Mutant Hemoglobin Research Articles

Mechanisms of Homogeneous Nucleation of Polymers of Sickle Cell Anemia Hemoglobin in Deoxy State

The primary pathogenic event of sickle cell anemia is the polymerization of the mutant hemoglobin (Hb) S within the red blood cells, occurring when HbS is in deoxy state in the venous circulation. Polymerization is known to start with nucleation of individual polymer fibers, followed by growth and branching via secondary nucleation, yet the mechanisms of nucleation of the primary fibers have never been subjected to dedicated tests. We implement a technique for direct determination of rates and induction times of primary nucleation of HbS fibers, based on detection of emerging HbS polymers using optical differential interference contrast microscopy after laser photolysis of CO-HbS. We show that: (i) nucleation throughout these determinations occurs homogeneously and not on foreign substrates; (ii) individual nucleation events are independent of each other; (iii) the nucleation rates are of the order of 10 6–10 8 cm −3 s −1; (iv) nucleation induction times agree with an a priori prediction based on Zeldovich's theory; (v) in the probed parameter space, the nucleus contains 11 or 12 molecules. The nucleation rate values are comparable to those leading to erythrocyte sickling in vivo and suggest that the mechanisms deduced from in vitro experiments might provide physiologically relevant insights. While the statistics and dynamics of nucleation suggest mechanisms akin to those for small-molecule and protein crystals, the nucleation rate values are nine to ten orders of magnitude higher than those known for protein crystals. These high values cannot be rationalized within the current understanding of the nucleation processes.

Crystallographic analysis of the interaction of nitric oxide with quaternary-T human hemoglobin.

In addition to interacting with hemoglobin as a heme ligand to form nitrosylhemoglobin, NO can react with cysteine sulfhydryl groups to form S-nitrosocysteine or cysteine oxides such as cysteinesulfenic acid. Both modes of interaction are very sensitive to the quaternary structure of hemoglobin. To directly view the interaction of NO with quaternary-T deoxyhemoglobin, crystallographic studies were carried out on crystals of deoxyhemoglobin that were exposed to gaseous NO under a variety of conditions. Consistent with previous spectroscopic studies in solution, these crystallographic studies show that the binding of NO to the heme groups of crystalline wild-type deoxyhemoglobin ruptures the Fe-proximal histidine bonds of the alpha-subunits but not the beta-subunits. This finding supports Perutz's theory that ligand binding induces tension in the alpha Fe-proximal histidine bond. To test Perutz's theory, deoxy crystals of the mutant hemoglobin betaW37E were exposed to NO. This experiment was carried out because previous studies have shown that this mutation greatly reduces the quaternary constraints that oppose the ligand-induced movement of the alpha-heme Fe atom into the plane of the porphyrin ring. As hypothesized, the Fe-proximal histidine bonds in both the beta- and the alpha-subunits remain intact in crystalline betaW37E after exposure to NO. With regard to S-nitrosocysteine or cysteine oxide formation, no evidence for the reaction of NO with any cysteine residues was detected under anaerobic conditions. However, when deoxyhemoglobin crystals are first exposed to air and then to NO, the appearance of additional electron density indicates that Cys93(F9)beta has been modified, most likely to cysteinesulfenic acid. This modification of Cys93(F9)beta disrupts the intrasubunit salt bridge between His146(HC3)beta and Asp94(FG1)beta, a key feature of the quaternary-T hemoglobin structure. Also presented is a reanalysis of our previous crystallographic studies [Chan, N.-L., et al. (1998) Biochemistry 37, 16459-16464] of the interaction of NO with liganded hemoglobin in the quaternary-R2 structure. These studies showed additional electron density at Cys93(F9)beta that was consistent with an NO adduct. However, for reasons discussed in this paper, we now believe that this adduct may be the Hb-S-N.-O-H radical intermediate and not Hb-S-N=O as previously suggested.

Ligand-linked structural transitions in crystals of a cooperative dimeric hemoglobin.

