Preparation and kinetic characterization of a series of betaW37 variants of human hemoglobin A: evidence for high-affinity T quaternary structures

Four variants of human beta globin in which the Trp at position 37 has been replaced with a Tyr, Ala, Gly, or Glu have been expressed in Escherichia coli. These globins have been combined with normal human alpha chains and heme to form tetrameric hemoglobin molecules. A technique for the preparation of alpha chain dimers, which are cross-linked between their alpha99 lysine residues, has been developed, and these alpha dimers were combined with two of the beta globins, betaW37G and betaW37E, to form the corresponding cross-linked variants. The kinetics of CO binding to the deoxygenated derivatives following rapid mixing and of CO rebinding following flash photolysis have been examined as functions of pH in the presence and absence of the organic phosphate inositol hexaphosphate, IHP. The kinetic measurements indicate that replacement of the tryptophan with other residues destabilizes the hemoglobin tetramer, resulting in considerable dissociation of even the deoxygenated hemoglobins into alphabeta dimers at micromolar protein concentrations. Substitutions at beta37 also alter the properties of the deoxygenated hemoglobin tetramer. The alteration of the functional properties of the T states of these variants as well as the tendency of the deoxygenated derivatives to dissociate into alphabeta dimers increases in the order HbA < betaW37Y < betaW37A < betaW37G < betaW37E. Stabilizing the betaW37G or betaW37E tetramers by addition of IHP or by cross-linking does not restore the normal functional properties of the T state. Measurements of the geminate rebinding of CO establish a kinetic difference between the normal R state tetramer and the alphabeta dimer consistent with quaternary enhancement, the greater affinity of oxygen for the R state tetramer than for the alphabeta dimer. Kinetics of geminate rebinding also suggest that quaternary enhancement may be altered by substitutions at the beta37 position.     

Quaternary structure regulates hemin dissociation from human hemoglobin

Rate constants for hemin dissociation from the alpha and beta subunits of native and recombinant human hemoglobins were measured as a function of protein concentration at pH 7.0, 37 degrees C, using H64Y/V68F apomyoglobin as a hemin acceptor reagent. Hemin dissociation rates were also measured for native isolated alpha and beta chains and for recombinant hemoglobin tetramers stabilized by alpha subunit fusion. The rate constant for hemin dissociation from beta subunits in native hemoglobin increases from 1.5 h-1 in tetramers at high protein concentration to 15 h-1 in dimers at low concentrations. The rate of hemin dissociation from alpha subunits in native hemoglobin is significantly smaller (0.3-0.6 h-1) and shows little dependence on protein concentration. Recombinant hemoglobins containing a fused di-alpha subunit remain tetrameric under all concentrations and show rates of hemin loss similar to those observed for wild-type and native hemoglobin at high protein concentration. Rates of hemin dissociation from monomeric alpha and beta chains are much greater, 12 and 40 h-1, respectively, at pH 7, 37 degrees C. Aggregation of monomers to form alpha1beta1 dimers greatly stabilizes bound hemin in alpha chains, decreasing its rate of hemin loss approximately 20-fold. In contrast, dimer formation has little stabilizing effect on hemin binding to beta subunits. A significant reduction in the rate of hemin loss from beta subunits does occur after formation of the alpha1beta2 interface in tetrameric hemoglobin. These results suggest that native human hemoglobin may have evolved to lose heme rapidly after red cell lysis, allowing the prosthetic group to be removed by serum albumin and apohemopexin.     

