

In solution, the oxygen affinity of hemoglobin in the T quaternary structure is decreased in the presence of allosteric effectors such as protons and organic phosphates. To explain these effects, as well as the absence of the Bohr effect and the lower oxygen affinity of T-state hemoglobin in the crystal compared to solution, Rivetti C et al. (1993a, Biochemistry 32:2888-2906) suggested that there are high- and low-affinity subunit conformations of T, associated with broken and unbroken intersubunit salt bridges. In this model, the crystal of T-state hemoglobin has the lowest possible oxygen affinity because the salt bridges remain intact upon oxygenation. Binding of allosteric effectors in the crystal should therefore not influence the oxygen affinity. To test this hypothesis, we used polarized absorption spectroscopy to measure oxygen binding curves of single crystals of hemoglobin in the T quaternary structure in the presence of the "strong" allosteric effectors, inositol hexaphosphate and bezafibrate. In solution, these effectors reduce the oxygen affinity of the T state by 10-30-fold. We find no change in affinity (< 10%) of the crystal. The crystal binding curve, moreover, is noncooperative, which is consistent with the essential feature of the two-state allosteric model of Monod J, Wyman J, and Changeux JP (1965, J Mol Biol 12:88-118) that cooperative binding requires a change in quaternary structure. Noncooperative binding by the crystal is not caused by cooperative interactions being masked by fortuitous compensation from a difference in the affinity of the alpha and beta subunits. This was shown by calculating the separate alpha and beta subunit binding curves from the two sets of polarized optical spectra using geometric factors from the X-ray structures of deoxygenated and fully oxygenated T-state molecules determined by Paoli M et al. (1996, J Mol Biol 256:775-792).     

Cooperative oxygen binding, subunit assembly, and sulfhydryl reaction kinetics of the eight cyanomet intermediate ligation states of human hemoglobin.

Correlations between the energetics of cooperativity and quaternary structural probes have recently been made for the intermediate ligation states of Hb [Daugherty et al. (1991) Proc. Natl. Acad. Sci. US 88, 1110-1114]. This has led to a "molecular code" which translates configurations of the 10 ligation states into switch points of quaternary transition according to a "symmetry rule"; T-->R quaternary structure change is governed by the presence of at least one heme-site ligand on each of the alpha beta dimeric half-molecules within the tetramer [see Ackers et al. (1992) Science 255, 54-63, for summary]. In order to further explore this and other features of the cooperative mechanism, we have used oxygen binding to probe the energetics and cooperativities for the vacant sites of the cyanomet ligation species. We have also probed structural aspects of all eight cyanomet ligation intermediates by means of sulfhydryl reaction kinetics. Our oxygen binding results, obtained from a combination of direct and indirect methods, demonstrate the same combinatorial aspect to cooperativity that is predicted by the symmetry rule. Overall oxygen affinities of the two singly-ligated species (alpha +CN beta)(alpha beta) and (alpha beta +CN)(alpha beta) were found to be identical (pmedian = 2.4 Torr). In contrast, the doubly-ligated species exhibited two distinct patterns of oxygen equilibria: the asymmetric species (alpha +CN beta +CN)(alpha beta) showed very high cooperativity (nmax = 1.94) and low affinity (pmedian = 6.0 Torr), while the other three doubly-ligated species showed diminished cooperativity (nmax = 1.23) and considerably higher oxygen affinity (pmedian = 0.4 Torr). Extremely high oxygen affinities were found for the triply-ligated species (alpha +CN beta +CN)(alpha beta +CN) and (alpha +CN beta +CN)(alpha +CN beta) (pmedian = 0.2 Torr). Their oxygen binding free energies are considerably more favorable than those of the alpha and beta subunits within the dissociated alpha beta dimer, demonstrating directly the quaternary enhancement effect, i.e., enhanced oxygen affinity at the last binding step of tetramer relative to the dissociated protomers. Oxygen binding free energies measured for the alpha subunit within the isolated (alpha beta +CN) dimer and for the beta subunit within the isolated (alpha +CN beta) dimer sum to the free energy for binding two oxygens to normal hemoglobin dimers (-16.3 +/- 0.2 versus -16.7 +/- 0.2, respectively), arguing against cooperativity in the isolated dimer. Correlations were established between cooperative free energies of the 10 cyanomet ligation microstates and the kinetics for reacting their free sulfhydryl groups.(ABSTRACT TRUNCATED AT 400 WORDS)     

