Inhibition of beta(S)-chain dependent polymerization by synergistic complementation of contact site perturbations of alpha-chain: application of semisynthetic chimeric alpha-chains

Mouse alpha(1-30)-horse alpha(31-141) chimeric alpha-chain, a semisynthetic super-inhibitory alpha-chain, inhibits beta(S)-chain dependent polymerization better than both parent alpha-chains. Although contact site sequence differences are absent in the alpha(1-30) region of the chimeric chain, the four sequence differences of the region alpha(17-22) could induce perturbations of the side chains at alpha(16), alpha(20) and alpha(23), the three contact sites of the region. A synergistic complementation of such contact site perturbation with that of horse alpha(31-141) probably results in the super-inhibitory activity of the chimeric alpha-chain. The inhibitory contact site sequence differences, by themselves, could also exhibit similar synergistic complementation. Accordingly, the polymerization inhibitory activity of Hb Le-Lamentin (LM) mutation [His20(alpha)-->Gln], a contact site sequence difference, engineered into human-horse chimeric alpha-chain has been investigated to map such a synergistic complementation. Gln20(alpha) has little effect on the O(2) affinity of HbS, but in human-horse chimeric alpha-chain it reduces the O(2) affinity slightly. In the chimeric alpha-chain, Gln20(alpha) increased sensitivity of the betabeta cleft for the DPG influence, reflecting a cross-talk between the alpha(1)beta(1) interface and betabeta cleft in this semisynthetic chimeric HbS. In the human alpha-chain frame, the polymerization inhibitory activity of Gln20(alpha) is higher compared with horse alpha(1-30), but lower than mouse alpha(1-30). Gln20(alpha) synergistically complements the inhibitory propensity of horse alpha(31-141). However, the inhibitory activity of LM-horse chimeric alpha-chain is still lower than that of mouse-horse chimeric alpha-chain. Therefore, perturbation of multiple contact sites in the alpha(1-30) region of the mouse-horse chimeric alpha-chain and its linkage with the inhibitory propensity of horse alpha(31-141) has been now invoked to explain the super-inhibitory activity of the chimeric alpha-chain. The 'linkage-map' of contact sites can serve as a blueprint for designing synergistic complementation of multiple contact sites into alpha-chains as a strategy for generating super-inhibitory antisickling hemoglobins for gene therapy of sickle cell disease.     

Ligand binding kinetic studies on the hybrid hemoglobin alpha (human):beta (carp): a hemoglobin with mixed conformations and sequential conformational changes

Oxygen and CO ligand binding kinetics have been studied for the hybrid hemoglobin (Hb) alpha (human):beta (carp), hybrid II. Valency and half-saturated hybrids were used to aid in the assignment of the conformations of both chains. In hybrid II, an intermediate S state occurs, in which one chain has R- and the other T-state properties. In HbCO at pH 6 (plus 1 mM inositol hexaphosphate), the human alpha-chain is R state and the carp beta-chain is T state. We have no evidence at this pH that the carp beta-chain ever assumes the R conformation. At pH 6, the human alpha-chain shows human Hb R-state kinetics at low fractional photolysis and T-state rates for CO ligation by stopped flow. At pH 7, the human-chain R-state rate slows toward a carp hemoglobin rate. The carp beta-chains, on the other hand, react 50% more rapidly in the liganded conformation than in carp hemoglobin, and while the human alpha-chains are in the R state, the two beta-chains appear to function as a cooperative dimer. In this hemoglobin, the chains appear to be somewhat decoupled near pH 7, allowing a sequential conformational change from the R state in which the beta-chains first assume T-state properties, followed by the alpha-chains. The rate of the R-T conformational change for the carp beta-chains is at least 300 times greater than that for the human alpha-chains. At pH 9, the R----T conformational transition rate is at least 200 times slower than that for human hemoglobin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Contact inhibition within hemoglobin S polymer by thiol reagents

