Differential labeling of the catalytic subunit of cAMP-dependent protein kinase with a water-soluble carbodiimide: identification of carboxyl groups protected by MgATP and inhibitor peptides

The catalytic subunit of cAMP-dependent protein kinase typically phosphorylates protein substrates containing basic amino acids preceding the phosphorylation site. To identify amino acids in the catalytic subunit that might interact with these basic residues in the protein substrate, the enzyme was treated with a water-soluble carbodiimide, 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC), in the presence of [14C]glycine ethyl ester. Modification of the catalytic subunit in the absence of substrates led to the irreversible, first-order inhibition of activity. Neither MgATP nor a 6-residue inhibitor peptide alone was sufficient to protect the catalytic subunit against inactivation by the carbodiimide. However, the inhibitor peptide and MgATP together completely blocked the inhibitory effects of EDC. Several carboxyl groups in the free catalytic subunit were radiolabeled after the catalytic subunit was modified with EDC and [14C]glycine ethyl ester. After purification and sequencing, these carboxyl groups were identified as Glu 107, Glu 170, Asp 241, Asp 328, Asp 329, Glu 331, Glu 332, and Glu 333. Three of these amino acids, Glu 331, Glu 107, and Asp 241, were labeled regardless of the presence of substrates, while Glu 333 and Asp 329 were modified to a slight extent only in the free catalytic subunit. Glu 170, Asp 328, and Glu 332 were all very reactive in the apoenzyme but fully protected from modification by EDC in the presence of MgATP and an inhibitor peptide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Use of Water-soluble Carbodiimide (EDC) for Immobilization of EDC-sensitive Dextranase

Water-soluble carbodiimide [EDC: (1-ethyl-3-(3-dimethylaminopropyl)carbodiimide)] is a useful reagent for chemical modification of carboxyl group of various proteins. Model experiments to establish detailed conditions for the cross-linking reaction with EDC were conducted. Since the reactivity of hexamethylenediamine as a nucleophile was almost comparable to that of glycine ethyl ester, AH-Sephadex and the carboxyl group of aspartylphenylalanine methyl ester were coupled by EDC. From the hydrolyzate of the isolated gel, aspartic acid and phenylalanine methyl ester were identified. When bovine serum albumin (BSA) was incubated with AH-Sephadex and EDC, about 90 % of the BSA was coupled to the gel by 3 hr incubation. Moreover, BSA was effectively coupled with the carboxymethyl cellulose (CMC) after activation of the carboxyl groups of CMC with EDC followed by the removal of excess EDC. The latter case would be useful for cross-linking the enzyme molecules to the matrix because of the very mild reaction conditions. For example, endodextranase, which readily lost its activity upon being incubated with EDC (suggesting that a carboxyl group was essential for the enzyme activity), was effectively immobilized to CMC with EDC. This improved reaction step for the cross-linking seemed to be especially useful for the glycosylases, because in most of these enzymes carboxyl groups play a role in the catalytic residue.     

Effects of Chemical Modification of Carboxyl Groups in the Hemolytic Lectin CEL-III on Its Hemolytic and Carbohydrate-Binding Activities

Effects of chemical modification of carboxyl groups in the hemolytic lectin CEL-III on its activities were investigated. When carboxyl groups were modified with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) and glycine methyl ester, hemolytic activity of CEL-III decreased as the EDC concentration increased, accompanied by reduction of oligomerization ability and hemagglutinating activity. However, binding ability of CEL-III for immobilized lactose was retained fairly well after modification, suggesting that one of two carbohydrate-binding sites might be responsible for such inactivation of CEL-III.     

Effects of chemical modification of carboxyl groups in the hemolytic lectin CEL-III on its hemolytic and carbohydrate-binding activities

Effects of chemical modification of carboxyl groups in the hemolytic lectin CEL-III on its activities were investigated. When carboxyl groups were modified with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) and glycine methyl ester, hemolytic activity of CEL-III decreased as the EDC concentration increased, accompanied by reduction of oligomerization ability and hemagglutinating activity. However, binding ability of CEL-III for immobilized lactose was retained fairly well after modification, suggesting that one of two carbohydrate-binding sites might be responsible for such inactivation of CEL-III.     

