Specific modification of the carboxyl groups of hemoglobin S

The reactivity of the carboxyl groups of hemoglobin S to form amide bonds with glycine ethyl ester by carbodiimide-activated coupling, and the influence of this derivatization on the functional properties of the protein have been investigated. Incubation of carbonmonoxy or oxyhemoglobin S with 20 mM 1-ethyl-3-(3'-dimethylaminopropyl)carbodiimide in the presence of 100 mM [14C]glycine ethyl ester, at pH 6.0 and 23 degrees C for 1 h resulted in the modification of, on an average, three carboxyl groups of the protein. The Hill coefficient of the modified hemoglobin S was 2.7, indicating normal subunit interactions. The derivatization increased the oxygen affinity of the molecule (the P50 was lowered from 8.0 to 5.0). The derivatization also resulted in an increase in the minimum gelling concentration of hemoglobin S from 16 to 24 g/100 ml. The reaction conditions used for the derivatization of the carboxyl groups of hemoglobin S are very selective for the protein carboxyl groups; very little of the label is associated with the heme carboxyls. Tryptic peptide mapping of the modified hemoglobin S indicated that the peptide beta T5, i.e. the segment representing amino acid residues 41 to 59 of beta-chain, accounted for nearly 75% of the label associated with the globin, demonstrating the high selectivity of the derivatization. Sequence analysis of the derivatized beta T5 demonstrated that at least 65% of the label incorporated into hemoglobin S is targeted toward the carboxyl group of Glu-43(beta), identifying it as the most reactive carboxyl group in hemoglobins. The results suggest that modification of the carboxyl group of hemoglobins S, presumably the gamma-carboxyl of Glu-43(beta), reduces the propensity of deoxyhemoglobin S to polymerize.     

Contribution of the gamma-carboxyl group of Glu-43(beta) to the alkaline Bohr effect of hemoglobin A.

Glu-43(beta) of hemoglobin A exhibits a high degree of chemical reactivity around neutral pH for amidation with nucleophiles in the presence of carbodiimide. Such a reactivity is unusual for the side-chain carboxyl groups of proteins. In addition, the reactivity of Glu-43(beta) is also sensitive to the ligation state of the protein [Rao, M. J., & Acharya, A. S. (1991) J. Protein Chem. 10, 129-138]. The influence of deoxygenation of hemoglobin A on the chemical reactivity of the gamma-carboxyl group of Glu-43(beta) has now been investigated as a function of pH (from 5.5 to 7.5). The chemical reactivity of Glu-43(beta) for amidation increases upon deoxygenation only when the modification reaction is carried out above pH 6.0. The pH-chemical reactivity profile of the amidation of hemoglobin A in the deoxy conformation reflects an apparent pKa of 7.0 for the gamma-carboxyl group of Glu-43(beta). This pKa is considerably higher than the pKa of 6.35 for the oxy conformation. The deoxy conformational transition mediated increase in the pKa of the gamma-carboxyl group of Glu-43(beta) implicates this carboxyl group as an alkaline Bohr group. The amidated derivative of hemoglobin A with 2 mol of glycine ethyl ester covalently bound to the protein was isolated by CM-cellulose chromatography.(ABSTRACT TRUNCATED AT 250 WORDS)     

Selective amidation of carboxyl groups of the intermolecular contact regions of hemoglobin S: Structural aspects

Carboxyl groups of HbS are readily activated by water-soluble carbodiimide atpH 6.0 and room temperature. These o-acylurea intermediates (activated carboxyl) are accessible for nucleophilic attack by amines. With glycine ethyl ester, the amidation is very selective for the -carboxyl of Glu-43() and more than 65% of the glycine ethyl ester incorporated is on this carboxyl group. In contrast, glucosamine derivatizes the -carboxyl group of Glu-22() as well as that of Glu-43() to nearly the same degree. However, the total amidation of HbS by glucosamine is lower than that with glycine ethyl ester. The differential selectivity of the two amines is apparently related to the differences in the microenvironment of the -carboxyl groups of Glu-22() and Glu-43(), which either facilitates or refracts the aminolysis of the activated carboxyl with the two amines to different degrees. The carboxyl groups of isolated -chain exhibit a higher reactivity for amidation with glycine ethyl ester than does the tetramer. The carboxyl groups of Glu-22() and Glu-43() and that of Asp-47() are all activated by carbodiimide suggesting that the higherpK_a of these carboxyl groups (facilitating the activation) is a property of tertiary interaction of the polypeptide chain. The interaction of the -chain with -chain, i.e., generation of the quaternary interactions, reduces overall reactivity of the carboxyl groups of the protein. The higher selectivity of hemoglobin S for amidation at Glu-43() with glycine ethyl ester compared with that of isolated -chain appears to be primarily a consequence of decreased amidation at sites other than at Glu-43().     