Cooperative ligand binding in the dimeric hemoglobin (HbI) from the blood clam Scapharca inaequivalvis is mediated primarily by tertiary structural changes, but with a small quaternary rearrangement (approximately 3 degrees), based on analysis of distinct crystal forms for ligated and unligated molecules. We report here ligand transition structures in both crystal forms. Binding CO to unligated HbI crystals results in a structure that approaches, but does not attain, the full allosteric transition. In contrast, removing CO from the HbI-CO crystals results in a structure that possesses all the key low affinity attributes previously identified from analysis of HbI crystals grown in the unligated state. Subsequent binding of CO shows the reversibility of this process. The observed structural changes include the quaternary rearrangement even under the constraints of lattice interactions, demonstrating that subunit rotation is an integral component of the ligand-linked structural transition in HbI. Analysis of both crystal forms, along with data from HbI mutants, suggests that the quaternary structural change is linked to the movement of the heme group, supporting a hypothesis that the heme movement is the central event that triggers cooperative ligand binding in this hemoglobin dimer. These results show both the effects of a crystal lattice in limiting quaternary structural transitions and provide the first example of complete allosteric transitions within another crystal lattice.

Conformational Changes in Hemoglobin S (βE6V) Imposed by Mutation of the βGlu7–βLys132 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.

Quantification of Effector Binding to the Hemoglobin Central Cavity by Intrinsic and Extrinsic Steady-State Fluorescence

The relative intrinsic and extrinsic fluorescence of hemoglobins are established markers of the R (oxy) → T (deoxy) transition and reveal site-specific conformational differences amongst hemoglobin (Hb) mutants. The Hb central cavity has been probed by binding the fluorescent analogue of 2,3-diphosphoglycerate, 8-hydroxy-1,3,6-pyrenetrisulfonate (HPT). An approach to quantify binding of HPT to HbC (β6 Lys) and HbA (β6 Glu), by steady-state front-face fluorescence spectroscopy using both the intrinsic and extrinsic emissions, is presented. When HPT specifically binds to Hb, efficient fluorescence energy transfer from the intrinsic fluorescence of Hb to HPT occurs, decreasing the intrinsic fluorescence of Hb that plateaus upon stoichiometric binding. HPT fluorescence is significantly but not totally quenched upon binding to HbA and HbC. HPT exhibits a molecular binding ratio of 2:1 to HbC, in contrast to HbA (1:1 binding). The apparent secondary binding site for HbC is weaker (KD1 = 25 μM vs. KD2 = 0.15 mM). Conformational alterations of HbC at the αα and ββ clefts of the central cavity are further supported by these data.

Beta-globin-like gene cluster haplotypes in hemoglobinopathies.

The pioneering work of Kan and Dozy () revealed by restriction endonuclease mapping a genetic variation in an HpaI recognition site about 5000 nucleotides from the 3′ end of the β-globin gene. Instead of a normal 7.6-kb fragment containing the β-globin gene, 7.0- and 13.0-kb variants were detected and were found in African Americans, Asians, and Caucasians. The 13.0-kb variant (HpaI+) was frequently associated with the sickle hemoglobin (Hb) mutation. Kan and Dozy () predicted that polymorphisms in a restriction enzyme site could be considered a new class of genetic marker and may offer a new approach to linkage analysis and anthropological studies. Based on limited data (), they reported that linkage to the wild-type HpaI-positive site was characteristic of West Africans while an HpaI-negative site typified East Africans. This finding did not show definitively that the mutation had occurred in two different chromosomal backgrounds, because a secondary mutation at the HpaI site could have postdated the sickle mutation.

Plasmodium falciparum erythrocyte invasion through glycophorin C and selection for Gerbich negativity in human populations.

Geographic overlap between malaria and the occurrence of mutant hemoglobin and erythrocyte surface proteins has indicated that polymorphisms in human genes have been selected by severe malaria. Deletion of exon 3 in the glycophorin C gene (called GYPCDeltaex3 here) has been found in Melanesians; this alteration changes the serologic phenotype of the Gerbich (Ge) blood group system, resulting in Ge negativity. The GYPCDeltaex3 allele reaches a high frequency (46.5%) in coastal areas of Papua New Guinea where malaria is hyperendemic. The Plasmodium falciparum erythrocyte-binding antigen 140 (EBA140, also known as BAEBL) binds with high affinity to the surface of human erythrocytes. Here we show that the receptor for EBA140 is glycophorin C (GYPC) and that this interaction mediates a principal P. falciparum invasion pathway into human erythrocytes. EBA140 does not bind to GYPC in Ge-negative erythrocytes, nor can P. falciparum invade such cells using this invasion pathway. This provides compelling evidence that Ge negativity has arisen in Melanesian populations through natural selection by severe malaria.