Oxygenation-linked subunit interactions in human hemoglobin: experimental studies on the concentration dependence of oxygenation curves

An experimental study on the concentration dependence of oxygenation curves for human hemoglobin has been carried out between 4 X 10(-8) M heme and 5 X 10(-4) M heme in 0.1 M tris(hydroxymehtyl)aminomethane hydrochloride, 0.1 M NaCl, 1 mM disodium ethylenediaminetetraacetic acid, pH 7.4, 21.5 degrees C. With decreasing hemoglobin concentration the curves show pronounced shifts in position and shape, consistent with dissociation of tetrameric hemoglobin into dimeric species of high affinity and low cooperativity. Combination of these data with independently determined values of dissociation constants for unliganded and fully liganded hemoglobin permits a resolution of the seven parameters necessary to define the linked binding and subunit association processes. The total oxygenation-linked subunit dissociation energy (6.34 kcal) was resolved into intersubunit contact energy changes between alphabeta dimers in tetrameric hemoglobin which accompany binding of the first, middle two, and last oxygen molecules. The resolution is accurate to within approximately +/-0.3 kcal. To within this limit the isolated dimers are found to bind oxygen noncooperatively and with the same affinity as isolated alpha and beta chains. Equally good fits to the data are obtained when dimers are slightly anticooperative. At least three major energetic states are apparently assumed by hemoglobin tetramers, with respect to the alpha1beta2 contact region, corresponding to (a) unliganded, (b) singly liganded, (c) triply and quadruply liganded species. The results do not establish whether these states may be assumed by a single molecule, or whether they arise as averages over a distrubution of conformational states. They do provide unequivocal evidence against a concerted transition at any particular binding step in a system with only two energetic states of tetramer (i.e., an all or none switchover between T and R states at a particular binding step).     

Synthesized allosteric effectors of the hemoglobin molecule: a possible mechanism for improved erythrocyte oxygen release capability in hemoglobinopathy H disease

Patients with the nondeletion genotype of hemoglobinopathy H (HbH or beta4) disease have higher proportions of HbH and more severe tissue hypoxia than patients with the deletion genotype. Because these patients' red blood cells (RBCs) contain mainly two Hb species, HbH and HbA, the high proportion of HbA can be exploited by lowering its oxygen affinity; this would probably increase oxygen delivery to the RBCs and improve the patients' clinical phenotype. Allosteric effectors that induce a low-affinity Hb may be useful in this regard. We investigated the effect of a bezafibrate derivative, RSR-4, on the oxygen affinity of RBCs and purified hemolysates containing HbA and HbH. This allosteric effector crosses RBC membranes and binds reversibly to the alpha-chains of deoxy-Hb, decreasing hemoglobin oxygen affinity. The blood used was obtained from a patient with HbH disease (alphaTSaudi homozygote) whose HbH level was 33.5% as measured by high-performance liquid chromatography. Oxygen binding studies were performed in RBCs and purified hemolysates. RBCs incubated in the presence of 500 microM RSR-4 (2-[[[(3,5-dichloroanilino)-carbonyl]methyl]phenoxy]-2-methylpropi onic acid) in standard conditions (pH 7.4, 0.14 M NaCl, 37 degrees C) displayed an increase in their P50 value from 14.5 to 35.2 mm Hg. Oxygen binding studies in purified stripped hemolysates (pH 7.2, 0.1 M NaCl, 25 degrees C) showed that addition of both 500 microM RSR-4 and 1 mM of 2,3 diphosphoglycerate (DPG) led to an 11-fold decrease in oxygen affinity, whereas the addition of the natural effector DPG or RSR-4 alone produced a 2.7- and 5.7-fold decrease, respectively. In both cases, the oxygen equilibrium curves (OECs) were biphasic due to the presence of the noncooperative, high-oxygen-affinity HbH (beta4) component. After addition of RSR-4, the lower part of the OEC (corresponding to HbH) was not shifted compared with the upper part (corresponding to HbA). These results were confirmed by kinetic studies of CO recombination. Both experiments demonstrated that RSR-4 does not affect beta4 Hb. Our findings provide an experimental model for lowering the oxygen affinity of HbA in HbH-containing cells and suggest that the oxygen delivery capability of the latter would be thereby improved.     

