Reactivity of Glu-22(beta) of hemoglobin S for amidation with glucosamine

X-ray diffraction analysis of deoxyhemoglobin S crystals has implicated that a number of carboxyl groups of the protein are present at or near the intermolecular contact regions. The reactivity of these or other carboxyl groups of hemoglobin S for the amidation with an amino sugar, i.e., glucosamine, and the influence of amidation on the oxygen affinity and polymerization have been investigated. Reaction of oxyhemoglobin S at pH 6.0 and 23 degrees C with 20 mM 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC) and 100 mM [3H]glucosamine for 1 h resulted in an incorporation of nearly two residues of glucosamine per tetramer. The amidation was very specific for the carboxyl groups of globin; the glucosamine was not incorporated into the heme carboxyls. Derivatization of hemoglobin S by glucosamine increased the O2 affinity of the protein but had no influence on either the Hill coefficient or the Bohr effect. Amidation by glucosamine also increased the solubility of deoxyhemoglobin S by about 55%. Tryptic peptide mapping of the modified hemoglobin S indicated that the peptides beta-T3 and beta-T5 contained the glucosamine incorporated into the protein. Sequence analysis of glucosamine-modified beta-T3 and beta-T5 demonstrated that the gamma-carboxyl groups of Glu-22 and Glu-43, respectively, had been derivatized with glucosamine. The residue Glu-43(beta) shows a high selectivity toward glycine ethyl ester also, whereas Glu-22(beta) is not reactive toward this amine.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

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.     

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().     

Assessment of role of beta 146-histidyl and other histidyl residues in the Bohr effect of human normal adult hemoglobin

The contribution of the carboxyl-terminal histidines of the beta chains, beta 146(HC3), to the alkaline Bohr effect of human normal adult hemoglobin has been shown by this laboratory to depend upon the solvent composition. Using high-resolution proton nuclear magnetic resonance spectroscopy, we have found that the pKa value of the beta 146-histidine is 8.0 in the deoxy form, while in the carbonmonoxy form it ranges from 7.1 to 7.85 depending upon the concentration of inorganic phosphate and chloride ions present. These conclusions have been questioned by Perutz and co-workers on the basis of biochemical, structural, and proton nuclear magnetic resonance studies of mutant and enzymatically or chemically modified hemoglobins [Perutz, M. F., Kilmartin, J. V., Nishikura, K., Fogg, J. H., Butler, P. J., & Rollema, H. S. (1980) J. Mol. Biol. 138, 649-670; Kilmartin, J. V., Fogg, J. H., & Perutz, M. F. (1980) Biochemistry 19, 3189-3193; Perutz, M. F., Gronenborn, A. M., Clore, G. M., Fogg, J. H., & Shih, D. T.-b. (1985) J. Mol. Biol. 183, 491-498]. In this work, we use proton nuclear magnetic resonance spectroscopy to assess the effects of structural modifications on the histidyl residues and on the overall conformation of the hemoglobin molecule in solution. The structural perturbations investigated all occur within the tertiary domains around the carboxyl-terminal region of the beta chain as follows: Hb Cowtown (beta 146His----Leu); Hb Wood (beta 97His----Leu); Hb Malm? (beta 97His----Gln); Hb Abruzzo (beta 143His----Arg). Our results demonstrate that the conformational effects of single-site structural modifications upon the conformation and dynamics of hemoglobin depend strongly on their location in the three-dimensional structure of the protein molecule and also on their chemical nature. Furthermore, in normal hemoglobin, the spectral properties of several surface histidyl residues are found to depend, in the ligated state, upon the nature of the ligand. Our present findings do not support the recent spectral assignments proposed by Perutz et al. (1985) for the proton resonances of the beta 146- and beta 97-histidines and their suggestion that the enzymatic removal of the carboxyl-terminal beta 146-histidyl residues induces a conformational equilibrium for the beta 97-histidines in the des-beta 146His hemoglobin molecule in the carbonmonoxy form.     

Reactivity of cyanate with valine-1 (alpha) of hemoglobin. A probe of conformational change and anion binding.