Effects of chemical modification of Anabaena flavodoxin and ferredoxin-NADP+ reductase on the kinetics of interprotein electron transfer reactions.

The influence of chemical modification of arginine residues (using phenylglyoxal) in ferredoxin-NADP+ reductase (FNR), and of carboxyl groups (using glycine ethyl ester) in flavodoxin (Fld), on the kinetics of electron transfer between FNR and Fld, and between ferredoxin (Fd) and FNR, was examined using laser flash photolysis methods. All proteins were obtained from the cyanobacterium Anabaena PCC7119. Reduction by laser-generated 5-deazariboflavin semiquinone of the FAD moiety of phenylglyoxal-modified FNR occurred with a second-order rate constant 2.5-fold smaller than that obtained for reduction of native FNR, indicating either a small degree of steric hindrance of the cofactor, or a decrease in its redox potential, upon chemical modification. In contrast, no changes were found in the kinetics of reduction of the FMN cofactor of Fld modified by glycine ethyl ester as compared with the native protein. The observed rate constants for reoxidation of Fdred (reduced Fd) by FNRox (oxidized FNR) were dramatically decreased (approximately 100-fold) when phenylglyoxal-modified FNR was used. In contrast to the reaction involving the native proteins, no ionic strength effects on kobs values were found. These results, and those obtained upon varying the protein concentration, indicate that the rate constant for complex formation and the attractive electrostatic interaction between the two proteins were greatly diminished by chemical modification of arginine residues of FNR. When phenylglyoxal-modified FNRsq (FNR semiquinone) was used to reduce Fldox (oxidized Fld), similar inhibitory effects were observed. In this case, the limiting first-order rate constant for Fldsq (Fld semiquinone) formation via intracomplex electron transfer from FNRsq was approximately 12-fold smaller than that obtained for the native FNR (600 s-1 vs 7000 s-1). Again, ionic strength effects were diminished. The glycine-ethyl-ester-modified Fld yielded a limiting first-order rate constant for intracomplex electron transfer from FNRsq to Fldox which was approximately 7-fold smaller (1000 s-1) than that obtained with native Fld, and ionic strength effects were again diminished. These results indicate that complex formation can still occur between modified FNR and native Fld, and between native FNR and modified Fld, but that the geometry of these complexes is altered so as to decrease the effectiveness of interprotein electron transfer. The results are discussed in terms of the specific structural features of the proteins involved.     

Role of electrostatic interactions in the reaction of NADPH-cytochrome P-450 reductase with cytochromes P-450

Chemical modification of cytochrome P-450 reductase was used to determine the involvement of charged amino acids in the interaction between the reductase and two forms of cytochrome P-450. Acetylation of 11 lysine residues of the reductase with acetic anhydride yielded a 20-40% decrease in the apparent Km of the reductase for cytochrome P-450b or cytochrome P-450c using either 7-ethoxycoumarin or benzphetamine as substrates. A 20-45% decrease in the Vmax was observed except for cytochrome P-450b with 7-ethoxycoumarin as substrate, where there was a 27% increase. Modification of carboxyl groups on the reductase with 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide (EDC) and methylamine, glycine methyl ester, or taurine as nucleophiles inhibited the interaction with the cytochromes P-450. We were able to modify 4.0, 7.9, and 5.9 carboxyl groups using methylamine, glycine methyl ester, or taurine, respectively. The apparent Km for cytochrome P-450c or cytochrome P-450b was increased 1.3- to 5.2-fold in a reconstituted monooxygenase assay with 7-ethoxycoumarin or benzphetamine as substrate. There were varied effects on the Vmax. There was no significant change in the conformation of the reductase upon chemical modification with either acetic anhydride or EDC. These results strongly suggest that electrostatic interactions as well as steric constraints play a role in the binding and electron transfer step(s) between the reductase and cytochrome P-450.     