N-Ethylmaleimide, a thiol reagent, increases the solubility of deoxyhemoglobin S. We investigated which of the two reacted beta 93 cysteine residues of the Hb tetramer was responsible for the inhibition of Hb S polymerization. Accordingly we compared the solubility of equal mixtures of HbA + HbS, HbA NEM + HbS and HbA + HbS NEM. Upon deoxygenation these mixtures contain about 50% a stable and asymmetrical hybrid alpha 2A beta A beta S, alpha 2A beta A,NEM beta S or alpha 2A beta A beta S,NEM respectively and 25% parental molecules as confirmed by ion-exchange HPLC performed in anaerobic conditions. Within the hybrid molecule, beta A or beta A,NEM chain has to be present in the alpha beta dimer located in trans to the dimer which contains the only beta 6 valine residue participating in intermolecular contacts (dimer in cis), while beta S or beta S,NEM must be in cis position in the hybrid molecule. The solubility of mixtures increases 4% for HbA NEM + HbS and 20% for HbA + HbS NEM mixtures compared to HbA + HbS mixture, indicating that the inhibitory effect of N-ethylmaleimide is more effective in cis than in trans position. The absence of a major role played by N-ethylmaleimide located in trans was supported by the solubility study of a mixture of HbS + Hb Créteil beta 89 Ser----Asn. The beta 89 residue in trans next to the cysteine beta 93 modified the T structure similarly to N-ethylmaleimide, and did not affect intermolecular contacts. Crystallographic studies of molecular contacts within deoxyHbS crystals suggest that the cis inhibitory effect of N-ethylmaleimide can be explained by direct inhibition of 'external' contacts between double strands involving the CD corner of the alpha chains.     

Polymerization and solubility of Ni(II)-Fe(II) hybrid Hb S

Polymerization of half-liganded Hb S was investigated using Ni(II)-Fe(II) hybrid Hb S, in which heme in either alpha or beta s subunits is replaced by Ni (II) protoporphyrin IX. Studies on the polymerization of these hybrid hemoglobins were carried out under aerobic conditions. Both alpha 2 (Ni) beta 2s (Fe-CO) and alpha 2 (Fe-CO) beta 2s (Ni) polymerized with a distinct delay time as do native deoxy-Hb S and Ni(II) Hb S. However, the critical concentration for polymerization of half-liganded Hb S, alpha 2 (Ni) beta 2s (Fe-CO) and alpha 2 (Fe-CO) beta 2s (Ni), was 4- and 8-times higher, respectively, than that of Ni(II)-Hb S. Kinetics of polymerization of both deoxygenated hybrid hemoglobins with CO completely removed were the same, although the critical concentrations for polymerization were intermediate between those for deoxy-Hb S and Ni(II)-Hb S. These results suggest that the small tertiary conformational change associated with the doubly liganded state may be much less favorable to polymerization than the completely unliganded state of Hb S. The conformational change depends on whether alpha or beta chain is liganded. The ease of polymerization and low solubility of sickle hemoglobin is dependent not only on quaternary, but on tertiary structural changes, as well as on the substitution of Val for Glu at the beta 6 position.     

Chimeric hemoglobins--hybrids of human and swine hemoglobin: assembly and stability of interspecies hybrids.