A survey of hemoglobin quaternary structures

We perform an analysis of the quaternary structure and dimer/dimer interface in the crystal structures of 165 human hemoglobin tetramers; 112 are in the T, 17 the R, 14 the Y (or R2) state; 11 are high-affinity T state mutants, and 11 may either be intermediates between the states, or off the allosteric transition pathway. The tertiary structure is fixed within each state, in spite of the different ligands, mutations, and chemical modifications present in individual entries. The geometry of the tetramer assembly is essentially the same in all the R or the Y state entries; it is slightly different in high salt and low salt crystals of T state hemoglobins. The dimer/dimer interface differs in terms of size, chemical composition and polar interactions, between the states. It is loosely packed, like crystal packing contacts or the subunit interface of weakly associated homodimers, and unlike most oligomeric proteins, which have close-packed interfaces. The loose packing is most obvious in the liganded forms, where the tetramer is known to dissociate at low concentration. We identify cavities that contribute to the loose packing of the α1β2 and α2β1 contacts. Two pairs of cavities occur recurrently in both the T and the R state tetramers. They may contribute to the allosteric mechanism by facilitating the subunit movements and the tertiary structure changes that accompany the transition from T to R to Y.     

Conformational changes in hemoglobin S (betaE6V) imposed by mutation of the beta Glu7-beta Lys132 salt bridge and detected by UV resonance Raman spectroscopy

The impact upon molecular structure of an additional point mutation adjacent to the existing E6V mutation in sickle cell hemoglobin was probed spectroscopically. The UV resonance Raman results show that the conformational consequences of mutating the salt bridge pair, betaGlu(7)-betaLys(132), are dependent on which residue of the pair is modified. The betaK132A mutants exhibit the spectroscopic signatures of the R --> T state transition in both the "hinge" and "switch" regions of the alpha(1)beta(2) interface. Both singly and doubly mutated hemoglobin (Hb) betaepsilon7Alpha exhibit the switch region signature for the R --> T quaternary state transition but not the hinge signature. The absence of this hinge region-associated quaternary change is the likely origin of the observed increased oxygen binding affinity for the Hb betaepsilon7Alpha mutants. The observed large decrease in the W3 alpha14beta15 band intensity for doubly mutated Hb betaepsilon7Alpha is attributed to an enhanced separation in the A helix-E helix tertiary contact of the beta subunits. The results for the Hb A betaGlu(7)-betaLys(132) salt bridge mutants demonstrate that attaining the T state conformation at the hinge region of the alpha(1)beta(2) dimer interface can be achieved through different intraglobin pathways; these pathways are subject to subtle mutagenic manipulation at sites well removed from the dimer interface.     

The influence of organic phosphates on the Bohr effect of human hemoglobin valency hybrids.

The Bohr effect of hemoglobin and that of the aquomet and cyanomet valency hybrids was measured in the presence and the absence of IHP (inositol hexaphosphate) and DPG (2,3-diphosphoglycerate). In the absence of these organic phosphates the four hybrids show similar, but suppressed Bohr effects as compared to hemoglobin. Addition of IHP and DPG results in all cases in an increase of the Bohr effect. The additional phosphate induced Bohr effect of the hybrids with the alpha chain in the oxidized form is almost identical to that of hemoglobin, while this effect of the hybrids with oxidized beta chains is slighly lower than that of hemoglobin. The results suggest (a) that the Bohr effect is correlated to the ligation state of the hemoglobin molecule rather than to its quaternary structure (b) that the additional phosphate induced Bohr effect is related to the change in quaternary structure of the tetramer, and (c) that with respect to the Bohr effect of the hybrids there is no difference between high and low spin species.     

High pressure NMR studies of hemoproteins. The effect of pressure on the tertiary and quaternary structures of human adult ferrous hemoglobin

The effect of pressure on the tertiary and quaternary structures of human oxy, carbonmonoxy, and deoxyhemoglobin was examined by high pressure NMR spectroscopy at 300 MHz. The increased pressure displaced the ring current-shifted gamma 1-methyl resonance of beta E11 valine for oxy- and carbonmonoxyhemoglobin to the upfield side, whereas that of the alpha subunit was insensitive to pressure. Such a preferential pressure-induced upfield shift for the beta E11 valine gamma 1-methyl signal was also encountered for the isolated carbonmonoxy beta chain. For deoxyhemoglobin, hyperfine shifted resonances of the heme peripheral proton groups and the proximal histidyl NH proton for the beta subunit were pressure-dependent, in contrast to the pressure-insensitive responses for these resonances of the alpha subunit. These results indicate the structural nonequivalence of the pressure-induced structural changes in the alpha and beta subunits of hemoglobin. 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 not changed upon pressurization. From all of above results, it was concluded that pressure induces the tertiary structural change preferentially at the beta heme pocket of the ferrous hemoglobin derivatives with the quaternary structure retained.     