The 3-fold increase in the carbamylation rate of Val-1 (alpha) of hemoglobin upon deoxygenation described earlier is now shown to be a sensitive probe of conformational change. Thus, whereas this residue in methemoglobin A is carbamylated at the same rate as in liganded hemoglobin, upon addition of inositol hexaphosphate its carbamylation rate is enhanced 30% as much as the total change in the rate between the CO and deoxy states. For CO-hemoglobin Kansas in the presence of the organic phosphate, the relative increase in the carbamylation rate of this residue is about 50%. These results indicate that methemoglobin A and hemoglobin Kansas in the presence of inositol hexaphosphate do not assume a conformation identical with deoxyhemoglobin but rather form either a mixture of R and T states or an intermediate conformation in the region around Val-1 (alpha). Studies on the mechanism for the rate enhancement in deoxyhemoglobin suggest that the cyanate anion binds to groups in the vicinity of Val-1 (alpha) prior to proton transfer and carbamylation of this NH2-terminal residue. Thus, specific removal with carboxypeptidase B of Arg-141 (alpha), which is close to Val-1 (alpha) in deoxyhemoglobin, abolishes the enhancement in carbamylation. Chloride, which has the same valency as cyanate, is a better competitive inhibitor of the carbamylation of deoxyhemoglobin (Ki = 50 mM) compared with liganded hemoglobin. Nitrate and iodide are also effective inhibitors of the carbamylation of Val-1 (alpha) of deoxyhemoglobin (Ki = 35 mM); inorganic phosphate, sulfate, and fluoride are poor competitive inhibitors. The change in pKa of Val-1 (alpha) upon deoxygenation may be due to its differential interaction with chloride.     

Quantitative determination of carbamino adducts of alpha and beta chains in human adult hemoglobin in presence and absence of carbon monoxide and 2,3-diphosphoglycerate.

The principal component of normal adult human hemoglobin was equilibrated under various conditions with 13CO2. Quantitative analysis of the carbamino resonance intensities over the pH range of 6.5 to 9.0 shows that the effects of conversion from the deoxy to the liganded state in reducing the carbamino adduct formation occur predominantly at Val-1beta. Analysis of the pH dependence of carbamino formation at constant total carbonates yields values of pKz and pKc for Val-1beta and Val-1alpha in the deoxy and liganded conditions. In contrast to the Val-1beta as the allosteric site for CO2, the Val-1alpha site is shown to be primarily an alkaline Bohr group. 2,3-Diphosphoglycerate is shown to reduce substantially the Val-1beta carbamino resonance intensity in deoxyhemoglobin. Evidence for 2,3-diphosphoglycerate effects in carbon monoxide hemoglobin at both Val-1alpha and Val-1beta sites is presented. Enhanced carbamino formation in carbon monoxide hemoglobin at Val-1beta is observed at pH values less than 7.8. Finally, chemical exchange analysis of the spectra shows the release rate of the deoxy Val-1alpha carbamino adduct to be greater than that for deoxy Val-1beta. At pH 7.47 k-1obs,beta congruent to 1.0 and k-1obs, alpha congruent to 11.0 s-1.     

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)     

Ionizable groups linked to the reaction of 2,2'-dithiobispyridine with hemoglobin.

The pH-dependence of the second-order rate-constant for the reaction of 2,2'-dithiobispyridine with the CysF9(93) beta sulphydryl group of hemoglobin in the R quaternary structure is analyzed in terms of a tentative model based on the observation that this sulphydryl exists as a mixture of two tertiary conformations in dynamic equilibrium. For the four aquomethemoglobins studied (human A and S, dog and rabbit), the equation derived from this model gives a better fit than a simpler equation based on the assumption of only one tertiary conformation. For the corresponding carbonmonoxyhemoglobins the simpler equation gives a better fit. The dog and rabbit oxy and azidomet data are better fitted by the model equation, whereas the data for the corresponding human A and S derivatives are better fitted by the simpler equation. From the analysis pKa values of 6.1 and 8.7 are obtained for the ionization of groups coupled to the presumed conformational transition. The pKa of 6.1 is assigned to HisHC3(146) beta; the pKa of 8.7 is assigned to the CysF9(93) beta sulphydryl group in its external conformation. It is estimated that the pKa of this sulphydryl may be as high as 12.9 in its internal conformation.     