Transgenic swine expressing human HbA contained only one of two types of the anticipated interspecies hybrids, namely H alpha 2 P beta 2 (H = human, P = swine). In an attempt to establish whether the absence of the swine alpha and human beta (P alpha 2 H beta 2) hybrid in vivo is a reflection of the lack of complementarity between the interspecies chains to generate appropriate interfaces, we have undertaken the in vitro assembly of swine alpha and human beta chimeric tetramer. In contrast to the in vivo transgenic swine system, in vitro the hybrid of swine alpha human beta chain is assembled readily and the hybrid exhibits normal cooperative oxygen binding. Both the swine alpha human beta and the human alpha swine beta interspecies hybrids are stable around neutral pH and do not segregate into parent tetramers even when mixed together. On the other hand, nearly complete exchange of P alpha chain of P alpha 2 H beta 2 hybrid occurs in the presence of H alpha chain at pH 6.0 and room temperature, resulting in the formation of HbA. However, very little of such an exchange reaction takes place at pH 7.0. These results suggest that the thermodynamic stability of P alpha 2 H beta 2 hybrid is lower compared to that of HbA. In contrast, P beta chain of H alpha 2 P beta 2 hybrid is refractory to exchange with H beta chain at pH 7.0 as well as at pH 6.0, suggesting that the stability of H alpha 2 P beta 2 is higher compared to that of HbA (H alpha 2 H beta 2). The swine alpha human beta chimeric Hb undergoes subunit exchange reaction with human alpha-chain in the presence of 0.9 M MgCl2, at pH 7.0. This demonstrates the lower thermodynamic stability of the intradimeric interactions of the heterodimer even at neutral pH. A synergistic coupling of the intra- and interdimeric interactions of the swine alpha and human beta chain heterodimer is essential for the thermodynamic stability of the chimeric Hb under the physiological conditions. Accordingly, we speculate that the lower thermodynamic stability of P alpha H beta heterodimer (compared to the homodimers H alpha H beta and P alpha P beta) facilitates its segregation into the homodimers by subunit exchange reaction involving either H alpha or P beta. This molecular aspect by itself or possibly along with other cellular aspects of the swine system results in the absence of P alpha 2 H beta 2 hybrid in transgenic swine expressing HbA.     

Carnivora: the primary structure of the alpha-chains of ferret (Mustela putorius furo, Mustelidae) hemoglobins

Ferret erythrocytes contain two hemoglobins differing only by their alpha-chains. The primary structure of the common beta-chain has been previously described; the complete sequence of the two alpha-chains are reported in this paper. The globin chains were separated by ion-exchange chromatography; the alpha-chains (42 steps), their tryptic peptides as well as the prolyl-peptides were subjected to automatic liquid- and gas-phase Edman degradation. The two alpha-chains are very similar, differing at only one position (Asp15----Gly15). Comparison with human hemoglobin alpha-chain shows 16 and 17 exchanges, for alpha 1 and alpha II chains, respectively; two substitutions involve alpha 1/beta 1 contacts and one the heme contacts. A high degree of homology was noted when the alpha-chains were compared to the corresponding chains of other representatives of the Carnivora order.     

Primary structure and functional properties of the hemoglobin from the free-tailed bat Tadarida brasiliensis (Chiroptera). Small effect of carbon dioxide on oxygen affinity

The hemoglobin of the Free-Tailed Bat Tadarida brasiliensis (Microchiroptera) comprises two components (Hb I and Hb II) in nearly equal amounts. Both hemoglobins have identical beta-chains, whereas the alpha-chains differ in having glycine (Hb I) or aspartic acid (Hb II) in position 115 (GH3). The components could be isolated by DEAE-Sephacel chromatography and separated into the globin chains by chromatography on carboxymethyl-cellulose CM-52. The sequences have been determined by Edman degradation with the film technique or the gas phase method (the alpha I-chains with the latter method only), using the native chains and tryptic peptides, as well as the C-terminal prolyl-peptide obtained by acid hydrolysis of the Asp-Pro bond in the beta-chains. The comparison with human hemoglobin showed 18 substitutions in the alpha-chains and 24 in the beta-chains. In the alpha-chains one amino-acid exchange involves an alpha 1/beta 1-contact. In the beta-chains one heme contact, three alpha 1/beta 1- and one alpha 1/beta 2-contacts are substituted. A comparison with other chiropteran hemoglobin sequences shows similar distances to Micro- and Megachiroptera. The oxygenation characteristics of the composite hemolysate and the two components, measured in relation to pH, Cl-, and 2,3-bis-phosphoglycerate, are described. The effect of carbon dioxide on oxygen affinity is considerably smaller than that observed in human hemoglobin, which might be an adaptation to life under hypercapnic conditions.     