Reductive hydroxyethylation of the α-amino groups of amidated hemoglobin S

Val-6(β) of hemoglobin S forms the primary site of intertetrameric interaction in the polymerization of deoxy hemoglobin S. However, a number of other intermolecular interactions contribute significantly to the polymerization process as well as to the stability of the polymerized gel. The strong stabilizing influence of Val-6(β) in the polymerization process is reflected in the fact that although a number of mutations at any one of the intermolecular contact regions (or perturbation of these contact regions by chemical modification) result in some increase in the solubility of deoxy hemoglobin S, none of these mutations and/or chemical modifications completely neutralize the polymerizing influence of Val-6(β), i.e., restores the solubility to that of hemoglobin A. Additivity and/or synergy of the solubilizing influence of two or more chemical modification reactions each of which independently increases the solubility may be considered as a possible strategy to restore the solubility of deoxy hemoglobin S to that of hemoglobin A. In the present study, the cumulative solubilizing influence of amidation of Glu-43(β) and hydroxyethylation of α-amino groups of hemoglobin S has been investigated by preparing hemoglobin S with double modification. Modification of Glu-43(β) by amidation with glycine ethyl ester did not influence the reactivity of the α-amino groups of hemoglobin S toward reductive hydroxyethylation, thus permitting the preparation of hemoglobin S with the two modifications. The reductive hydroxyethylation increased the oxygen affinity of amidated hemoglobin S to nearly the same degree as it does on modification of unmodified hemoglobin. In addition, hemoglobin S with double modification has a Hill coefficient that is the same as that of unmodified hemoglobin S, suggesting that the overall quaternary interaction of hemoglobin S with a double modification is nearly the same as the unmodified protein. However, the reductive hydroxyethylation of the amidated hemoglobin S increased the solubility of the protein further. The solubility of hemoglobin S with a double modification is nearly twice that of the unmodified protein and is close to that of 1:1 mixture of hemoglobin S and hemoglobin F. The results demonstrate the additivity of the solubilizing influence of perturbing the quinary interactions at the intermolecular contact regions of deoxy hemoglobin S.     

Basic carboxyl groups of hemoglobin S: Influence of oxy-deoxy conformation on the chemical reactivity of Glu-43(β)

The -carboxyl groups of Glu-43() and Glu-22() of hemoglobin-S (HbS), two intermolecular contact residues of deoxy protein, are activated by carbodiimide atp H 6.0. The selectivity of the modification by the two nucleophiles, glycine ethyl ester (GEE) and glucosamine, is distinct. Influence ofN-hydroxysulfosuccinimide, a reagent that rescues carbodiimide-activated carboxyl (O-acyl isourea) as sulfo-NHS ester, on the overall selectivity and efficiency of the coupling of Glu-22() and Glu-43() with nucleophiles has been investigated. Sulfo-NHS increases the extent of coupling of nucleophiles to HbS. The rescuing efficiency of sulfo-NHS(increase in modification) with GEE and galactosamine as nucleophiles is 2.0 and 2.8, respectively. In the presence of sulfo-NHS, the extent of modification of a carboxyl group is a direct reflection of the extent to which it is activated (i.e., the protonation state of the carboxyl group). The modification reaction exhibits very high selectivity for Glu-43() with GEE and galactosamine (GA) in the presence of sulfo-NHS. From the studies of the kinetics of amidation of oxy-HbS at its Glu-43() (i.e., chemical reactivity) as a function of thepH in the region of 5.5–7.5, the apparentpKa of its -carboxyl group has been calculated to be 6.35. Deoxygenation of HbS, nearly doubles the chemical reactivity of Glu-43() of HbS atpH 7.0. It is suggested that the increased hydrophobicity of the microenvironment of Glu-43(), which occurs on deoxygenation of the protein, is reflected as the increased chemical reactivity of the -carboxyl group and could be one of the crucial preludes to the polymerization process.     

X-ray and functional studies of hemoglobins Nancy and Cochin-Port-Royal.