Functional heterogeneity of the alpha and beta subunits in the association reaction between hemoglobin and carbon monoxide

A technique is described for the rapid inactivation and removal of excess ferricyanide used for the non-cryogenic oxidation of the unliganded subunits of the intermediates in the association reaction between hemoglobin and carbon monoxide. Under these conditions the asymmetric oxidized intermediates, which dissociate into non-identical dimers, disproportionate into their parent tetramers and four species, Hb+, HbCO, alpha 2+ beta 2CO, alpha 2CO beta 2+, are isolated by non-cryogenic isoelectric focusing. The relative concentrations of species alpha 2CO beta 2+ and alpha 2+ beta 2CO measure the overall distribution of the ligand between the alpha and beta subunits in the association reaction. At 20 degrees C in 0.1 M KCl, pH 7, preferential CO binding to the beta subunits was observed, in agreement with observations made by the cryogenic technique for the isolation of the intermediates [M. Perrella, N. Davids and L. Rossi-Bernardi, J. Biol. Chem. 267 (1992) 8744].     

Carbon monoxide binding properties of hemoglobin M Iwate

The kinetic and equilibrium CO binding properties of hemoglobin (Hb) M Iwate (alpha2 87 His leads to Tyr beta2) have been investigated. The results show that the alpha(Met) beta2 (CO) tetramer of this protein has a low affinity for CO, as indicated by the stopped-flow and flash-photolysis kinetic, as well as the CO binding equilibrium, measurements. However, it has been found that the phosphate-free alpha2(Met)beta2(CO) tetramer does tend to dimerize extensively (K4.2 = 55 muM). The high-affinity forms seen in earlier kinetic measurements may be explained by this fact. When dimers are accounted for in the functional studies, the results show that the tetramer binds CO noncooperatively either with or without the allosteric cofactor, inositol hexaphosphate (IHP). IHP appears to influence the functional properties of a solution of Hb M Iwate by stabilizing the tetrameric state of aggregation, thereby greatly reducing the population of high-affinity dimers. When the CO "off" rate with IHP present (0.23 s-1) and the CO "on" rate to the tetramer either with or without IHP (1.9 X 10(5) M-1 s-1) at 25 degrees C are sued to calculate the equilibrium constant, the value obtained (8.3 X 10(5) M-1 s-1) is similar to that in equilibrium binding measurements on the phosphate-free tetramer (9.5 X 10(5) M-1) estimated from the observed P 1/2 value at 0.48 mM total heme concentration. By showing that dimers account for the high-affinity component seen in earlier kinetic experiments with Hg M Iwate, we can now more strongly suggest that cooperative CO binding to this tetramer is minimal or absent, with both of the active beta-hemes presenting a very low affinity.     

Isolation and partial characterization of elastase from dog granulocytes

Hemoglobin Hope (beta(H14)136gly leads to asp), a mildly unstable variant, was found to have decreased oxygen affinity, a normal Bohr effect and diminished cooperativity. Decreased oxygen affinity of hemoglobin Hope may explain the previous failure to find an appropriate response to hemolysis in individuals studied who were heterozygous for both hemoglobin Hope and sickle hemoglobin. Salt bridge formation between NA1 valine and H14 aspartic acid may stabilize the beta Hope subunit in its deoxy form thus producing intrinsically low oxygen affinity and reduced cooperativity.     

Significance of elevated hemoglobulin A1c for the pathogenesis of diabetic retinopathy

The hemoglobin of 70 diabetics with retinopathy was analysed. 56 patients had pathologically elevated values, 12 values were within the upper normal limit and in 2 cases the findings were normal. This hemoglobin variant is characterized by an increased affinity of oxygen. Clinically and pathologically speaking the elevated HbA1c value could be a causal factor in diabetic retinopathy. Comparisons with sickle cell anemia and thalassemia seem to indicate that hemoglobinopathy and retinopathy are pathogenetically related.     