Effects of different beta73 amino acids on formation of 14-stranded fibers of Hb S versus double-stranded crystals of Hb C-Harlem

Hb S (alpha(2)beta(2)(6Glu-->Val)) forms polymers, while Hb C-Harlem (alpha(2)beta(2)(6Glu-->Val,73Asp-->Asn)) forms crystals upon oversaturation. Since the only difference between the two is the beta73 amino acid, it follows that this site is a critical determinant in promoting either polymerization or crystallization. Beta73 Asp in Hb S forms a hydrogen bond with beta4 Thr, while beta73 Asn in Hb C-Harlem may inhibit this interaction as well as increase the hydrophobicity at the EF helix beta6 Val acceptor sites. Two new beta73 Hb S variants (beta73 His and Leu) were constructed and analyzed to define other amino acids facilitating formation of Hb S-like polymers versus Hb C-Harlem-like crystals. The two variants that were chosen were expected to either (1) enhance formation of the beta73-beta4 hydrogen bond (beta73 His) or (2) inhibit it and increase the hydrophobicity of the EF helix beta6 Val acceptor sites (beta73 Leu). beta73 His Hb S formed fibers but at a lower concentration than Hb S, while beta73 Leu Hb S formed crystals but at a higher concentration than Hb C-Harlem. The solubility of beta73 His Hb S was (1)/(7) of that of Hb S, while the solubility of beta73 Leu Hb S was similar to that of Hb C-Harlem. The delay time prior to polymer or crystal formation depended on Hb concentration. The delay time for beta73 His Hb S was 10(5)-fold shorter than that for Hb S, while that for beta73 Leu Hb S was 10(5)-fold longer in 1.0 M phosphate buffer. NMR results indicate beta73 amino acid changes induce alteration in the beta-chain heme pocket region, while CD results indicate no change in the helical content of the variants. These results suggest that enhancing the beta73-beta4 hydrogen bond and/or induced changes in the heme pocket by the beta73 Asp to His change facilitate formation of Hb S-like fibers. Our results also suggest that removal of the beta73-beta4 hydrogen bond and enhancing the hydrophobicity of the EF helix beta6 Val acceptor sites by the beta73 Asp to Leu or Asn changes delay nuclei formation and facilitate formation of Hb C-Harlem-like crystals.     

Oxygen equilibrium and EPR studies on alpha1beta1 hemoglobin dimer

We undertook this project to clarify whether hemoglobin (Hb) dimers have a high affinity for oxygen and cooperativity. For this, we prepared stable Hb dimers by introducing the mutation Trp-->Glu at beta37 using our Escherichia coli expression system at the alpha1beta2 interface of Hb, and analyzed their molecular properties. The mutant hybrid Hbs with a single oxygen binding site were prepared by substituting Mg(II) protoporphyrin for ferrous heme in either the alpha or beta subunit, and the oxygen binding properties of the free dimers were investigated. Molecular weight determination of both the deoxy and CO forms showed all these molecules to be dimers in the absence of IHP at different protein concentrations. Oxygen equilibrium measurements showed high affinity and non-cooperative oxygen binding for all mutant Hb and hybrid Hb dimers. However, EPR results on the [alpha(N)(Fe-NO)beta(M)(Mg)] hybrid showed some alpha1beta1 interactions. These results provide some clues as to the properties of Hb dimers, which have not been studied extensively owing to practical difficulties in their preparation.     

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

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

Effect of zeta-globin substitution on the O2-transport properties of Hb S in vitro and in vivo

Hemoglobin zeta(2)beta(2)(S) is generated by substituting embryonic zeta-globin subunits for the normal alpha-globin components of Hb S (alpha(2)beta(2)(S)). This novel hemoglobin has recently been shown to inhibit polymerization of Hb S in vitro and to normalize the pathological phenotype of mouse models of sickle cell disease in vivo. Despite its promise as a therapeutic tool in human disease, however, the basic O(2)-transport properties of Hb zeta(2)beta(2)(S) have not yet been described. Using human hemoglobins purified from complex transgenic-knockout mice, we show that Hb zeta(2)beta(2)(S) exhibits an O(2) affinity as well as a Hill coefficient, Bohr response, and allosteric properties in vitro that are suboptimally suited for physiological O(2) transport in vivo. These data are substantiated by in situ analyses demonstrating an increase in the O(2) affinity of intact erythrocytes from mice that express Hb zeta(2)beta(2)(S). Surprisingly, though, co-expression of Hb zeta(2)beta(2)(S) leads to a substantial improvement in the tissue oxygenation of mice that model sickle cell disease. These analyses suggest that, in the context of sickle cell disease, the beneficial antisickling effects of Hb zeta(2)beta(2)(S) outweigh its O(2)-transport liabilities. The potential structural bases for the antisickling properties of Hb zeta(2)beta(2)(S) are discussed in the context of these new observations.     