The mutations in hemoglobin Nancy beta145(HC2) Tyr leads to Asp and hemoglobin Cochin-Portal-Royal beta146(HC3) His leads to Arg involve residues which are thought to be essential for the full expression of allosteric action in hemoglobin. Relative to the structure of deoxyhemoglobin A, our x-ray study of deoxyhemoglobin Nancy shows severe disordering of the beta chain COOH-terminal tetrapeptide and a possible movement of the beta heme iron atom toward the plane of the porphyrin ring. These structural perturbations result in a high oxygen affinity, reduced Bohr effect, and lack of cooperatively in hemoglobin Nancy. In the presence of inositol hexaphosphate (IHP), the Hill constant for hemoglobin Nancy increases from 1.1 to 2.0. But relative to its action on hemoglobin A, IHP is much less effective in reducing the oxygen affinity and in increasing the Bohr effect of hemoglobin Nancy. This indicates that IHP does not influence the R in equilibrium T equilibrium as much in hemoglobin Nancy as in hemoglobin A, and this probably is due to the disordering of His 143beta which is known to be part of the IHP binding site. IHP is also known to produce large changes in the absorption spectrum of methemoglobin A, but we find that it has no effect on the spectrum of methemoglobin Nancy. In contrast to the large structural changes in deoxyhemoglobin Nancy, the structure of deoxyhemoglobin Cochin-Port-Royal differs from deoxyhemoglobin A only in the position of the side chain of residue 146beta. The intrasubunit salt bridge between His 146beta and Asp 94beta in deoxyhemoglobin A is lost in deoxyhemoglobin Cochin-Portal-Royal with the guanidinium ion of Arg 146beta floating freely in solution. This small difference in structure results in a reduced Bohr effect, but does not cause a change in the Hill coefficient, the response to 2,3-diphosphoglycerate, or the oxygen affinity at physiological pH.     

Specifically carboxymethylated hemoglobin as an analogue of carbamino hemoglobin. Solution and X-ray studies of carboxymethylated hemoglobin and X-ray studies of carbamino hemoglobin

Hemoglobin can be specifically carboxymethylated at its NH2-terminal amino groups (i.e. HbNHCH2COO-) to form the derivatives alpha 2Cm beta 2, alpha 2 beta 2Cm, and alpha 2Cm beta 2Cm, where Cm represents carboxymethyl. Previous studies (DiDonato, A., Fantl, W. J., Acharya, A. S., and Manning, J. M. (1983) J. Biol. Chem. 258, 11890-11895) suggested that these derivatives could be used as stable analogues of the corresponding carbamino (Hb-NHCOO-) forms of hemoglobin, adducts that are generated reversibly in vivo when CO2 combines with alpha-amino groups. In this paper we present x-ray diffraction studies of both carbamino hemoglobin and carboxymethylated hemoglobin that verify this proposal and we use the carboxymethylated derivatives to study the functional consequences of placing a covalently bound carboxyl group at the NH2 terminus of each hemoglobin subunit. Our studies also provide additional information concerning the oxygen-linked binding of anions and protons to Val-1 alpha. Difference electron density analysis of deoxy alpha 2Cm beta 2Cm versus the unmodified deoxyhemoglobin tetramer (deoxy alpha 2 beta 2) shows that the covalently bound carboxyl moieties replace inorganic anions that are normally bound to the free NH2-terminal amino groups in crystals of native deoxyhemoglobin grown from solutions of concentrated (2.3 M) ammonium sulfate. In the case of the beta-subunits, the carboxymethyl group replaces an inorganic anion normally bound between the alpha-amino group of Val-1 beta, the epsilon-amino group of Lys-82 beta, and backbone NH groups at the NH2-terminal end of the F'-helix. In the case of the alpha-subunits, the carboxymethyl group replaces an anion that is normally bound between the alpha-amino group of Val-1 alpha and the beta-OH group of Ser-131 alpha. A corresponding difference electron map of carbamino deoxyhemoglobin in low-salt (50 mM KCl) crystals shows that CO2 bound in the form of carbamate occupies the same two anion binding sites. The alkaline Bohr effect of alpha 2Cm beta 2 is only marginally lower (approximately 7%) than that of alpha 2 beta 2. Previous studies (Kilmartin, J. V., 1977) have shown that about 30% of the alkaline Bohr effect is the result of an oxygen-linked change in the pK alpha of Val-1 alpha, and O'Donnell et al., 1979, found that this portion of the Bohr effect is the result of the oxygen-linked binding of chloride to Val-1 alpha.(ABSTRACT TRUNCATED AT 400 WORDS)     