Spectrophotometric titration of a single carboxyl group at the active site of ribonuclease T1.

Low-pH-induced difference spectra for ribonuclease T1, which were determined using a reference solution at pH 6, consisted of a shorter wavelength component from 270 to 285 nm that relfected an ionization having a pKa of 3.54 and a longer wavelength component above 285 nm that reflected an ionization having a pKa of 4.29. The temperature dependence of the pKa value for data at 300 nm is consistent with its representing the dissociation of a carboxyl group. In addition, the pKa determined at this wavelength significantly decreased at lower ionic strength. Similar experiments which were conducted using catalytically inactive gamma-carboxymethyl-Glu-58-ribonuclease T1 gave difference spectra having only the shorter wavelength component and were characterized by a single pKa of 3.53. It is concluded that the longer wavelength component of the difference spectra is due to the ionization of Glu-58. The pKa determined for this residue in the present study agrees with one found previously from kinetic studies which supports a role for Glu-58 in catalysis. Furthermore, the results suggest a model for the interaction of Glu-58 with histidine and tryptophan residues at the active site.     

Oxygen and CO binding to triply NO and asymmetric NO/CO hemoglobin hybrids.

The bimolecular and geminate CO recombination kinetics have been measured for hemoglobin (Hb) with over 90% of the ligand binding sites occupied by NO. Since Hb(NO)4 with inositol hexaphosphate (IHP) at pH below 7 is thought to take on the low affinity (deoxy) conformation, the goal of the experiments was to determine whether the species IHPHb-(NO)3(CO) also exists in this quaternary structure, which would allow ligand binding studies to tetramers in the deoxy conformation. For samples at pH 6.6 in the presence of IHP, the bimolecular kinetics show only a slow phase with rate 7 x 10(4) M-1 s-1, characteristic of CO binding to deoxy Hb, indicating that the triply NO tetramers are in the deoxy conformation. Unlike Hb(CO)4, the fraction recombination occurring during the geminate phase is low (< 1%) in aqueous solutions, suggesting that the IHPHb(NO)3(CO) hybrid is also essentially in the deoxy conformation. By mixing stock solutions of HbCO and HbNO, the initial exchange of dimers produces asymmetric (alpha NO beta NO/alpha CO beta CO) hybrids. At low pH in the presence of IHP, this hybrid also displays a high bimolecular quantum yield and a large fraction of slow (deoxy-like) CO recombination; the slow bimolecular kinetics show components of equal amplitude with rates 7 and 20 x 10(4) M-1 s-1, probably reflecting the differences in the alpha and beta chains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mercuri-nitrophenol as a reporter group for the conformational change of hemoglobin.

One mole of horse hemoglobin tetramer reacts with 2 moles of 2-chloromercuri-4-nitrophenol (MNP) at beta 93 cysteine. The difference spectra between NMP-bound hemoglobin and hemoglobin, measured with the aid of ascorbic acid and ascorate oxidase [EC 1.10.3.3] as deoxygenation reagents, indicate that the pK of the phenolic hydroxyl group of MNP increases by 0.6 to 0.8 pH unit on deoxygenation of the hemoglobin. The Hill constant of the modified hemoglobin changes with pH. It decreases from about 2.4 at pH 6.8 to about 1.0 at pH 9.0 This effect of the reagent is interpreted as inherent to the reporter groups.     

Dissociation of the DNA polymerase III holoenzyme beta 2 subunits is accompanied by conformational change at distal cysteines 333