Novel recombinant hemoglobin, rHb (beta N108Q), with low oxygen affinity, high cooperativity, and stability against autoxidation

Using our Escherichia coli expression system, we have constructed rHb (beta N108Q), a new recombinant hemoglobin (rHb), with the amino acid substitution located in the alpha(1)beta(1) subunit interface and in the central cavity of the Hb molecule. rHb (beta N108Q) exhibits low oxygen affinity, high cooperativity, enhanced Bohr effect, and slower rate of autoxidation of the heme iron atoms from the Fe(2+) to the Fe(3+) state than other low-oxygen-affinity rHbs developed in our laboratory, e.g., rHb (alpha V96W) and rHb (alpha V96W, beta N108K). It has been reported by Olson and co-workers [Carver et al. (1992) J. Biol. Chem. 267, 14443-14450; Brantley et al. (1993) J. Biol. Chem. 268, 6995-7010] that the substitution of phenylalanine for leucine at position 29 of myoglobin can inhibit autoxidation in myoglobin and at position 29 of the alpha-chain of hemoglobin can lower NO reaction in both the deoxy and the oxy forms of human normal adult hemoglobin. Hence, we have further introduced this mutation, alpha L29F, into beta N108Q. rHb (alpha L29F, beta N108Q) is stabilized against auto- and NO-induced oxidation as compared to rHb (beta N108Q), but exhibits lower oxygen affinity at pH below 7.4 and good cooperativity as compared to Hb A. Proton nuclear magnetic resonance (NMR) studies show that rHb (beta N108Q) has similar tertiary structure around the heme pockets and quaternary structure in the alpha(1)beta(1) and alpha(1)beta(2) subunit interfaces as compared to those of Hb A. The tertiary structure of rHb (alpha L29F, beta N108Q) as measured by (1)H NMR, especially the alpha-chain heme pocket region (both proximal and distal histidyl residues), is different from that of CO- and deoxy-Hb A, due to the amino acid substitution at alpha L29F. (1)H NMR studies also demonstrate that rHb (beta N108Q) can switch from the R quaternary structure to the T quaternary structure without changing ligation state upon adding an allosteric effector, inositol hexaphosphate, and reducing the temperature. On the basis of its low oxygen affinity, high cooperativity, and stability against autoxidation, rHb (beta N108Q) is considered a potential candidate for the Hb-based oxygen carrier in a blood substitute system.     

A role for the alpha 113 (GH1) amino acid residue in the polymerization of sickle hemoglobin. Evaluation of its inhibitory strength and interaction linkage with two fiber contact sites (alpha 16/23) located in the AB region of the alpha-chain