Recombinant protein sequences can trigger methylation of N-terminal amino acids in Escherichia coli

Recombinant human hemoglobin rHb1.1 has been genetically engineered with the replacement of the wild-type valine residues at all N-termini with methionine, an Asn 108 Lys substitution on the beta globins, and a fusion of the two alpha globins with a glycine linker. When rHb1.1 was expressed in Escherichia coli, methylation of the N-terminal methionine of the alpha globin was discovered. Another mutant has been engineered with the alpha globin gene coding for N-terminal methionine followed by an insertion of alanine. Characterization of expressed hemoglobin from this variant revealed a methylated N-terminal alanine that occurred through two posttranslational events: initial excision of the N-terminal methionine, followed by methylation of alanine as the newly generated N-terminus. No methylation was observed for variants expressed with wild-type valine at the N-terminus of the alpha globin. The methylation of N-terminal amino acids was attributed to a specific protein sequence that can trigger methylation of proteins expressed in E. coli. Here we demonstrate that proline at position 4 in the protein sequence of alpha globin seems an essential part of that signaling. Although N-terminal methylation has been observed previously for native E. coli proteins with similar N-terminal sequences, methylation of the recombinant globins has allowed further delineation of the recognition sequence, and indicates that methylation of heterologous proteins can occur in E. coli.     

Location of a high affinity Zn2+ binding site in the channel of alpha1beta1 gamma-aminobutyric acidA receptors

Zn2+ inhibits currents through gamma-aminobutyric acid (GABA)A receptors. Its affinity depends on the subunit composition; alpha1beta1 receptors are inhibited with high affinity (IC50 = 0.54 micro M). We sought to identify the residues that form this high affinity Zn2+ binding site. beta1His267 aligns with alpha1Ser272, a residue near the extracellular end of the M2 membrane-spanning segment that we previously demonstrated to be exposed in the channel. The Zn2+ affinity of alpha1beta1 H267S was reduced by 300-fold (IC50 = 161 micro M). Addition of a histidine at the aligned position in alpha1 creates a receptor, alpha1S272Hbeta1, that should have five channel-lining histidines; the Zn2+ affinity was increased 20-fold (IC50 = 0.025 micro M). Shifting the position of the histidine from the beta1 subunit to the aligned position in alpha1 with the two mutants alpha1S272Hbeta1H267S reduced the affinity (IC50 = 26 micro M) compared with wild-type. We infer that the high affinity Zn2+ binding site involves beta1His267 from at least two subunits. For two histidines to interact with a Zn2+ ion, the alpha carbons must be separated by <13 A. This limits the separation of the subunits and provides a constraint on the possible quaternary structures of the channel. The ability of a divalent cation to penetrate from the extracellular end of the channel to beta1His267 implies that the charge-selectivity filter, the structure that discriminates between anions and cations, is located at a more cytoplasmic position than beta1His267; this is consistent with our previous work that showed that positively charged sulfhydryl-specific reagents reacted with an engineered cysteine residue as cytoplasmic as alpha1T261C.     

Thermodynamic studies on the equilibrium properties of a series of recombinant betaW37 hemoglobin mutants

In human hemoglobin (Hb) the beta37 tryptophan residue (betaW37), located at the hinge region of the alpha1beta2 interface, forms many contacts with alpha subunit residues of the opposite dimer, in both the T and R quaternary structures. We have carried out equilibrium O2 binding studies on a series of recombinant Hbs that have mutations at this residue site: betaW37Y, betaW37A, betaW37G, and betaW37E. Binding isotherms measured at high concentrations of these mutants were found to be shifted toward increased affinity and decreased cooperativity from that of the normal HbA0 tetramer. Analysis of these binding isotherms indicated that amino acid substitutions at the beta37 position could both destabilize the tetrameric form of the mutants relative to their constituent dimers and also alter cooperativity of the intact tetrameric species. These alterations from wild-type function are dependent on the particular side chain substituted, with the magnitude of change increasing as Trp is substituted by Tyr, Ala, Gly, and Glu. The dimer to tetramer assembly free energy of deoxy-betaW37E, the most perturbed mutant in the series, was measured using analytical gel chromatography to be 9 kcal/tetramer less favorable than that of deoxy HbA0. Stabilizing the betaW37E tetramer by addition of IHP, or by cross-linking at the alphaK99 positions, does not restore normal O2 binding behavior. Thermodynamic parameters of all the mutants were found to correlate with their CO binding rates and with their high-resolution X-ray crystal structures (see accompanying papers: Kwiatkowski et al. (1998) Biochemistry 37, 4325-4335; Peterson & Friedman (1998) Biochemistry 37, 4346-4357; Kavanaugh et al. (1998) Biochemistry 37, 4358-4373].     