The beta subunit of DNA polymerase III holoenzyme is in a dimer-monomer equilibrium at physiological beta concentrations. Dissociation is accompanied by the fluorescence enhancement of a fluorophore attached to a unique sulfhydryl group of beta (Griep, M. A., and McHenry, C. S. (1988) Biochemistry 27, 5210-5215). Sequencing of the isolated tryptic peptides of beta revealed that the fluorescent maleimide group was attached to cysteine 333. The 2 residues, lysine 332 and glutamate 334, that flank this residue are hydrophilic and may place cysteine 333 on the surface of beta, explaining its high reactivity. Fluorescence energy transfer permitted us to locate the uniquely labeled cysteines 333 of beta at the distal ends of the beta dimer. When the beta dimer was dissociated to monomers, the accompanying alteration of the conformational state was reported by the fluorescein-5-maleimide (fluorescein)-labeled cysteines which were located far from the dimer interface. The carboxyl of fluorescein had a fluorescence pKa of 6.9 when beta was in its dimeric state. The pKa decreased by 0.3 pH unit upon dissociation to monomers and resulted in the fluorescence enhancement that was observed when the signal was monitored at constant pH. The adjacent glutamate 334 apparently increased the pKa of the attached fluorescein when beta was in its dimeric state. Movement of either the adjacent lysine 332 amino side chain to a closer position or glutamate 334 to a position further away could lower the pKa upon beta monomerization. Thus, beta undergoes a conformational change concomitant with dimer dissociation that was transmitted to the opposite ends of the beta dimer. The pKa of fluorescein attached to the distal cysteines was shifted, leading to greater ionization and enhanced fluorescence.     

The effect of crosslinking by bis(3,5-dibromosalicyl) fumarate on the autoxidation of hemoglobin

Bis(3,5-dibromosalicyl) fumarate was used to crosslink hemoglobin both in the oxy and deoxy states. This double headed diaspirin was known to crosslink oxy Hb A selectively between Lys 82 beta 1 and Lys 82 beta 2 (Walder, J. A., et al. (1979) Biochemistry 18, 4265) and deoxy Hb A between Lys 99 alpha 1 and Lys 99 alpha 2 (Chatterjee R. Y., et al. (1986) J. Biol. Chem. 261, 9929). The autoxidation at 37 degrees C of oxy alpha 99 crosslinked hemoglobin was found to be 1.8 times as fast as that of Hb A while that of the oxy beta 82 crosslinked hemoglobin was only 1.2 times as fast. After 5 hours the formation of methemoglobin in the alpha crosslinked Hb A is 21.3% compared to 10.8% in beta crosslinked Hb A and 6.4% in Hb A. These results may effect the proposed use of alpha 99 crosslinked hemoglobin as a blood substitute by demonstrating the need for protection from autoxidation during storage.     

Studies on cobalt myoglobins and hemoglobins. Preparation of isolated chains containing cobaltous protoporphyrin IX and characterization of their equilibrium and kinetic properties of oxygenation and EPR spectra.

Human hemoglobin containing cobalt protoporphyrin IX or cobalt hemoglobin has been separated into two functionally active alpha and beta subunits using a new method of subunit separation, in which the -SH groups of the isolated subunits were successfully regenerated by treatment with dithiothreitol in the presence of catalase. Oxygen equilibria of the isolated subunit chains were examined over a wide range of temperature using Imai's polarographic method (Imai, K., Morimoto, H., Kotani, M., Watari, H., and Kuroda, M. (1970) Biochim. Biophys. Acta 200, 189-196). Kinetic properties of their reversible oxygenation were investigated by the temperature jump relaxation method at 16 degrees. Electron paramagnetic resonance characteristics of the molecules in both deoxy and oxy states were studies at 77K. The oxygen affinity of the individual regenerated chains was higher than that of the tetrameric cobalt hemoglobin and was independent of pH. The enthalpy changes of the oxygenation have been determined as -13.8 kcal/mol and -16.8 kcal/mol for the alpha and beta chains, respectively. The rates of oxygenation were similar to those reported for iron hemoglobin chains, whereas those of deoxygenation were about 10(2) times larger. The effects of metal substitution on oxygenation properties of the isolated chains were correlated with the results obtained previously on cobalt hemoglobin and cobalt myoglobin. The EPR spectrum of the oxy alpha chain showed a distinctly narrowed hyperfine structure in comparison with that of the oxy beta chain, indicating that the environment around the paramagnetic center (the bound oxygen) is different between these chains. In the deoxy form, EPR spectra of alpha and beta chains were indistinguishable. These observations suggest that one of the inequivalences between alpha and beta chains might exist near the distal histidine group.     