Site mutations disrupt inter-helical H-bonds (α14W–α67T and β15W–β72S) involved in kinetic steps in the hemoglobin R→T transition without altering the free energies of oxygenation

Three recombinant mutant hemoglobins (rHbs) of human normal adult hemoglobin (Hb A), rHb (αT67V), rHb (βS72A), and rHb (αT67V, βS72A), have been constructed to test the role of the tertiary intra-subunit H-bonds between α67T and α14W and between β72S and β15W in the cooperative oxygenation of Hb A. Oxygen-binding studies in 0.1 M sodium phosphate buffer at 29 °C show that rHb (αT67V), rHb (βS72A), and rHb (αT67V, βS72A) exhibit oxygen-binding properties similar to those of Hb A. The binding of oxygen to these rHbs is highly cooperative, with a Hill coefficient of approximately 2.8, compared to approximately 3.1 for Hb A. Proton nuclear magnetic resonance (NMR) studies show that rHb (αT67V), rHb (βS72A), rHb (αT67V, βS72A), and Hb A have similar quaternary structures in the α1β2 subunit interfaces. In particular, the inter-subunit H-bonds between α42Tyr and β99Asp and between β37Trp and α94Asp are maintained in the mutants in the deoxy form. There are slight perturbations in the distal heme pocket region of the α- and β-chains in the mutants. A comparison of the exchangeable 1H resonances of Hb A with those of these three rHbs suggests that α67T and β72S are H-bonded to α14W and β15W, respectively, in the CO and deoxy forms of Hb A. The absence of significant free energy changes for the oxygenation process of these three rHbs compared to those of Hb A, even though the inter-helical H-bonds are abolished, indicates that these two sets of H-bonds are of comparable strength in the ligated and unligated forms of Hb A. Thus, the mutations at αT67V and βS72A do not affect the overall energetics of the oxygenation process. The preserved cooperativity in the binding of oxygen to these three mutants also implies that there are multiple interactions involved in the oxygenation process of Hb A.

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.

Max Ferdinand Perutz

Max Ferdinand Perutz

NMR Investigation of the Dynamics of Tryptophan Side-chains in Hemoglobins

NMR relaxation measurements of 15N spin–lattice relaxation rate ( R 1), spin–spin relaxation rate ( R 2), and heteronuclear nuclear Overhauser effect (NOE) have been carried out at 11.7 T and 14.1 T as a function of temperature for the side-chains of the tryptophan residues of 15N-labeled and/or ( 2H, 15N)-labeled recombinant human normal adult hemoglobin (Hb A) and three recombinant mutant hemoglobins, rHb Kempsey (βD99N), rHb (αY42D/βD99N), and rHb (αV96W), in the carbonmonoxy and the deoxy forms as well as in the presence and in the absence of an allosteric effector, inositol hexaphosphate (IHP). There are three Trp residues (α14, β15, and β37) in Hb A for each αβ dimer. These Trp residues are located in important regions of the Hb molecule, i.e. α14Trp and β15Trp are located in the α 1β 1 subunit interface and β37Trp is located in the α 1β 2 subunit interface. The relaxation experiments show that amino acid substitutions in the α 1β 2 subunit interface can alter the dynamics of β37Trp. The transverse relaxation rate ( R 2) for β37Trp can serve as a marker for the dynamics of the α 1β 2 subunit interface. The relaxation parameters of deoxy-rHb Kemspey (βD99N), which is a naturally occurring abnormal human hemoglobin with high oxygen affinity and very low cooperativity, are quite different from those of deoxy-Hb A, even in the presence of IHP. The relaxation parameters for rHb (αY42D/βD99N), which is a compensatory mutant of rHb Kempsey, are more similar to those of Hb A. In addition, TROSY–CPMG experiments have been used to investigate conformational exchange in the Trp residues of Hb A and the three mutant rHbs. Experimental results indicate that the side-chain of β37Trp is involved in a relatively slow conformational exchange on the micro- to millisecond time-scale under certain experimental conditions. The present results provide new dynamic insights into the structure–function relationship in hemoglobin.