Non-equivalence of human hemoglobin chains in the oxidation-reduction and heme-transfer reactions. A 13C nuclear-Magnetic-resonance study

12C nuclear magnetic resonance (NMR) spectroscopy has been applied to the investigation of chain non-equivalence for two reactions of human hemoglobin: oxidation-reduction and hemetransfer. The method is based on previous observations that in the carbonyl region, Hb13CO gives two well-resolved resonances which arise from 13C of carbonyls bound respectively to the alpha and beta chains; moreover, integration of spectra allows on e to estimate their relative abundance. A mixture of ferrous and ferric hemoglobins in dye-mediated oxidation-reduction equilibrium can be formally considered to be equivalent to two redox couples in equilibrium, namely alphaIII/alphaII and betaIII/betaII; from a knowledge of these ratios, one can conclude whether the chains are equivalent or not in their oxidation-reduction properties. In this work, these ratios were evaluated by reacting the redox systems with 13CO and integrating the 13C NMR spectra. The results show differences in the intrinsic oxidation-reduction potentials of the chains in hemoglobin tetramer, E1/2(beta)being higher than E1/2(alpha)in neutral solution but not at pH9 and above. The binding of inositol hexakisphosphate does not modify the difference between beta and alpha though substantially increasing the overall potential The results are discussed in the light of current hypotheses to account for the change of Hill coefficient with pH for the reaction studied. The non-equivalence of chains is shown also for heme transfer from methemoglobin. For the phosphate-free protein, the beta chains lose heme more rapidly than that alpha chains; the addition of inositol hexakisphosphate results in the decrease of overall heme transfer as well as of chain heterogeneity.     

Cocaine abuse counseling as HIV prevention

The synthesis and hemoglobin cross-linking studies of a novel organic reagent, bis[2-(4-carboxyphenoxy)carbonylethyl]phosphinic acid (BCCEP; 2) has been reported. The reagent was synthesized in four steps from hydroxybenzoic acid. The tri-sodium salt of BCCEP was employed to cross-link oxyHb, and the product was purified by DEAE-cellulose chromatography. The purified material was analyzed by SDS-PAGE, IEF, and HPLC analyses, which clearly showed the formation of covalent, intramolecular cross-links. While SDS-PAGE analyses of individual bands pointed to the molecular weight range of 32 kDa, the HPLC analyses suggested that the cross-links had formed between beta 1-beta 2 subunits. The oxygen equilibrium measurements and the Hill plots were performed on the purified bands to assess oxygen affinity as well as cooperativity of oxygen binding of the modified hemoglobins. All bands corresponding to modified hemoglobins showed significantly reduced oxygen affinity as compared with that of cell-free hemoglobin, as desired. The modified hemoglobins, however, exhibited somewhat reduced oxygen-binding cooperativity as contrasted with human stroma-free hemoglobin. Molecular dynamics simulation studies (Insight II/Discover/Biosym) on the Reagent-HbA0 complex suggested that the most likely amino acid residues involved in the cross-linking are Lys82 or N-terminal Val1 on one of the beta chains, and Lys144 on the other.     

The influence of beta subunit structure on the stability of Na+/K(+)-ATPase complexes and interaction with K+