A cluster of amino acid residues located in the AB-GH region of the alpha-chain are shown in intra-double strand axial interactions of the hemoglobin S (HbS) polymer. However, alphaLeu-113 (GH1) located in the periphery is not implicated in any interactions by either crystal structure or models of the fiber, and its role in HbS polymerization has not been explored by solution experiments. We have constructed HbS Twin Peaks (betaGlu-6-->Val, alphaLeu-113-->His) to ascertain the hitherto unknown role of the alpha113 site in the polymerization process. The structural and functional behavior of HbS Twin Peaks was comparable with HbS. HbS Twin Peaks polymerized with a slower rate compared with HbS, and its polymer solubility (C(sat)) was found to be about 1.8-fold higher than HbS. To further authenticate the participation of the alpha113 site in the polymerization process as well as to evaluate its relative inhibitory strength, we constructed HbS tetramers in which the alpha113 mutation was coupled individually with two established fiber contact sites (alpha16 and alpha23) located in the AB region of the alpha-chain: HbS(alphaLys-16-->Gln, alphaLeu-113-->His), HbS(alphaGlu-23-->Gln, alphaLeu-113-->His). The single mutants at alpha16/alpha23 sites were also engineered as controls. The C(sat) values of the HbS point mutants involving sites alpha16 or alpha23 were higher than HbS but markedly lower as compared with HbS Twin Peaks. In contrast, C(sat) values of both double mutants were comparable with or higher than that of HbS Twin Peaks. The demonstration of the inhibitory effect of alpha113 mutation alone or in combination with other sites, in quantitative terms, unequivocally establishes a role for this site in HbS gelation. These results have implications for development of a more accurate model of the fiber that could serve as a blueprint for therapeutic intervention.     

Mouse alpha chains inhibit polymerization of hemoglobin induced by human beta S or beta S Antilles chains

A murine model of sickle cell disease was tested by studying the polymerization of hybrid hemoglobin tetramers between alpha mouse and human beta S or beta S Antilles chains were prepared from Hb S Antilles, which was a new sickling hemoglobin inducing a sickle cell syndrome more severe than Hb S. The hybrid molecules did not polymerize in solution, indicating that the mouse alpha chains inhibited fiber formation. Consequently, a mouse model for sickle cell disease requires the transfer and expression of both alpha and beta S or beta S Antilles genes.     

Cooperative ligand binding of crosslinked hemoglobins at very high temperatures

Human hemoglobin was reacted with the bifunctional reagent bis(3,5-dibromosalicyl) fumarate to yield a derivative (Hb alpha alpha) crosslinked between the two alpha-chains; when the reaction was carried out with HbA already crosslinked between the two beta-chains by 2-nor-2-formylpyridoxal 5'-phosphate, a doubly crosslinked derivative (Hb alpha alpha beta beta) was obtained. We have observed that both modified hemoglobins are extremely stable up to temperatures of at least 85 degrees C. The carbon monoxide binding kinetics of both crosslinked hemoglobins, studied at temperatures between 15 and 85 degrees C, by means of stopped flow and flash photolysis techniques, show that the ligand-linked allosteric transition is maintained even at the highest temperatures. These results are also relevant to the mechanism of thermal unfolding of human hemoglobin, since they show that dissociation into alpha beta dimers (and exposure of the relatively hydrophobic dimer-dimer interfaces) is an obligatory step in the irreversible denaturation of deoxy and carbon monoxy hemoglobin.     

Linkage of interactions in sickle hemoglobin fiber assembly: inhibitory effect emanating from mutations in the AB region of the alpha-chain is annulled by a mutation at its EF corner

The AB and GH regions of the alpha-chain are located in spatial proximity and contain a cluster of intermolecular contact residues of the sickle hemoglobin (HbS) fiber. We have examined the role of dynamics of AB/GH region on HbS polymerization through simultaneous replacement of non-contact Ala(19) and Ala(21) of the AB corner with more flexible Gly or rigid alpha-aminoisobutyric acid (Aib) residues. The polymerization behavior of HbS with Aib substitutions was similar to the native HbS. In contrast, Gly substitutions inhibited HbS polymerization. Molecular dynamics simulation studies of alpha-chains indicated that coordinated motion of AB and GH region residues present in native (Ala) as well as in Aib mutant was disrupted in the Gly mutant. The inhibitory effect due to Gly substitutions was further explored in triple mutants that included mutation of an inter-doublestrand contact (alphaAsn(78) --> His or Gln) at the EF corner. Although the inhibitory effect of Gly substitutions in the triple mutant was unaffected in the presence of alphaGln(78), His at this site almost abrogated its inhibitory potential. The polymerization studies of point mutants (alphaGln(78) --> His) indicated that the inhibitory effect due to Gly substitutions in the triple mutant was synergistically compensated for by the polymerization-enhancing activity of His(78). Similar synergistic coupling, between alphaHis(78) and an intra-double-strand contact point (alpha16) mutation located in the AB region, was also observed. Thus, two conclusions are made: (i) Gly mutations at the AB corner inhibit HbS polymerization by perturbing the dynamics of the AB/GH region, and (ii) perturbations of AB region (through changes in dynamics of the AB/GH region or abolition of a specific fiber contact site) that influence HbS polymerization do so in concert with alpha78 site at the EF corner. The overall results provide insights about the interaction-linkage between distant regions of the HbS tetramer in fiber assembly.     