The carbon monoxide derivative of human hemoglobin carrying the double mutation LeuB10→Tyr and HisE7→Gln on α and β chains probed by infrared spectroscopy

The fine structural properties of the distal heme pocket have been probed by infrared spectroscopy of ferrous carbon monoxy human hemoglobin mutants carrying the mutations LeuB10→Tyr and HisE7→Gln on the α, β, and both chains, respectively. The stretching frequency of iron-bound carbon monoxide occurs as a single broad band around 1943 cm −1 in both the α and the β mutated chains. Such a frequency value indicates that no direct hydrogen bonding exists between the bound CO molecule and the TyrB10 phenolic oxygen, at variance with other naturally occurring TyrB10, GlnE7 nonvertebrate hemoglobins. The rates of carbon monoxide release have been determined for the first time by a Fourier transform infrared spectroscopy stopped-flow technique that allowed us to single out the heterogeneity in the kinetics of CO release in the α and β chains for the mutated proteins and for native HbA. The rates of CO release are 15- to 20-fold faster for the mutated α or β chains with respect to the native ones consistent with the lack of distal stabilization on the iron-bound CO molecule. The present results demonstrate that residues in key topological positions (namely E7 and B10) for the distal steric control of the iron-bound ligand are not interchangeable among hemoglobins from different species.

Sickle Hemoglobin Polymer Stability Probed by Triple and Quadruple Mutant Hybrids

As part of an effort to understand the interactions in HbS polymerization, we have produced and studied a recombinant triple mutant, D6A(alpha)/D75Y(alpha)/E121R(beta), and a quadruple mutant comprising the preceding mutation plus the natural genetic mutation of sickle hemoglobin, E6V(beta). These recombinant hemoglobins expressed in yeast were extensively characterized, and their structure and oxygen binding cooperativity were found to be normal. Their tetramer-dimer dissociation constants were within a factor of 2 of HbA and HbS. Polymerization of these mutants mixed with HbS was investigated by a micromethod based on volume exclusion by dextran. The elevated solubility of mixtures of HbS with HbA and HbF in dextran could be accurately predicted without any variable parameters. Relative to HbS, the copolymerization probability of the quadruple mutant/HbS hybrid was found to be 6.2, and the copolymerization probability for the triple mutant/HbS hybrid was 0.52. The pure quadruple mutant had a solubility slightly above that of its hybrid with HbS. One way to explain these results is to require significant cis-trans differences in the polymer and that HbA assemble above 42.5 g/dl. A second way to explain these data is by the modification of motional freedom, thereby changing vibrational entropy in the polymer.

Hemoglobin Kansas found by electrophoretic diagnosis in Brazil

Some hemoglobin variants with abnormal oxygen affinity have been reported so far from various regions of the world. They can be classified by their oxygen affinity and 15 variants with low oxygen affinity have been reported. A number of hemoglobin mutants which show an abnormal affinity for oxygen have been reported, but only few cases of hemoglobin Kansas. All cases reported so far are from Japan or in Japanese families. In this paper we describe a Brazilian patient with cyanosis and hemoglobin Kansas diagnosed by an electrophoretical procedure.

The father of us all.

The father of us all.