Heterologous expression of the beta subunit of H+/K(+)-ATPase (HK beta) with alpha subunits of Na+/K(+)-ATPase (NK alpha) in yeast leads to the formation of ouabain binding complexes, indicating assembly of the two subunits into active ion pumps (Eakle, K. A., Kim, K. S., Kabalin, M. A., and Farley, R. A. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 2834-2838). Complexes of NK alpha and HK beta are less sensitive to inhibition of ouabain binding by K+, suggesting that HK beta lowers the affinity of K+ binding sites. This effect is particularly pronounced when HK beta is combined with the alpha 3 isoform of NK alpha. In this case, titration with K+ yields a biphasic curve, suggesting that there are two nonequivalent sites for K+ binding. Attempts at purifying complexes formed with either alpha 1 + HK beta or alpha 3 + HK beta using SDS extraction of microsomal membranes resulted in the loss of ouabain binding. Controls show that alpha 1 + beta 1 and alpha 3 + beta 1 complexes still retain ouabain binding after SDS extraction under the same conditions. This suggests that the HK beta subunit forms a less stable complex with NK alpha subunits. We have created chimeric beta subunits comprised of the amino-terminal cytoplasmic and transmembrane regions of HK beta combined with the carboxyl-terminal extracellular region of Na+/K(+)-ATPase beta 1 (HN beta 1) and the complementary chimera with amino-terminal cytoplasmic and transmembrane regions of beta 1 combined with the carboxyl-terminal extracellular region of HK beta (NH beta 1). When NH beta 1 is combined with either alpha 1 or alpha 3, the complexes show profiles of K+ inhibition of ouabain binding that are very similar to HK beta combined with either alpha 1 or alpha 3. The data suggest that the extracellular region of HK beta is primarily responsible for the effect on apparent K+ affinity. When the HN beta 1 subunit is expressed with the alpha 3 subunit, less than 5% of the amount of ouabain binding complexes are formed compared with HN beta 1 + alpha 1. This observation suggests that the HN beta 1 subunit either assembles poorly or forms an unstable complex with alpha 3. After SDS extraction, complexes of alpha 1 + NH beta 1 and alpha 3 + NH beta 1 retain ouabain binding, while alpha 1 + HN beta 1 complexes are sensitive to SDS extraction.(ABSTRACT TRUNCATED AT 400 WORDS)     

Residues at the subunit interfaces of the nicotinic acetylcholine receptor that contribute to alpha-conotoxin M1 binding

The two binding sites in the pentameric nicotinic acetylcholine receptor of subunit composition alpha2 beta gamma delta are formed by nonequivalent alpha-gamma and alpha-delta subunit interfaces, which produce site selectivity in the binding of agonists and antagonists. We show by sedimentation analysis that 125I-alpha-conotoxin M1 binds with high affinity to the alpha-delta subunit dimers, but not to alpha-gamma dimers, nor to alpha, gamma, and delta monomers, a finding consistent with alpha-conotoxin M1 selectivity for the alpha delta interface in the intact receptor measured by competition against alpha-bungarotoxin binding. We also extend previous identification of alpha-conotoxin M1 determinants in the gamma and delta subunits to the alpha subunit interface by mutagenesis of conserved residues in the alpha subunit. Most mutations of the alpha subunit affect affinity similarly at the two sites, but Tyr93Phe, Val188Lys, Tyr190Thr, Tyr198Thr, and Asp152Asn affect affinity in a site-selective manner. Mutant cycle analysis reveals only weak or no interactions between mutant alpha and non-alpha subunits, indicating that side chains of the alpha subunit do not interact with those of the gamma or delta subunits in stabilizing alpha-conotoxin M1. The overall findings suggest different binding configurations of alpha-conotoxin M1 at the alpha-delta and alpha-gamma binding interfaces.     

Association of hemoglobin Saint Etienne (alpha2beta295F8 His replaced by G1n) with hemoglobins A and F. Synthesis and subunit exchange in vitro

The unstable hemoglobin (Hb) Saint Etienne (alpha2beta295F8 His replaced by G1n) (betaSE) was found in the red blood cells of an 8-year-old boy. The composition of this hemoglobin was 26% Saint Etienne, 52% A, 3% A2 and 19% HbF. Studies of hemoglobin synthesis indicate: a) a balanced synthesis of alpha and non-alpha chains (alpha=betaA + betaSE + gamma), b) an increased pool of free alpha hemoglobin chains, and c) a rapid exchange of alpha chains between this pool and HbSE. The alpha chain pool resulted from the dissociation of HbSE and the greater instability of betaSE chains than alpha chains upon heating. Hemoglobin F is of the fetal type and is heterogeneously distributed among the red cells. Furthermore, two populations of red blood cells could be separated according to their i antigen content. Analysis of the hemoglobins revealed a heterogeneous distribution. Thus, F hemoglobin was preferentially associated with cells having low i antigen level, while Saint Etienne hemoglobin was increased in cells having a high i antigen level. HbF and HbSE were not present in the parents of the propositus. Study of the genetic markers confirmed the filiation. The parents were normal upon clinical and hematological examination; they exhibited a normal pattern and synthesis of hemoglobin. The Hb Saint Etienne case is compared with Hb Istanbul, which in spite of the same amino acid substitution is not associated with increased HbF level.     