Hemoglobin Einstein: semisynthetic deletion in the B-helix of the alpha-chain

The influence of the deletion of the tetra peptide segment alpha(23-26) of the B-helix of the alpha-chain of hemoglobin-A on its assembly, structure, and functional properties has been investigated. The hemoglobin with the deletion, ss-Hemoglobin-Einstein, is readily assembled from semisynthetic alpha(1-141) des(23-26) globin and human betaA-chain. The deletion of alpha(23-26) modulates the O2 affinity of hemoglobin in a buffer/allosteric effector specific fashion, but has little influence on the Bohr effect. The deletion has no influence on the thermodynamic stability of the alpha1beta1 and the alpha1beta2 interface. The semisynthetic hemoglobin exhibits normal intersubunit interactions at the alpha1beta1 and alpha1beta2 interfaces as reflected by 1H-NMR spectroscopy. Molecular modeling studies of ss-Hemoglobin-Einstein suggest that the segment alpha(28-35) is in a helical conformation, while the segment alpha(19-22) is the nonhelical AB region. The shortened B-helix conserves the interactions of alpha1beta1 interface. The results demonstrate a high degree of plasticity in the hemoglobin structure that accommodates the deletion of alpha(23-26) without perturbing its overall global conformation.     

Ligand binding properties and structural studies of recombinant and chemically modified hemoglobins altered at beta 93 cysteine

To investigate the roles of beta93 cysteine in human normal adult hemoglobin (Hb A), we have constructed four recombinant mutant hemoglobins (rHbs), rHb (betaC93G), rHb (betaC93A), rHb (betaC93M), and rHb (betaC93L), and have prepared two chemically modified Hb As, Hb A-IAA and Hb A-NEM, in which the sulfhydryl group at beta93Cys is modified by sulfhydryl reagents, iodoacetamide (IAA) and N-ethylmaleimide (NEM), respectively. These variants at the beta93 position show higher oxygen affinity, lower cooperativity, and reduced Bohr effect relative to Hb A. The response of some of these Hb variants to allosteric effectors, 2,3-bisphosphoglycerate (2,3-BPG) and inositol hexaphosphate (IHP), is decreased relative to that of Hb A. The proton nuclear magnetic resonance (NMR) spectra of these Hb variants show that there is a marked influence on the proximal heme pocket of the beta-chain, whereas the environment of the proximal heme pocket of the alpha-chain remains unchanged as compared to Hb A, suggesting that higher oxygen affinity is likely to be determined by the heme pocket of the beta-chain rather than by that of the alpha-chain. This is further supported by NO titration of these Hbs in the deoxy form. For Hb A, NO binds preferentially to the heme of the alpha-chain relative to that of the beta-chain. In contrast, the feature of preferential binding to the heme of the alpha-chain becomes weaker and even disappears for Hb variants with modifications at beta93Cys. The effects of IHP on these Hbs in the NO form are different from those on HbNO A, as characterized by (1)H NMR spectra of the T-state markers, the exchangeable resonances at 14 and 11 ppm, reflecting that these Hb variants have more stability in the R-state relative to Hb A, especially rHb (betaC93L) and Hb A-NEM in the NO form. The changes of the C2 proton resonances of the surface histidyl residues in these Hb variants in both the deoxy and CO forms, compared with those of Hb A, indicate that a mutation or chemical modification at beta93Cys can result in conformational changes involving several surface histidyl residues, e.g., beta146His and beta2His. The results obtained here offer strong evidence to show that the salt bridge between beta146His and beta94Asp and the binding pocket of allosteric effectors can be affected as the result of modifications at beta93Cys, which result in the destabilization of the T-state and a reduced response of these Hbs to allosteric effectors. We further propose that the impaired alkaline Bohr effect can be attributed to the effect on the contributions of several surface histidyl residues which are altered because of the environmental changes caused by mutations and chemical modifications at beta93Cys.     