Chemical modifications of the sigma subunit of the E. coli RNA polymerase.

The function of arginine, cysteine and carboxylic amino acid (glutamic and aspartic) residues of sigma was studied using chemical modification by group specific reagents. Following modification of 3 arginine residues with phenylglyoxal or 3 cysteine residues with N-ethylmaleimide (NEM) sigma activity was lost. Analysis of the kinetic data for inactivation indicated that one arginine or cysteine residue is essential for sigma activity. At low NEM concentration alkylation was limited to a non-critical cysteine which was identified as cysteine-132. Modification of arginine or cysteine residues had no observable effect on the binding of the inactivated sigma to the core polymerase. Modification of aspartic and/or glutamic acid residues with the water-soluble carbodiimides 1-ethyl-3-(3-dimethylamino-propyl) carbodiimide hydrochloride (EDC) or 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate (CMC) resulted in loss of sigma activity. The inactivation data indicated that one carboxylic amino acid residue is essential for sigma activity. Sigma modified with EDC, CMC or EDC in the presence of glycine was inactive in supporting promoter binding and initiation by core polymerase. Reaction with EDC plus (3H)glycine resulted in the incorporation of glycine into sigma. The (3H)glycine-sigma was unable to form a stable holoenzyme complex.     

Chemical modification of carboxyl groups on spinach ferredoxin alters its ability to interact with ferredoxin:NADP reductase

Treatment of spinach ferredoxin with glycine ethyl ester in the presence of a water soluble carbodiimide resulted in the modification of 3-4 carboxyl groups and decreased the ability of ferredoxin to participate in NADP photoreduction by chloroplast membranes by about 80%. The ability of the modified ferredoxin to receive electrons from the reducing side of Photosystem I was relatively unaffected. These findings suggest that the modified ferredoxin is unable to interact with ferredoxin:NADP reductase. This has been verified by demonstration that the modified ferredoxin fails to produce difference spectra typical of a ferredoxin-ferredoxin:NADP reductase complex when added to ferredoxin:NADP reductase.     

The chemical modification of papain with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide.

The reaction of the water-soluble carbodimide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), with active papain in the presence of the nucleophile ethyl glycinate results in an irreversible inactivation of the enzyme. This inactivation is accompanied by the derivatization of the catalytically essential thiol group of the enzyme (Cys-25) and by the modification of 6 out of 14 of papain's carboxyl groups and up to 9 out of 19 of the enyzme's tyrosyl residues. No apparent irreversible modification of histidine residues is observed. Mercuripapain is also irreversibly inactivated by EDC/ethyl glycinate, again with the concomitant modification of 6 carboxyl groups, up to 10 tyrosyl residues, and no histidine residues; but in this case there is no thiol derivatization. Treatment of either modified native papain or modified mercuripapain with hydroxylamine results in the complete regeneration of free tyrosyl residues but does not restore any activity. The competitive inhibitor benzamidoacetonitrile substantially protects native papain against inactivation and against the derivatization of the essential thiol group as well as 2 of the 6 otherwise accessible carboxyl groups. The inhibitor has no effect upon tyrosyl modification. These findings are discussed in the context of a possible catalytic role for a carboxyl group in the active site of papain.     

The involvement of carboxylate groups of putidaredoxin in the reaction with putidaredoxin reductase