Proton magnetic resonance study of the influence of chemical modification, mutation, quaternary state, and ligation state on dynamic stability of the heme pocket in hemoglobin as reflected in the exchange of the proximal histidyl ring labile proton

Proton nuclear magnetic resonance spectroscopy has been utilized to investigate the rates of exchange with deuterium of the proximal histidyl ring protons in a series of chemically modified and mutated forms of Hb A. Differences in rates of exchange are related to differences in the stability of the deformed or partially unfolded intermediates from which exchange with bulk solvent takes place. Each modified/mutated Hb exhibited kinetic subunit heterogeneity in the reduced ferrous state, with the alpha subunit exhibiting faster exchange than the beta subunit. Modification or mutation resulted in significant increases in the His F8 ring NH exchange rates primarily for the affected subunit and only if the modification/mutation occurs at the allosterically important alpha 1 beta 2 subunit interface. Moreover, this enhancement in exchange rate is observed primarily in that quaternary state of the modified/mutated Hb in which the modified/substituted residue makes the intersubunit contact. This confirms the importance of allosteric constraints in determining the dynamic properties of the heme pocket. Using modified or mutated Hbs that can switch between the alternate quaternary states within a given ligation state or ligate within a given quaternary state, we show that the major portion of the enhanced exchange rate in R-state oxy Hb relative to T-state deoxy Hb originates from the quaternary switch rather than from ligation. However, solely ligation effects are not negligible. The exchange rates of the His F8 ring labile protons increase dramatically upon oxidizing the iron to the ferric state, and both the subunit kinetic heterogeneity and the allosteric sensitivity to the quaternary state are essentially abolished.(ABSTRACT TRUNCATED AT 250 WORDS)     

X-ray diffraction studies of a partially liganded hemoglobin, [alpha(FeII-CO)beta(MnII)]2

We have applied single-crystal X-ray diffraction methods to analyze the structure of [alpha(FeII-CO)beta(MnII)]2, a mixed-metal hybrid hemoglobin that crystallizes in the deoxyhemoglobin quaternary structure (the T-state) even though it is half liganded. This study, carried out at a resolution of 3.0 A, shows that (1) the Mn(II)-substituted beta subunits are structurally isomorphous with normal deoxy beta subunits, and (2) CO binding to the alpha subunits induces small, localized changes in the T-state that lack the main directional component of the corresponding larger structural changes in subunit tertiary structure that accompany complete ligand binding to all four subunits and the deoxy to oxy quaternary structure change. Specifically, in the T-state, CO binding to the alpha heme group draws the iron atom toward the heme plane, and this in turn pulls the last turn of the F helix (residues 85 through 89) closer to the heme group. The direction of these small movements is almost perpendicular to the axis of the F helix. In contrast, when the structures of fully liganded and deoxyhemoglobin are compared, extensive structural changes occur throughout the F helix and FG corner, and the main component of the atomic movements in the F helix (in addition to the smaller component toward the heme) is in a direction parallel to the heme plane and toward the alpha 1 beta 2 interface. These findings are discussed in terms of the current stereochemical theories of co-operative ligand binding and the Bohr effect.     

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.     

Ligand-dependent Bohr effect of Chrionomus hemoglobins.