Flexibility and nucleation in sickle hemoglobin

We have studied the self-assembly of Hemoglobin C-Harlem (HbC-Harlem), a double mutant of hemoglobin that possesses the β6 Glu → Val mutation of sickle hemoglobin (HbS) plus β73 Asp → Asn. By electron microscopy we find it forms crystals, rather than the wrapped multistranded fibers seen in HbS. Fourier transforms of the crystals yield unit cell parameters indistinguishable from crystals of HbS. Differential interference contrast (DIC) microscopy and birefringence also show crystal formation rather than the polymers or domains seen for HbS, while the growth patterns showed radiating crystal structures rather than simple linear crystalline forms. The solubility of the assembly was measured using a photolytic micromethod over a temperature range of 17–31 °C in 0.15 M phosphate buffer and found to be essentially the same as that of fibers of HbS. The assembly kinetics were observed by photolysis of the carbon monoxide derivative, and the mass of assembled hemoglobin was found to grow exponentially, with onset times that were stochastically distributed for small volumes. The stochastic onset of assembly showed strong concentration dependence, similar to but slightly greater than that seen in sickle hemoglobin nucleation. These observations suggest that like HbS, HbC-Harlem assembly proceeds by a homogeneous nucleation process, followed by heterogeneous nucleation. However, relative to HbS, both homogeneous and heterogeneous nucleation are suppressed by almost 11 orders of magnitude. The slowness of nucleation can be reconciled with the similarity of the solubility to HbS by an increase in contact energy coupled with a decrease in vibrational entropy recovered on assembly. This also explains the linearity of the double-strands, and agrees with the chemical nature of the structural replacement.

Control of heme reactivity by diffusion: structural basis and functional characterization in hemoglobin mutants.

The effect of mutagenesis on O(2), CO, and NO binding to mutants of human hemoglobin, designed to modify some features of the reactivity that hinder use of hemoglobin solutions as blood substitute, has been extensively investigated. The kinetics may be interpreted in the framework of the Monod-Wyman-Changeux two-state allosteric model, based on the high-resolution crystallographic structures of the mutants and taking into account the control of heme reactivity by the distal side mutations. The mutations involve residues at topological position B10 and E7, i.e., Leu (B10) to Tyr and His (E7) to Gln, on either the alpha chains alone (yielding the hybrid tetramer Hbalpha(YQ)), the beta chains alone (hybrid tetramer Hbbeta(YQ)), or both types of chains (Hb(YQ)). Our data indicate that the two mutations affect ligand diffusion into the pocket, leading to proteins with low affinity for O(2) and CO, and especially with reduced reactivity toward NO, a difficult goal to achieve. The observed kinetic heterogeneity between the alpha(YQ) and beta(YQ) chains in Hb(YQ) has been rationalized on the basis of the three-dimensional structure of the active site. Furthermore, we report for the first time an experiment of partial CO binding, selective for the beta chains, to high salt crystals of the mutant Hb(YQ) in the T-state; these crystallographic data may be interpreted as "snapshots" of the initial events possibly occurring on ligand binding to the T-allosteric state of this peculiar mutant Hb.

Pathophysiology of sickle cell disease: Role of cellular and genetic modifiers

Sickle hemoglobin (HbS), caused by a point mutation in the β-globin gene of hemoglobin, polymerizes when deoxygenated. The pathophysiology of sickle cell disease results from cellular defects caused directly by the hemoglobin mutation interacting with the environment and many other gene products—a few known, but most yet unidentified—a typical example of epistasis. How normal tissue perfusion is interrupted is complex and why the phenotype of sickle cell disease differs from patient to patient is poorly understood. We review the “classic” aspects of the pathophysiology of sickle cell disease and focus on known and potential modulators of the phenotype of this disorder.

Probing the importance of the amino-terminal sequence of the beta- and gamma-chains to the properties of normal adult and fetal hemoglobins.