Modification of carboxyl groups on putidaredoxin with 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide (EDC) resulted in loss of putidaredoxin reductase activity. The modification did not affect the visible absorption spectrum of putidaredoxin, indicating that the iron-sulfur center was not perturbed. In order to identify the carboxyl groups labeled by EDC, native and EDC-treated putidaredoxin were digested with a combination of trypsin and Staphylococcus aureus protease, and the resulting peptides were separated by high pressure liquid chromatography. The most heavily modified carboxyl groups were found to be those at residues 58, 65, 67, 72, and 77. These carboxyl groups are located in the same general region of the protein as those on adrenodoxin that have been shown to be involved in binding to both adrenodoxin reductase and cytochrome P-450scc. Chemical modification was also used to compare the role of lysine, arginine, and histidine residues on putidaredoxin and adrenodoxin. Modification of lysine and arginine residues had no effect on the reductase activity of either protein. The reductase activity of adrenodoxin was unaffected by labeling with 1 eq of diethyl pyrocarbonate/histidine residue, but labeling with a second equivalent completely abolished both activity and the iron-sulfur center spectrum. In contrast, modification of the 2 histidines in putidaredoxin with 1 eq each resulted in nearly complete loss of reductase activity. There was no significant activity for adrenodoxin in the putidaredoxin reductase assay or for putidaredoxin in the adrenodoxin reductase assay, demonstrating that, in spite of the structural similarity between the two proteins, they are not interchangeable functionally.     

Inactivation of Buckwheat α-Glucosidase with 1-Ethyl-3-(3-dimethylaminopropyl) carbodiimide

The amino acid residue(s) involved in the activity of buckwheat α-glucosidase was modified by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide in the presence of glycine ethyl ester. The modification resulted in the decrease in the hydrolytic activity of the enzyme following pseudo-first order kinetics. Competitive inhibitors, such as Tris and turanose, protected the enzyme against the inactivation. Protection was provided also by alkali metal, alkaline-earth metal and ammonium ions, though these cations are non-essential for the activity of the enzyme. Turanose or K⁺ protected one carboxyl group per enzyme from the modification with carbodiimide and glycine ethyl ester. Free sulfhydryl group of the enzyme was also partially modified with carbodiimide, but the inactivation was considered to be mainly attributed to the modification of essential carboxyl group rather than to that of free sulfhydryl group.     

Modification of essential carboxyl group in rabbit muscle phosphorylase by water-soluble carbodiimide

Water-soluble carbodiimide (1-ethyl-3-(3-dimethylaminopropyl)carbodiimide) (EDC) and glycine ethyl ester (GEE) as a nucleophile were used to modify the essential carboxyl group of phosphorylases. The inactive b form of the muscle phosphorylase was modified faster than the active a form and potato phosphorylases. Use of N,N,N',N'-tetramethyl-ethylenediamine (TEMED)-HCl buffer system (pH 6.2) resulted in a remarkable difference from the previous results obtained with phosphate and beta-glycerophosphate buffer systems. That is, the substrate glucose 1-phosphate gave the best protection of the three phosphorylase activities. Glucose and glycogen were also effective to retard the inactivation of muscle phosphorylases, though glycogen was not effective for the potato enzyme. The EDC-GEE-modified phosphorylase b retained the affinity for AMP-Sepharose, though partially modified enzyme completely lost the homotropic cooperativity. Phosphorylase b was subjected to differential labeling with [14C]GEE. A labeled peptide was obtained after CNBr cleavage and peptic digestions, and corresponded to the catalytic site sequence surrounding the GEE-substituted Asp 661 and Glu 664. Either or both of these EDC-modified carboxyl residues may have an important role in the catalytic reaction.     

Carboxyl groups at the two active centers of sucrase-isomaltase from rabbit small intestine.

1. Seveal selective reagents were employed to identify the amino acid residues essential for the catalytic activity of sucrase-isomaltase. 2. Modification of histidine, lysine and carboxyl residues resulted in a partial inactivation of the enzyme. Substrates or competitive inhibitors provided protection against inactivation only in the reaction of carboxyl groups with carbodiimide (+lycine ethyl ester) or with diazoacetic ethyl ester. This indicated the occurrence of carboxyl groups at the two active centers of the enzyme complex. 3. Protection against inactivation of the enzyme by carbodiimide was provided also by the presence of alkali and alkaline earth metal ions, which are non-essential activators of sucrase-isomaltase. The presence of Na+ and Ba2+ protected approximately one carboxyl group per active center from reacting with carbodiimide plus glycine ethyl ester. 4. The carbodiimide-reactive groups were not identical with the two carboxylate groups recently found to react with conduritol-B-epoxide, an active-site-directed inhibitor of sucrase-isomaltase (Quaroni, A. and Semenza, G., 1976, J. Biol. Chem 251,3250--3253). A possible role for the carbodiimide-reactive carboxyl groups at the active centers of sucrase-isomaltase is discussed.     