The O2 and CO Bohr effects of monomeric and dimeric hemoglobins of the insect Chironomus thummi thummi were determined as proton releases upon ligation. For the O2 Bohr effect of the monomeric hemoglobin III a maximum value of 0.20 H+/heme was obtained at pH 7.5. Upon ligation with CO, however, only 0.04 H+/heme were released at the same pH. In agreement with this finding isoelectric focusing experiments revealed different isoelectric points for O2-liganded and CO-liganded states of hemoglobin III. Analogous results were obtained in the cases of the monomeric hemoglobin IV and the dimeric hemoglobins of Chironomus thummi thummi; here O2 Bohr effects of 0.43 and 0.86 H+/heme were observed. For the corresponding CO Bohr effects values of 0.08 and 0.31 H+/heme were obtained respectively. On the basis of the available structural data the reduced CO Bohr effect in hemoglobin III is discussed as arising from a steric hindrance of the CO ligand by the side chain of isoleucine-E11, obstructing the movement of the heme-iron upon reaction with carbon monoxide. It should, however, be noted that ligands, according to their different electron donor and acceptor properties, may generally induce different conformational changes and thus different Bohr effects, in those hemoglobins in which distinct tertiary and/or quaternary constraints have not evolved. The general utilization of CO instead of O2 as allosteric effector is ruled out by the results reported here.     

Refined crystal structure of lipoamide dehydrogenase from Azotobacter vinelandii at 2.2 A resolution. A comparison with the structure of glutathione reductase

The structure of lipoamide dehydrogenase from Azotobacter vinelandii has been refined by the molecular dynamics technique to an R-factor of 19.8% at 2.2 A resolution. In the final model, the root-mean-square deviation from ideality is 0.02 A for bond lengths and 3.2 degrees for bond angles. The asymmetric unit comprises two subunits, each consisting of 466 amino acid residues and the prosthetic group FAD, plus 512 solvent molecules. The last ten amino acid residues of both chains are not visible in the electron density distribution and they are probably disordered. The operation required to superimpose the two chains forming the dimer is a rotation of exactly 180 degrees with no translation component. The final model shows the two independently refined subunits to be very similar, except for six loops located at the surface of the molecule. The structure of each subunit of the enzyme consists of four domains with the catalytic centre located at the subunit interface. The reactive disulphide bridge, 48-53, is oxidized with S gamma of Cys53 located 3.5 A away from carbon C-4a of the isoalloxazine ring. The side-chain of His450' points its N epsilon 2 towards S gamma of Cys48 and is hydrogen bonded to the carboxylate of Glu455'. The FAD is bound in an extended conformation and the isoalloxazine ring is not completely planar with an angle between the pteridine and the benzene ring of 7.3 degrees in the first subunit and of 12.1 degrees in the second one. The overall folding of lipoamide dehydrogenase is very similar to that of glutathione reductase. However, a comparison of the two enzymes, which have only 26% sequence identity, reveals significant conformational differences. These concern the tertiary as well as the quaternary structure of the two molecules. In each subunit of lipoamide dehydrogenase the NAD-binding domain and the interface domain appear to be differently oriented with respect to the FAD-binding domain by 7.1 degrees and 7.8 degrees, respectively. The interface domain contains, in addition, major changes in tertiary structure. Furthermore, the two subunits forming the dimer appear to be shifted with respect to each other by more than 4 A, when the lipoamide dehydrogenase dimer is compared with that of glutathione reductase. In spite of all these changes at the tertiary and quaternary level the active sites of the enzymes, which occur at the dimer interface, appear to be remarkably similar.(ABSTRACT TRUNCATED AT 400 WORDS)     

High-resolution X-ray study of deoxyhemoglobin Rothschild 37 beta Trp----Arg: a mutation that creates an intersubunit chloride-binding site.

The mutation site in hemoglobin Rothschild (37 beta Trp----Arg) is located in the "hinge region" of the alpha 1 beta 2 interface, a region that is critical for normal hemoglobin function. The mutation results in greatly reduced cooperativity and an oxygen affinity similar to that of hemoglobin A [Gacon, G., Belkhodja, O., Wajcman, H., & Labie, D. (1977) FEBS Lett. 82, 243-246]. Crystal were grown under "low-salt" conditions [100 mM Cl- in 10 mM phosphate buffer at pH 7.0 with poly(ethylene glycol) as a precipitating agent]. The crystal structure of deoxyhemoglobin Rothschild and the isomorphous crystal structure of deoxyhemoglobin A were refined at resolutions of 2.0 and 1.9 A, respectively. The mutation-induced structural changes were partitioned into components of (1) tetramer rotation, (2) quaternary structure rearrangement, and (3) deformations of tertiary structure. The quaternary change involves a 1 degree rotation of the alpha subunit about the "switch region" of the alpha 1 beta 2 interface. The tertiary changes are confined to residues at the alpha 1 beta 2 interface, with the largest shifts (approximately 0.4 A) located across the interface from the mutation site at the alpha subunit FG corner-G helix boundary. Most surprising was the identification of a mutation-generated anion-binding site in the alpha 1 beta 2 interface. Chloride binds at this site as a counterion for Arg 37 beta. The requirement of a counterion implies that the solution properties of hemoglobin Rothschild, in particular the dimer-tetramer equilibrium, should be very dependent upon the concentration and type of anions present.     