The interaction of hemoglobin with the cytoplasmic domain of band 3 of the human erythrocyte membrane

Previous studies point to the acidic amino-terminal segment of band 3, the anion transport protein of the red cell, as the common binding site for hemoglobin and several of the glycolytic enzymes to the erythrocyte membrane. We now report on the interaction of hemoglobin with the synthetic peptide AcM-E-E-L-Q-D-D-Y-E-D-E, corresponding to the first 11 residues of band 3, and with the entire 43,000-Da cytoplasmic domain of the protein. In the presence of increasing concentrations of the peptide, the oxygen binding curve for hemoglobin is shifted progressively to the right, indicating that the peptide binds preferentially to deoxyhemoglobin. The dissociation constant for the deoxyhemoglobin-peptide complex at pH 7.2 in the presence of 100 mM NaCl is 0.31 mM. X-ray crystallographic studies were carried out to determine the exact mode of binding of the peptide to deoxyhemoglobin. The difference electron density map of the deoxyhemoglobin-peptide complex at 5 A resolution showed that the binding site extends deep (approximately 18 A) into the central cavity between the beta chains, along the dyad symmetry axis, and includes Arg 104 beta 1 and Arg 104 beta 2 as well as most of the basic residues within the 2,3-diphosphoglycerate binding site. The peptide appears to have an extended conformation with only 5 to 7 of the 11 residues in contact with hemoglobin. In agreement with the crystallographic studies, binding of the peptide to deoxyhemoglobin was blocked by cross-linking the beta chains at the entrance to the central cavity. Oxygen equilibrium studies showed that the isolated cytoplasmic fragment of band 3 also binds preferentially to deoxyhemoglobin. The binding of the 43,000-Da fragment to hemoglobin was inhibited in the cross-linked derivative indicating that the acidic amino-terminal residues in the intact cytoplasmic domain also bind within the central cavity of the hemoglobin tetramer.     

Biosynthesis of heparin. O-sulfation of the antithrombin-binding region

The antithrombin-binding region in heparin is a pentasaccharide sequence with the predominant structure GlcNAc(6-OSO3)-GlcA-GlcNSO3(3,6-di-OSO3)-IdoA -(2-OSO3)-GlcNSO3(6-OSO3) (where GlcA and IdoA represent D-glucuronic and L-iduronic acid, respectively), in which the 3-O-sulfate residue on the internal glucosaminyl unit is a marker group for this particular region of the polysaccharide molecule. A heparin octasaccharide which contained the above pentasaccharide sequence was N/O-desulfated and re-N-sulfated and was then incubated with adenosine 3'-phosphate 5'-phospho[35S]sulfate in the presence of a microsomal fraction from mouse mastocytoma tissue. Fractionation of the resulting 35S-labeled octasaccharide on antithrombin-Sepharose yielded a high affinity fraction that accounted for approximately 2% of the total incorporated label. Structural analysis of this fraction indicated that the internal glucosamine unit of the pentasaccharide sequence was 3-O-35S-sulfated, whereas both adjacent glucosamine units carried 6-O-[35S]sulfate groups. In contrast, the fractions with low affinity for antithrombin (approximately 98% of incorporated 35S) showed no consistent O-35S sulfation pattern and essentially lacked glucosaminyl 3-O-[35S]sulfate groups. It is suggested that the 3-O-sulfation reaction concludes the formation of the antithrombin-binding region. This proposal was corroborated in a similar experiment using a synthetic pentasaccharide with the structure GlcNSO3(6-OSO3)-GlcA-GlcNSO3(6-OSO3)-Id oA (2-OSO3)-GlcNSO3(6-OSO3) as sulfate acceptor. This molecule corresponds to a functional antithrombin-binding region but for the lack of a 3-O-sulfate group at the internal glucosamine unit. The 35S-labeled pentasaccharide recovered after incubation bound with high affinity to antithrombin-Sepharose and contained a 3-O-[35S]sulfate group at the internal glucosamine residue as the only detectable labeled component. The use of this pentasaccharide substrate along with the affinity matrix provides a highly specific assay for the 3-O-sulfotransferase.     