The presence of essential carboxyl group for binding of cytochrome c in rat hepatic NADPH-cytochrome P-450 reductase by the reaction with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide

NADPH-cytochrome P-450 reductase (EC 1.6.2.4) purified from rat hepatic microsomal fraction was inactivated by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), a specific agent for modification of carboxyl groups in a protein. The inactivation exhibited pseudo-first order kinetics with a reaction order approximately one and a second-order-rate constant of 0.60 M-1 min-1 in a high ionic strength buffer and 0.08 M-1 min-1 in a low ionic strength buffer. By treatment of NADPH-cytochrome P-450 reductase with EDC, the pI value changed to 6.5 from 5.0 for the native enzyme, and the reductase activity for cytochrome c, proteinic substrate, was strongly inactivated. When an inorganic substrate, K3Fe(CN)6, was used for assay of the enzyme activity, however, no significant inactivation by EDC was observed. The rate of inactivation by EDC was markedly but not completely decreased by NADPH. Also, the inactivation was completely prevented by cytochrome c, but not by K3Fe(CN)6 or NADH. The sulfhydryl-blocked enzyme prepared by treatment with 5,5'-dithio-bis(2-nitrobenzoic acid), which had no activity, completely recovered its activity in the presence of dithiothreitol. When the sulfhydryl-blocked enzyme was modified by EDC, the enzyme in which the carboxyl group alone was modified was isolated, and its activity was 35% of the control after treatment with dithiothreitol. In addition, another carboxyl reagent, N-ethyl-5-phenylisoxazolium-3'-sulfonate (Woodward reagent K), decreased cytochrome c reductase activity of NADPH-cytochrome P-450 reductase. These results suggest that the carboxyl group of NADPH-cytochrome P-450 reductase from rat liver is located at or near active-site and plays a role in binding of cytochrome c.     

Comparisons of wild-type and mutant flavodoxins from Anacystis nidulans. Structural determinants of the redox potentials

The long-chain flavodoxins, with 169-176 residues, display oxidation-reduction potentials at pH 7 that vary from -50 to -260 mV for the oxidized/semiquinone (ox/sq) equilibrium and are -400 mV or lower for the semiquinone/hydroquinone (sq/hq) equilibrium. To examine the effects of protein interactions and conformation changes on FMN potentials in the long-chain flavodoxin from Anacystis nidulans (Synechococcus PCC 7942), we have determined crystal structures for the semiquinone and hydroquinone forms of the wild-type protein and for the mutant Asn58Gly, and have measured redox potentials and FMN association constants. A peptide near the flavin ring, Asn58-Val59, reorients when the FMN is reduced to the semiquinone form and adopts a conformation ("O-up") in which O 58 hydrogen bonds to the flavin N(5)H; this rearrangement is analogous to changes observed in the flavodoxins from Clostridium beijerinckii and Desulfovibrio vulgaris. On further reduction to the hydroquinone state, the Asn58-Val59 peptide in crystalline wild-type A. nidulans flavodoxin rotates away from the flavin to the "O-down" position characteristic of the oxidized structure. This reversion to the conformation found in the oxidized state is unusual and has not been observed in other flavodoxins. The Asn58Gly mutation, at the site which undergoes conformation changes when FMN is reduced, was expected to stabilize the O-up conformation found in the semiquinone oxidation state. This mutation raises the ox/sq potential by 46 mV to -175 mV and lowers the sq/hq potential by 26 mV to -468 mV. In the hydroquinone form of the Asn58Gly mutant the C-O 58 remains up and hydrogen bonded to N(5)H, as in the fully reduced flavodoxins from C. beijerinckii and D. vulgaris. The redox and structural properties of A. nidulans flavodoxin and the Asn58Gly mutant confirm the importance of interactions made by N(5) or N(5)H in determining potentials, and are consistent with earlier conclusions that conformational energies contribute to the observed potentials.The mutations Asp90Asn and Asp100Asn were designed to probe the effects of electrostatic interactions on the potentials of protein-bound flavin. Replacement of acidic by neutral residues at positions 90 and 100 does not perturb the structure, but has a substantial effect on the sq/hq equilibrium. This potential is increased by 25-41 mV, showing that electrostatic interaction between acidic residues and the flavin decreases the potential for conversion of the neutral semiquinone to the anionic hydroquinone. The potentials and the effects of mutations in A. nidulans flavodoxin are rationalized using a thermodynamic scheme developed for C. beijerinckii flavodoxin.     