Mutual effects of proton and sodium chloride on oxygenation of liganded human hemoglobin

The different effects of pH and NaCl on individual O2-binding properties of alpha and beta subunits within liganded tetramer and dimer of human hemoglobin (HbA) were examined in a number of laser time-resolved spectroscopic measurements. A previously proposed approach [Dzhagarov BM & Lepeshkevich SV (2004) Chem Phys Lett390, 59-64] was used to determine the extent of subunit dissociation rate constant difference and subunit affinity difference from a single flash photolysis experiment. To investigate the effect of NaCl concentration on the association and dissociation rate constants we carried out a series of experiments at four different concentrations (0.1, 0.5, 1.0 and 2.0 m NaCl) over the pH range of the alkaline Bohr effect. As the data suggest, the individual properties of the alpha and beta subunits within the completely liganded tetrameric hemoglobin did not depend on pH under salt-free conditions. However, different effects NaCl on the individual kinetic properties of the alpha and beta subunits were revealed. Regulation of the O2-binding properties of the alpha and beta subunits within the liganded tetramer is proposed to be attained in two quite different ways.     

The crystal structure of bar-headed goose hemoglobin in deoxy form: the allosteric mechanism of a hemoglobin species with high oxygen affinity

The crystal structure of a high oxygen affinity species of hemoglobin, bar-headed goose hemoglobin in deoxy form, has been determined to a resolution of 2.8 A. The R and R(free) factor of the model are 0.197 and 0.243, respectively. The structure reported here is a special deoxy state of hemoglobin and indicates the differences in allosteric mechanisms between the goose and human hemoglobins. The quaternary structure of the goose deoxy hemoglobin shows obvious differences from that of human deoxy hemoglobin. The rotation angle of one alphabeta dimer relative to its partner in a tetramer molecule from the goose oxy to deoxy hemoglobin is only 4.6 degrees, and the translation is only 0.3 A, which are much smaller than those in human hemoglobin. In the alpha(1)beta(2) switch region of the goose deoxy hemoglobin, the imidazole ring of His beta(2)97 does not span the side-chain of Thr alpha(1)41 relative to the oxy hemoglobin as in human hemoglobin. And the tertiary structure changes of heme pocket and FG corner are also smaller than that in human hemoglobin. A unique mutation among avian and mammalian Hbs of alpha119 from proline to alanine at the alpha(1)beta(1 )interface in bar-headed goose hemoglobin brings a gap between Ala alpha119 and Leu beta55, the minimum distance between the two residues is 4.66 A. At the entrance to the central cavity around the molecular dyad, some residues of two beta chains form a positively charged groove where the inositol pentaphosphate binds to the hemoglobin. The His beta146 is at the inositol pentaphosphate binding site and the salt-bridge between His beta146 and Asp beta94 does not exist in the deoxy hemoglobin, which brings the weak chloride-independent Bohr effect to bar-headed goose hemoglobin.     

Role of Bohr group salt bridges in cooperativity in hemoglobin.

Possible problems in measuring the first Adair constant, K1, from accurate oxygen equilibrium curves have been investigated. Of these only the presence of small amounts of CO-hemoglobin or hemoglobin dimers had a significant effect. The former can be eliminated by treatment with oxygen, the latter by measuring the concentration-dependence of K1 or working at high protein concentrations. K1 values have been measured for normal hemoglobin at pH 7 and 9, hemoglobin specifically reacted with cyanate at Val 1alpha (alphac2beta2) and des(His 146beta) hemoglobin at pH 7. K1 is equal to KT, the oxygen affinity of the T state of hemoglobin, for all these hemoglobins and was increased in all of them when compared to normal hemoglobin at pH 7. This shows that the breakage of the Bohr group salt bridges by increasing pH or specific modification changes KT. Hence the Bohr group salt bridges break on ligation of the T state and are partially responsible for the free energy of cooperativity.