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

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

Carboxyl methylation of cytosolic proteins in intact human erythrocytes. Identification of numerous methyl-accepting proteins including hemoglobin and carbonic anhydrase

Intact human erythrocytes incubated with L-[methyl-3H]methionine incorporated radioactivity into base-labile linkages with membrane and cytosolic proteins which are characteristic of protein methyl esters. Kinetic analysis of the methylation reactions in intact cells shows that individual erythrocytes contain approximately 38,000 and 115,000 protein methyl esters with biological half-lives of 150 min or less in the membrane and cytosolic protein fractions, respectively. Fractionation of the methylated cytosolic species by gel filtration chromatography at pH 6.5 followed by sodium dodecyl sulfate-gel electrophoresis at pH 2.4 reveals that many different cytosolic proteins serve as methyl acceptors and that the degree of modification varies widely for individual proteins. For example, hemoglobin is modified to the extent of 3 methyl groups/10(6) polypeptide chains, while carbonic anhydrase contains 1 methyl group/approximately 16,500 polypeptide chains at steady state. Aspartic acid beta-[3H]methyl ester (Asp beta-[3H]Me) can be isolated from carboxypeptidase Y digests of cytosol proteins. By synthesizing and separating diastereomeric L-Leu-L-Asp beta Me and L-Leu-D-Asp beta Me dipeptides, we show that all of the Asp beta-[3H]Me recovered from cytosolic proteins is in the D-stereoconfiguration. Based on these data and on previous observations that erythrocytes contain a single methyltransferase which also methylates red cell membrane proteins at D-aspartyl residues both in vivo (McFadden, P. N., and Clarke, S. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 2460-2464) and in vitro (O'Connor, C. M., and Clarke, S. (1983) J. Biol. Chem. 258, 8485-8492), we propose that protein carboxyl methylation is part of a generalized mechanism for metabolizing damaged proteins. The infrequent and spontaneous occurrence of D-aspartyl residues in proteins adequately explains the broad substrate specificity and limited stoichiometries of protein carboxyl methylation reactions.     

Assembly properties of tubulin after carboxyl group modification

By chemically modifying carboxyl groups we have investigated the role of the highly acidic COOH-terminal domains of alpha- and beta-tubulin in regulating microtubule assembly. Using a carbodiimide-promoted amidation reaction, as many as 25 carboxyl groups were modified by the addition of 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide and an amine nucleophile, [14C] glycine ethyl ester or [3H]methylamine, to assembled microtubules. Modification occurred primarily in the carboxyl-terminal region as demonstrated by limited proteolysis of modified tubulin by trypsin, chymotrypsin, subtilisin, and carboxypeptidase Y. Modified tubulin polymerized into microtubules with a critical concentration that was 15% of that for unmodified tubulin. Assembly of modified tubulin and microtubules formed from modified tubulin were less sensitive to Ca2+ and high ionic strength. Ca2+ binding studies under low ionic strength conditions indicated that modified tubulin does not contain the high affinity Ca2+ binding site. While assembly of unmodified tubulin was stimulated by Mg2+ up to 10 mM, assembly of the modified protein was inhibited by concentrations greater than 1 mM. When 24 residues were modified, polymerization was no longer stimulated by microtubule-associated proteins (MAPs) or polylysine and incorporation of high molecular weight MAPs into the polymers was reduced by about 70% compared to unmodified tubulin. These studies demonstrate that chemical modification of carboxyl groups in tubulin, most of which are localized in the COOH-terminal region, leads to an enhanced ability to polymerize and a decrease in interaction with MAPs and other positively charged species.     

Inhibition of the gelation of extracellular and intracellular hemoglobin S by selective acetylation with methyl acetyl phosphate

Methyl acetyl phosphate binds to the 2,3-diphosphoglycerate (2,3-DPG) binding site of hemoglobin and selectively acetylates three amino groups at or near that site. The subsequent binding of 2,3-DPG is thus impeded. When intact sickle cells are exposed to methyl acetyl phosphate, their abnormally high density under anaerobic conditions is reduced to the density range of oxygenated, nonsickling erythrocytes. This change is probably due to a combination of direct and indirect effects induced by the specific acetylation. The direct effect is on the solubility of deoxyhemoglobin S, which is increased from 17 g/dL for unmodified hemoglobin S to 22 g/dL for acetylated hemoglobin S at pH 6.8. Acetylated hemoglobin S does not gel at pH 7.4, up to a concentration of 32 g/dL. The indirect effect could be due to the decreased binding of 2,3-DPG to deoxyhemoglobin S within the sickle erythrocyte, thus hindering the conversion of oxyhemoglobin S to the gelling form, deoxyhemoglobin S.     