Identification and characterization of an NADPH-cytochrome P450 reductase derived peptide involved in binding to cytochrome P450

The amino acids of cytochrome P450 reductase involved in the interaction with cytochrome P450 were identified with a differential labeling technique. The water-soluble carbodiimide EDC (1-ethyl-3-[3- (dimethylamino)propyl]-carbodiimide) was used with the nucleophile methylamine to modify carboxyl residues. When the modification was performed in the presence of cytochrome P450, there was no inhibition in the ability of the modified reductase to bind to cytochrome P450. However, subsequent modification of the reductase in the absence of cytochrome P450 caused a fourfold increase in the Km and an 80% decrease in kcat/Km (relative to the reductase modified in the first step), for the interaction with cytochrome P450. These effects are attributed to the modification of approximately 3.2 mol of carboxyl residues per mole of reductase. Tryptic peptides generated from the modified reductase were purified by reverse phase high-performance liquid chromatography and characterized. Amino acid sequencing and analysis suggest that the peptide which contains approximately 40% of the labeled carboxyl residues corresponds to amino acid residues 109-130 of rat liver NADPH-cytochrome P450 reductase. One or more of the seven carboxyl containing amino acids within this peptide is presumably involved in the interaction with cytochrome P450.     

The role of carboxyl groups on the chitosanase and CMCase activity of a bifunctional enzyme purified from a commercial cellulase with EDC modification

The carboxyl groups of the bifunctional cellulase–chitosanase (CCBE), purified from a commercial cellulase prepared from Trichoderma viride were modified using the water-soluble carbodiimide 1-ethyl-3-(3-dimethyl-aminopropyl) carbodiimide (EDC). The EDC modified CCBE lost 80–90% of its chitosnase activity and 20% of its carboxylmethyl cellulase (CMCase) activity; meanwhile, its conformation changed slightly, which altered the substrate binding affinity to chitosan, without affecting its binding to CMC. However, the modification did not alter the structure integrity. The dynamic analysis of modification indicated that the CCBE possessed two carboxylates essential for its chitosanase activity and one carboxyl group for its CMCase activity. One of the two carboxylates involved in chitosanase activity was deduced to be the proton donator, and the other may function for substrate recognition, while the only catalytic carboxyl group for CMCase activity probably also acted as a proton donator.     

Oxidation-reduction potentials of ferredoxin-NADP+ reductase and flavodoxin from Anabaena PCC 7119 and their electrostatic and covalent complexes.