1H NMR study of the solution properties of the polypeptide neurotoxin I from the sea anemone Stichodactyla helianthus

The solution properties of the polypeptide neurotoxin I from the sea anemone Stichodactyla helianthus (Sh I) have been investigated by high-resolution 1H nuclear magnetic resonance (NMR) spectroscopy at 300 MHz. The pH dependence of the spectra has been examined over the range 1.1-12.2 at 27 degrees C. Individual pKa values have been obtained for the alpha-ammonium group of Ala-1 (8.6) and the side chains of Glu-8 (3.7), Tyr-36 (10.9), and Tyr-37 (10.8). For the remaining seven carboxyl groups in the molecule (from five Asp, Glu-31, and the C-terminus), four pKa values, viz., 2.8, 3.5, 4.1 and 6.4, can be clearly identified. The five Lys residues titrate in the range 10.5-11, but individual pKa values could not be obtained because of peak overlap. Conformational changes associated with the protonation of carboxylates occur below pH 4, while in the alkaline pH range major unfolding occurs above pH 10. The molecule also unfolds at elevated temperatures, having a transition temperature of ca. 55 degrees C at pH 5.25. Exchange of the backbone amide protons has been monitored at various values of pH and temperature in the ranges pH 4-5 and 12-27 degrees C. Up to 18 slowly exchanging amides are observed, consistent with the existence of a core of hydrogen-bonded secondary structure, most probably beta-sheet.(ABSTRACT TRUNCATED AT 250 WORDS)     

Specificity of alpha-chymotrypsin with exposed carboxyl groups blocked.

The 15 exposed carboxyl groups of alpha-chymotrypsin were modified with glycine ethyl ester at low pH using barbodiimide reagent. The specificity of the modified enzyme (Chy-15) was studied over the pH range of 4 to 9 with both N-acylated and non-N-acylated amino acid esters. The modified enzyme had lower reactivity toward N-acylated esters than non-N-acylated esters compared to the native enzyme. Typical substances such as acetyl- and benzoyl-L-tyrosine ethyl esters retained 4 and 9% activity, whereas phenylalanine ethyl ester was slightly more reactive with the modified than with the native enzyme. The pH-rate profiles of acetyl-L-phenylalanine ethyl ester and tryptophan ethyl and benzyl esters were investigated in detail. Analysis of these profiles revealed three pKa values of approximately 5, 7, and 9 related to a functional carboxyl, imidazoyl, and an amino group, respectively. Since similar pKa values occur for the native enzyme, modification did not block the carboxyl corresponding to pKa 5. A mechanism is proposed for catalysis which includes both the protonated and unprotonated form of the imidazoyl (His-57) and utilizes water rather than a carboxyl (Asp-102) as the proton sink.     

Identification of an essential cysteine in the reaction catalyzed by aspartate-beta-semialdehyde dehydrogenase from Escherichia coli.

The enzyme L-aspartate-beta-semialdehyde dehydrogenase from Escherichia coli has been studied by oligonucleotide-directed mutagenesis. The focus of this investigation was to examine the role of a cysteine residue that had been previously identified by chemical modification with an active site directed reagent (Biellmann et al. (1980) Eur. J. Biochem. 104, 59-64). Substitution of this cysteine at position 135 with an alanine results in complete loss of enzyme activity. However, changing this cysteine to a serine yields a mutant enzyme with a maximum velocity that is 0.3% that of the native enzyme. This C135S mutant has retained essentially the same affinity for substrates as the native enzyme, and the same overall conformation as reflected in identical behavior on gel electrophoresis and in identical fluorescence spectra. The pH profile of the native enzyme shows a loss in catalytic activity upon protonation of a group with a pKa value of 7.7. The same activity loss is observed at this pH with the serine-135 mutant, despite the differences in the pKa values for a cysteine sulfhydryl and a serine hydroxyl group that have been measured in model compounds. This observed pKa value may reflect the protonation of an auxiliary catalyst that enhances the reactivity of the active site cysteine nucleophile in the native aspartate-beta-semialdehyde dehydrogenase.