Stability of asymmetrical hybrid hemoglobins. Determination by anaerobic high performance liquid chromatography

Asymmetrical hybrid hemoglobins formed in mixtures of Hb A and Hb S, Hb F and Hb S, Hb S and Hb York(beta 146 His----Pro), and Hb A and Hb York were separated by high performance liquid chromatography on cation and anion exchange columns under anaerobic conditions. The ratio of the hybrid hemoglobin to the total mixture was consistently lower than that theoretically expected and decreased with longer elution times. The hybrid tetramer appears to be unstable even under anaerobic conditions and dissociates into alpha beta dimers. The time course of dissociation of the hybrid hemoglobins was determined by varying the separation programs and thus separating the hybrid hemoglobin at different elution times. The rate of the dissociation of the hybrid hemoglobins studied follows first order kinetics. The lines representing the time course of dissociation of hybrid hemoglobins were extrapolated to time 0 to determine the fraction of the hybrid hemoglobin in the mixture prior to separation. The values obtained for equimolar mixtures of Hb A and Hb S and Hb York and Hb S or Hb A were in agreement with the expected theoretical value (50%). In contrast, the value obtained for hybrid hemoglobin FS was slightly less (about 40%). AY and SY hybrid hemoglobins dissociated into dimers at a considerably faster rate than did AS and FS hybrid hemoglobins, possibly because of the mutation at the beta 146-position in hybrid hemoglobins containing alpha beta Y dimers. This mutation hinders the formation of salt bridges that normally stabilize the "T" quaternary conformation. Since such hybrid hemoglobins have a partial "R" conformation even when deoxygenated, their rate of dissociation to dimers is expected to increase.     

A recombinant human hemoglobin with anti-sickling properties greater than fetal hemoglobin

A new recombinant, human anti-sickling beta-globin polypeptide designated beta(AS3) (betaGly(16) --> Asp/betaGlu(22) --> Ala/betaThr(87) --> Gln) was designed to increase affinity for alpha-globin. The amino acid substitutions at beta22 and beta87 are located at axial and lateral contacts of the sickle hemoglobin (HbS) polymers and strongly inhibit deoxy-HbS polymerization. The beta16 substitution confers the recombinant beta-globin subunit (beta(AS3)) with a competitive advantage over beta(S) for interaction with the alpha-globin polypeptide. Transgenic mouse lines that synthesize high levels of HbAS3 (alpha(2)beta(AS3)(2)) were established, and recombinant HbAS3 was purified from hemolysates and then characterized. HbAS3 binds oxygen cooperatively and has an oxygen affinity that is comparable with fetal hemoglobin. Delay time experiments demonstrate that HbAS3 is a potent inhibitor of HbS polymerization. Subunit competition studies confirm that beta(AS3) has a distinct advantage over beta(S) for dimerization with alpha-globin. When equal amounts of beta(S)- and beta(AS3)-globin monomers compete for limiting alpha-globin chains up to 82% of the tetramers formed is HbAS3. Knock-out transgenic mice that express exclusively human HbAS3 were produced. When these mice were bred with knock-out transgenic sickle mice the beta(AS3) polypeptides corrected all hematological parameters and organ pathology associated with the disease. Expression of beta(AS3)-globin should effectively lower the concentration of HbS in erythrocytes of patients with sickle cell disease, especially in the 30% percent of these individuals who coinherit alpha-thalassemia. Therefore, constructs expressing the beta(AS3)-globin gene may be suitable for future clinical trials for sickle cell disease.