Modification of human hemoglobin by glutathione. III. Perturbations of hemoglobin conformation analyzed by computer modeling

The perturbations of the conformation of human deoxyhemoglobin induced by the covalent attachment of glutathione at cysteine beta 93 have been investigated by computer simulation in conjunction with molecular graphics. In the first phase of the analysis, a systematic search was carried out of the conformational space of glutathione attached to deoxyhemoglobin. In this search, the conformation of the hemoglobin molecule was held constant, while the relative energies of a series of 186,624 glutathione conformations involving systematic variation of six dihedral angels were calculated. From this search, the most favorable conformation was selected as the starting conformation for energy minimization of the glutathionyl hemoglobin molecule as a function of all Cartesian coordinates. In order to provide a reference state, an independent minimization by the same procedures was carried out for deoxyhemoglobin in the absence of glutathione. Comparison of the minimized structures with and without glutathione attached revealed a number of significant differences. The most conspicuous difference in the protein moiety concerned the salt bridge between aspartate beta 94 and histidine beta 146 which is destabilized upon minimization of the glutathionyl-hemoglobin complex due to interactions of the aspartate residue with the glycyl NH group of glutathione. Other observed differences in the minimized structures are located at the alpha 1-beta 2 interface and include displacement of the carboxyl group of aspartate beta 99. In the minimized complex, the glutathione portion assumes a quasi-cyclic conformation stabilized through interactions between the free (gamma-glutamyl) amino and (glycyl) carboxyl ends of the tripeptide and between this carboxyl end and the epsilon amino group of lysine alpha 40. In a parallel conformational study of glutathione alone, a similar structure was found as the lowest energy form. These quasi-cyclic conformations contrast with the extended structures reported by Wright (Wright, W.B. (1955) Acta Crystallogr. 11, 632-642) for crystals of glutathione where interactions between molecules play a major role. The conclusions of our analysis are in agreement with the experimental investigations reported in the two preceding papers and permit, moreover, a coherent interpretation of the observed functional and structural changes in deoxyhemoglobin induced by glutathione.     

The structure of hemoglobin Creteil (beta 89 Ser replaced by Asn) is similar to that of abnormal human hemoglobins having sequence changes at Tyr 145 beta

In normal deoxyhemoglobin A, the beta chain COOH-terminal peptide adopts a well ordered structure which is needed for the full expression of allosteric action. Our crystallographic studies of deoxyhemoglobin Creteil (beta 89 Ser replaced by Asn), a variant hemoglobin characterized by high oxygen affinity and a very low level of allosteric function, show that replacement of Ser 89 beta by asparagine causes severe disordering of the beta chain COOH-terminal tetrapeptide. This results, as shown by our spectroscopic studies, in the destabilization of the quaternary structure of deoxyhemoglobin Creteil. We find, furthermore, that the changes in tertiary structure observed in deoxyhemoglobin Creteil are common to other variant hemoglobins having similar functional abnormalities but very different changes in primary structure. In particular, direct comparison of the difference electron density map of deoxyhemoglobin Creteil with that of deoxyhemoglobin Nancy (beta 145 Tyr replaced by Asp) suggests that these two abnormal hemoglobins may have the same mechanism of dysfunction despite the very different nature of their respective sequence changes.     

Influence of ligation state and concentration of hemoglobin A on its cross-linking by glycolaldehyde: functional properties of cross-linked, carboxymethylated hemoglobin

The ligation state of hemoglobin during its cross-linking by glycolaldehyde influences the ultimate oxygen affinity of the cross-linked protein. Thus, if the cross-linking is performed with carbonmonoxy-hemoglobin, the oxygen affinity increases slightly to a P50 of 7 mmHg from a P50 of 9 mmHg for unmodified hemoglobin. In contrast, when deoxyhemoglobin is cross-linked with glycolaldehyde, the oxygen affinity of the product decreases (P50 = 15 mmHg). When deoxyhemoglobin is first carboxymethylated and then cross-linked with glycolaldehyde, an even lower oxygen affinity is achieved (P50 = 23 mmHg). Carboxymethylated hemoglobin is very responsive to the presence of 5% CO2 with a P50 of 33 mmHg, which is lowered further to 42 mmHg when chloride (0.1 M) is also present. Hemoglobin carboxymethylated and cross-linked under anaerobic conditions is also responsive to the modulators CO2 and chloride with a resultant oxygen affinity of 27 mmHg. The type of cross-linking of liganded hemoglobin by the mild reagent glycolaldehyde is dependent upon the initial hemoglobin concentration. Thus, with dilute hemoglobin (45 microM in tetramer), cross-linking by glycolaldehyde (50 mM) results in about 75% of 64,000 molecular weight species (some of which are cross-linked within tetramer) and 25% of intertetrameric cross-linked species with a range of molecular weights averaging 128,000-512,000. With hemoglobin solutions of higher concentration (360 microM), the amount of the higher molecular weight species increases to about 65% with a corresponding reduction to 35% in the 64,000 molecular weight component.     