Oxygen equilibrium properties of asymmetric nickel(II)-iron(II) hybrid hemoglobin

Asymmetric Ni(II)-Fe(II) hybrid hemoglobin, XL[alpha(Fe)beta(Fe)][alpha(Ni)beta(Ni)], in which the alpha 1 beta 1 dimer containing ferrous protoporphyrin IX and the complementary alpha 2 beta 2 dimer containing Ni(II) protoporphyrin IX were cross-linked between Lys-82 beta 1 and Lys-82 beta 2 by reaction with bis(3,5-dibromosalicyl) fumarate, was synthesized and characterized. We have previously shown that (i) Ni(II) protoporphyrin IX, which binds neither oxygen nor carbon monoxide, mimics a fixed deoxyheme with respect to its effect on the oxygen equilibrium properties of the counterpart iron subunits in both symmetric Ni(II)-Fe(II) hybrid Hbs [Shibayama, N., Morimoto, H., & Miyazaki, G. (1986) J. Mol. Biol. 192, 323-329] and (ii) the cross-linking used in this study little affects the oxygen equilibrium properties of hemoglobin [Shibayama, N., Imai, K., Hirata, H., Hiraiwa, H., Morimoto, H., & Saigo, S. (1991) Biochemistry 30, 8158-8165]. These remarkable features of our model allowed us to measure the oxygen equilibrium curves for the first two steps of oxygen binding to the alpha 1 beta 1 dimer within the hemoglobin tetramer. At all pH values examined, the affinities of this asymmetric hybrid for the first oxygen molecule are as low as those of native hemoglobin. The hybrid did not show cooperative oxygen binding at pH 6.4, while significant cooperativity was observed with rising pH; i.e., the Hill coefficient was increased from 1.41 to 1.53 upon a pH change from 7.4 to 8.4. The electronic absorption spectrum of Ni(II) protoporphyrin IX in the alpha 2 subunit was changed upon carbon monoxide (or oxygen) binding to the alpha 1 beta 1 dimer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Recombinant soluble human alpha 3 beta 1 integrin: purification, processing, regulation, and specific binding to laminin-5 and invasin in a mutually exclusive manner

Using insect cells, we expressed large quantities of soluble human integrin alpha 3 beta 1 ectodomain heterodimers, in which cytoplasmic and transmembrane domains were replaced by Fos and Jun dimerization motifs. In direct ligand binding assays, soluble alpha 3 beta 1 specifically bound to laminin-5 and laminin-10, but not to laminin-1, laminin-2, fibronectin, various collagens, nidogen, thrombospondin, or complement factors C3 and C3b. Soluble alpha 3 beta1 integrin also bound to invasin, a bacterial surface protein, that mediates entry of Yersinia species into the eukaryotic host cell. Invasin completely displaced laminin-5 from the alpha 3 beta 1 integrin, suggesting sterically overlapping or identical binding sites. In the presence of 2 mM Mg2+, alpha 3 beta 1's binding affinity for invasin (Kd = 3.1 nM) was substantially greater than its affinity for laminin-5 (Kd > 600 nM). Upon addition of 1 mM Mn2+, or activating antibody 9EG7, binding affinity for both laminin-5 and invasin increased by about 10-fold, whereas the affinity decreased upon addition of 2 mM Ca2+. Thus, functional regulation of the purified soluble integrin alpha 3 beta 1 ectodomain heterodimer resembles that of wild-type membrane-anchored beta 1 integrins. The integrin alpha 3 subunit was entirely cleaved into disulfide-linked heavy and light chains, at a newly defined cleavage site located C-terminal of a tetrabasic RRRR motif. Within the alpha 3 light chain, all potential N-glycosylation sites bear N-linked mannose-rich carbohydrate chains, suggesting an important structural role of these sugar residues in the stalk-like region of the integrin heterodimer. In conclusion, studies of our recombinant alpha 3 beta 1 integrin have provided new insights into alpha 3 beta1 structure, ligand binding function, specificity, and regulation.     