A recombinant mutant of human fetal hemoglobin (Hb F), named rHb Oscar, has been constructed to explore the importance of the sequence of the amino-terminal region of the gamma-chain to the structural and functional properties of Hb F as compared to human normal adult hemoglobin (Hb A). Substitutions in the N-terminal region of Hb A have shown this region to be important to its structural and functional properties. Recent studies of recombinant mutants of Hb A with gamma-chain mutations have been used to probe the significance of the N-terminal sequence to the properties of Hb F. One of these mutants of Hb A, called rHb Felix, contains eight substitutions in the N-terminal region of the beta-chain corresponding to the sequence of the gamma-chain in that region [Dumoulin et al. (1998) J. Biol. Chem. 273, 35032-35038]. rHb Felix exhibits a 2,3-bisphosphoglycerate (2,3-BPG) response like that of Hb A, but its tetramer-dimer dissociation constant is similar to that of Hb F. In contrast, rHb Oscar contains a gamma-chain with eight mutations at the N-terminal end corresponding to the sequence of the beta-chain of Hb A in that region. (1)H NMR studies of rHb Oscar indicate a global structure like that of Hb F. rHb Oscar is not as stable against alkaline denaturation as Hb F but is more stable than Hb A, and it exhibits a stronger response to 2,3-BPG and inositol hexaphosphate as compared to Hb F. The 2,3-BPG effect in rHb Oscar also appears to be slightly enhanced compared to that in Hb A. Subzero isoelectric focusing experiments suggest that rHb Oscar does not have dissociation properties like those of Hb A. These results along with those of rHb Felix illustrate that the effects of the N-terminal region on structure and function of the Hb molecule are complicated by interactions with the rest of the molecule that are not yet well defined. However, studies of complementary mutations of Hb A and Hb F may eventually help to define such interactions and lead to a better understanding of the relationship between the amino acid sequence and the properties of the Hb molecule.

Activation of the low oxygen affinity-inducing potential of the Asn108(beta)-->Lys mutation of Hb-Presbyterian on intramolecular alpha alpha-fumaryl cross-bridging.

The Asn108 beta-->Lys mutation in hemoglobin (HbPresbyterian mutation) endows a low O(2) affinity-inducing propensity to the protein. Introduction of a fumaryl cross-bridge between its two alpha 99 lysine residues also induces a low O(2) affinity into HbA. We have now engineered an alpha alpha-fumaryl cross-bridge into Hb-Presbyterian to determine the synergy or additivity, if any, that can be achieved between these two low O(2) affinity-inducing structural perturbations. Despite the presence of the additional epsilon-amino group of Lys108(beta) within the central cavity, the epsilon-amino group of Lys99(alpha alpha) of deoxy Hb-Presbyterian retained high selectivity for alpha alpha-fumaryl cross-bridging, with an overall efficiency comparable to that with HbA. The alpha alpha-fumaryl cross-linking of Hb-Presbyterian reduced its O(2) affinity much more significantly than that observed with HbA, indicating a synergy between the two low O(2) affinity-inducing structural perturbations. Apparently, the alpha alpha-fumaryl cross-bridge in Hb-Presbyterian activates part of the latent low O(2) affinity-inducing potential of Lys108(beta) that is generally activated in the presence of chloride. The synergy between the Asn108(beta)-->Lys mutation and the alpha alpha-fumaryl cross-bridging was conserved in the presence of chloride, but not in the presence of DPG. Furthermore, in the presence of chloride and DPG, alpha alpha-fumaryl Hb-Presbyterian accessed a low O(2) affinity T-state that is accessed by HbA, alpha alpha-HbA and Hb-Presbyterian only in the presence of IHP. Isoelectric focusing analysis suggested that the alpha alpha-fumaryl cross-linking of Hb-Presbyterian induces changes in the ionization behavior of one or more of the functional groups neighboring Lys99(alpha) and Lys108(beta) [presumably His103(alpha) and/or Glu101(beta)] to compensate for the extra positive charge of Lys108(beta). Molecular modeling studies identified two potential chloride binding sites per alpha beta dimer within the middle of the central cavity of alphaalpha-fumaryl HbA involving residues His103(alpha), Arg104(beta) and Asn108(beta). The affinity of these sites is increased in alpha alpha-fumaryl Hb-Presbyterian as a result of the Asn108(beta)-->Lys mutation. Thus, the results of the present study suggest that the enhanced neutralization of the positive charges in the middle of the central cavity of Hb achieved by these two electrostatic modifications, one (the alpha alpha-fumaryl cross-bridge) acting directly and the other (the Presbyterian mutation) acting indirectly through the mediation of chloride ion binding, facilitates the alpha alpha- fumaryl-Hb Presbyterian to access a low O(2) affinity T-state structure much more readily than either Hb-Presbyterian or alpha alpha-fumaryl HbA.