Solvent regulation of oxygen affinity in hemoglobin. Sensitivity of bovine hemoglobin to chloride ions

Under physiological conditions of pH (7.4) and chloride concentration (0.15 M), the oxygen affinity of bovine hemoglobin is substantially lower than that of human hemoglobin. Also, the Bohr effect is much more pronounced in bovine hemoglobin. Numerical simulations indicate that both phenomena can be explained by a larger preferential binding of chloride ions to deoxyhemoglobin in the bovine system. Also, they show that the larger preferential binding may be produced by a decreased affinity of the anions for oxyhemoglobin, thereby stressing the potential relevance of the oxy conformation in regulating the functional properties of the protein. The conformation of the amino-terminal end of the beta subunits appears to regulate the interaction of hemoglobin with solvent components. The pronounced sensitivity of the oxygen affinity of bovine hemoglobin to chloride concentration and to pH suggests that in bovine species these are the modulators of oxygen transport in vivo.     

Refined crystal structure of deoxyhemoglobin S. II. Molecular interactions in the crystal

The refined crystal structure of deoxyhemoglobin S (Padlan, E. A., and Love, W. E. (1985) J. Biol. Chem. 260, 8272-8279) was used to analyze in detail the molecular interactions between hemoglobin tetramers in the crystal. The analysis confirms the close similarity and also the nonequivalence of the molecular interactions involving the two independent tetramers in the asymmetric unit of the crystal. The residue at the site of the hemoglobin S mutation, beta 6, is intimately involved in the lateral contacts between adjacent molecules. The molecular contacts in the crystals of deoxyhemoglobin S, deoxyhemoglobin A, and deoxyhemoglobin F were compared; some contacts involve the same regions of the molecule although the details of the interactions are very different. The effect of introducing an R state tetramer into the deoxyhemoglobin S strands was investigated using the known structure of carbon monoxyhemoglobin A. It was found that substituting a molecule of carbon monoxyhemoglobin A for one of the deoxyhemoglobin S tetramers results in extensive molecular interpenetration.     

Permissible discontinuity region of the alpha-chain of hemoglobin: noncovalent interaction of heme and the complementary fragments alpha 1-30 and alpha 31-141

Generation of a fragment-complementing system of the alpha-chain on limited proteolysis with Staphylococcus aureus V8 protease has been investigated. Digestion of the alpha-chain (0.4 mM) of hemoglobin with V8 protease in phosphate buffer at pH 6.0 and 37 degrees C is limited to the peptide bonds of Glu-23, Glu-27, Glu-30, and Asp-47. Gel filtration of a V8 protease digest of the alpha-chain on a Sephadex G-50 column did not release any heme to the low molecular weight region, though some peptides were released from the protein. The filtration studies revealed the presence of two heme-containing components in the digest, the major one eluting at the alpha-chain position and the minor one eluting slightly ahead of the alpha-chain position. Reversed-phase high-performance liquid chromatography and amino-terminal sequence analysis demonstrated that the component eluting at the alpha-chain position contains species generated by the noncovalent interactions of heme and the complementary fragments alpha 1-30 and alpha 31-141. In dilute solutions (0.04 mM) the V8 protease digestion occurred exclusively on the carboxyl side of Glu-30(alpha). This high selectivity was also observed at pH 4.0 and pH 7.8. The visible spectra and the ultraviolet circular dichroic spectra of the digest reflect the native-like structure of the noncovalent fragment system. The dissociation constant of alpha 1-30 appears to be in the range of 10(-8) M. In tetrameric hemoglobin A the peptide bond of Glu-30-Arg-31 of the alpha-chain is not accessible to V8 protease digestion.(ABSTRACT TRUNCATED AT 250 WORDS)