The oxidation-reduction potentials of ferredoxin-NADP+ reductase and flavodoxin from the cyanobacterium Anabaena PCC 7119 were determined by potentiometry. The potentials at pH 7 for the oxidized flavodoxin/flavodoxin semiquinone couple (E2) and the flavodoxin semiquinone/hydroquinone couple (E1) were -212 mV and -436 mV, respectively. E1 was independent of pH above about pH 7, but changed by approximately -60 mV/pH below about pH 6, suggesting that the fully reduced protein has a redox-linked pKa at about 6.1, similar to those of certain other flavodoxins. E2 varied by -50 mV/pH in the range pH 5-8. The redox potential for the two-electron reduction of ferredoxin-NADP+ reductase was -344 mV at pH 7 (delta Em = -30 mV/pH). In the 1:1 electrostatic complex of the two proteins titrated at pH 7, E2 was shifted by +8 mV and E1 was shifted by -25 mV; the shift in potential for the reductase was +4 mV. The potentials again shifted following treatment of the electrostatic complex with a carbodiimide, to covalently link the two proteins. By comparison with the separate proteins at pH 7, E2 for flavodoxin shifted by -21 mV and E1 shifted by +20 mV; the reductase potential shifted by +2 mV. The potentials of the proteins in the electrostatic and covalent complexes showed similar pH dependencies to those of the individual proteins. Qualitatively similar changes occurred when ferredoxin-NADP+ reductase from Anabaena variabilis was complexed with flavodoxin from Azotobacter vinelandii. The shifts in redox potential for the complexes were used with previously determined values for the dissociation constant (Kd) of the electrostatic complex of the two oxidised proteins, in order to estimate Kd values for the interaction of the different redox forms of the proteins. The calculations showed that the electrostatic complexes, formed when the proteins differ in their redox states, are stronger than those formed when both proteins are fully oxidized or fully reduced.     

Irreversible thermoinactivation of glucoamylase from Aspergillus niger and thermostabilization by chemical modification of carboxyl groups

The incubation of glucoamylase from Aspergillus niger at 70 degrees C induced its rapid and irreversible inactivation. The covalent modifications of the protein structure involved in the thermoinactivation depended on the pH of the medium. We observed the formation of a low amount of disulfide-linked oligomers showing that disulfide exchange takes place at pH 5.5. Hydrolysis of peptide bonds at pH 3.5 and 4.5 was also detected. The chemical modification of carboxyl groups with a water-soluble carbodiimide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) decreased the rate of appearance of low-molecular-weight peptides at pH 3.5 and 4.5 upon heating at 70 degrees C. However, the rate of inactivation at such pH values was not modified. Modification of carboxyl groups with EDC in the presence of ethylenediamine leading to the transformation of three carboxyl groups to amino groups increased the thermostability of the enzyme for temperatures above the temperature of compensation, Tc, which is 60 degrees C.     

Evidence for a reactive gamma-carboxyl group (Glu-418) at the herbicide glyphosate binding site of 5-enolpyruvylshikimate-3-phosphate synthase from Escherichia coli

Incubation of 5-enolpyruvylshikimate-3-phosphate synthase, a target for the nonselective herbicide glyphosate (N-(phosphonomethyl)glycine), with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide in the presence of glycine ethyl ester resulted in a time-dependent loss of enzyme activity. The inactivation followed pseudo-first order kinetics, with a second order rate constant of 2.2 M-1 min-1 at pH 5.5 and 25 degrees C. The inactivation is prevented by preincubation of the enzyme with a combination of the substrate shikimate 3-phosphate plus glyphosate, but not by shikimate 3-phosphate, phosphoenolpyruvate, or glyphosate alone. Increasing the concentration of glyphosate during preincubation resulted in decreasing the rate of inactivation of the enzyme. Complete inactivation of the enzyme required the modification of 4 carboxyl groups per molecule of the enzyme. However, statistical analysis of the residual activity and the extent of modification showed that among the 4 modifiable carboxyl groups, only 1 is critical for activity. Tryptic mapping of the enzyme modified in the absence of shikimate 3-phosphate and glyphosate by reverse phase chromatography resulted in the isolation of a [14C]glycine ethyl ester-containing peptide that was absent in the enzyme modified in the presence of shikimate 3-phosphate and glyphosate. By amino acid sequencing of this labeled peptide, the modified critical carboxyl group was identified as Glu-418. The above results suggest that Glu-418 is the most accessible reactive carboxyl group under these conditions and is located at or close to the glyphosate binding site.