Alteration of an intersubunit contact in hemoglobin variants: comparative study of modifications at position alpha 126 Asp (H9)

Four human hemoglobin variants have already been described at position alpha 126 (H9), which is normally occupied by an aspartate: Hb Montefiore (-->Tyr), Hb Tarrant (-->Asn), Hb Fukutomi (-->Val), Hb Sassari (-->His). An additional variant, Hb West One (alpha 126 (H9) Asp-->Gly) is herein described. Aspartate alpha 126 (H9) is involved in a set of hydrogen bonds and salt bridges located at the C-terminal portion of the alpha-chains and of the C-helix of the beta-chains, which are broken in the oxy conformer, providing one of the most important sources of the difference in free energy between the T- and R-state in hemoglobin. A comparative study of four of these alpha 126 Hb variants is presented. An identical degree of alteration of the oxygen binding properties (increased oxygen affinity and decreased cooperativity) was found in all cases, when measured under standard experimental conditions (pH 7.2, 0.1 M NaCl). In contrast, the effect of L345 (a derivative of bezafibrate, which is a specific alpha-chain binding effector) on oxygen binding to Hb differed from one variant to another. When a bulky Tyr or His residue occupied the alpha 126 (H9) position, little effect of L345 was observed. Conversely, when this position was occupied by a residue of smaller size (Gly or Asn), normal heterotropic effects were observed. Molecular graphic modelling indicates that two classes of three-dimensional structure modifications may occur.     

Electron paramagnetic resonance and oxygen binding studies of alpha-Nitrosyl hemoglobin. A novel oxygen carrier having no-assisted allosteric functions

alpha-Nitrosyl hemoglobin, alpha(Fe-NO)2beta(Fe)2, which is frequently observed upon reaction of deoxy hemoglobin with limited quantities of NO in vitro as well as in vivo, has been synthetically prepared, and its reaction with O2 has been investigation by EPR and thermodynamic equilibrium measurements. alpha-Nitrosyl hemoglobin is relatively stable under aerobic conditions and undergoes reversible O2 binding at the heme sites of its beta-subunits. Its O2 binding is coupled to the structural/functional transition between T- (low affinity extreme) and R- (high affinity) states. This transition is linked to the reversible cleavage of the heme Fe-proximal His bonds in the alpha(Fe-NO) subunits and is sensitive to allosteric effectors, such as protons, 2,3-biphosphoglycerate, and inositol hexaphosphate. In fact, alpha(Fe-NO)2beta(Fe)2 is exceptionally sensitive to protons, as it exhibits a highly enhanced Bohr effect. The total Bohr effect of alpha-nitrosyl hemoglobin is comparable to that of normal hemoglobin, despite the fact that the oxygenation process involves only two ligation steps. All of these structural and functional evidences have been further confirmed by examining the reactivity of the sulfhydryl group of the Cysbeta93 toward 4, 4'-dipyridyl disulfide of several alpha-nitrosyl hemoglobin derivatives over a wide pH range, as a probe for quaternary structure. Despite the halved O2-carrying capacity, alpha-nitrosyl hemoglobin is fully functional (cooperative and allosterically sensitive) and could represent a versatile low affinity O2 carrier with improved features that could deliver O2 to tissues effectively even after NO is sequestered at the heme sites of the alpha-subunits. It is concluded that the NO bound to the heme sites of the alpha-subunits of hemoglobin acts as a negative allosteric effector of Hb and thus might play a role in O2/CO2 transport in the blood under physiological conditions.