Modification of glucoamylases from Rhizopus sp. with 1-cyclohexyl-3-(2-morpholinyl-(4)-ethyl)carbodiimide

To investigate the role of carboxyl groups of glucoamylases [EC 3.2.1.3] from a Rhizopus sp. (Gluc1 and Gluc2), the modification of Gluc1 and Gluc2 with a water-soluble carbodiimide, 1-cyclohexyl-3-(2-morpholinyl-(4)-ethyl)carbodiimide metho-p-toluenesulfonate (CMC), was studied. The inactivation of Gluc1 proceeded with the incorporation of about 3 CMC moieties. In the presence of maltose, the modification of about 2.2 carboxyl groups of Gluc1 proceeded with a slight loss of enzymatic activity. In the re-modification of Gluc1 modified in the presence of maltose, Gluc1 was inactivated by further modification of about 1.3 carboxyl groups. Therefore, one carboxyl group, which was protected by maltose, was thought to be a crucial one. The inactivation of Gluc2 proceeded similarly to that of Gluc1, but the number of CMC moieties incorporated was about one less than in the case of Gluc1. Thus, it was suggested that one of the reactive carboxyl groups of Gluc1 was located in the N-terminal part of Gluc1, which is deficient in Gluc2. From the results of kinetic studies on CMC-modified Gluc1, it was suggested that the hydrolysis mechanism of malto-oligomers differs somewhat from that of PNPG.     

Modification of a minor glucoamylase from Aspergillus saitoi with 1-cyclohexyl-3-(2-morpholinyl-(4)-ethyl)carbodiimide metho p-toluenesulfonate

In order to elucidate the structure-function relationship of glucoamylases [EC 3.2.1.3, alpha-D-(1-4)-glucan glucohydrolase] from Aspergillus saitoi, the reaction of a minor component, Gluc M2 with 1-cyclohexyl-3-(2-morpholinyl-(4)-ethyl)carbodiimide metho p-toluenesulfonate (CMC) was studied at pH 4.5. Inactivation of Gluc M2 with [14C]CMC proceeded with the incorporation of about 5 CMC moieties. From the results of analyses of amino acid and sulfhydryl contents of CMC-modified Gluc M2 and the hydroxylamine treatment of the CMC-modified Gluc M2 at pH 7.0, it was concluded that the sites of CMC-modification were carboxylic acids of Gluc M2. In the presence of maltose, when Gluc M2 was treated with [14C]CMC, ca. 4 CMC moieties were incorporated with a simultaneous decrease in activity (30%). The Gluc M2 modified in the presence of maltose was re-modified with CMC after elimination of maltose. The CMC-modified Gluc M2 (70% activity) was inactivated completely with the further incorporation of ca. 2 CMC moieties. The logarithm of the half-life of the inactivation of Gluc M2 by CMC was a linear function of log[CMC] indicating that one carboxyl group among the modified ones was crucial for the inactivation of Gluc M2. From the results of these modification reactions, it was concluded that one or two carboxylic acids in Gluc M2 were crucial for the catalysis of glucoamylase from A. saitoi. Based on the analysis of the pH-profile of CMC inactivation of Gluc M2, the participation of a carboxylic acid having pKa 5.7 in the active site is proposed.     

Mitochondrial nicotinamide nucleotide transhydrogenase: nonidentical modification by N,N'-dicyclohexylcarbodiimide and N-(ethoxycarbonyl)-2-ethoxy-1,2-dihydroquinoline at the NAD(H) binding site

The energy-linked nicotinamide nucleotide transhydrogenase (TH) purified from bovine heart mitochondria is inhibited by the carboxyl group modifiers, N,N'-dicyclohexylcarbodiimide (DCCD) and N-(ethoxycarbonyl)-2-ethoxy-1,2-dihydroquinoline (EEDQ). With either reagent, complete activity inhibition corresponds to modification of one carboxyl group per 2 mol (monomers) of this dimeric enzyme, suggesting half-site reactivity toward DCCD and EEDQ [D. C. Phelps, and Y. Hatefi (1984) Biochemistry 23, 4475-4480; 6340-6344]. It has also been shown in the former reference that DCCD appears to modify TH at the NAD(H)-binding site. The present paper presents data suggesting that EEDQ also binds at or near the NAD(H)-binding domain of TH, but at a site not identical to that of DCCD: TH modified with and inhibited approximately 85% by EEDQ could be further labeled with [14C]DCCD to the extent of 70% of the maximum in the same time period that unmodified TH was modified by [14C]DCCD to near saturation (1 mol DCCD/TH dimer); DCCD-modified TH did not bind to NAD-agarose, while EEDQ-modified TH showed partial affinity for NAD-agarose; 5'-AMP completely protected TH against modification by DCCD, but showed only a weak protective effect against EEDQ; by contrast, NMNH, which is a TH substrate and binds to the NADH site, did not protect TH against DCCD, but completely protected the enzyme against attack by EEDQ. The results are consistent with the possibility that DCCD modifies TH where the 5'-AMP moiety of NAD(H) binds, while EEDQ modifies the enzyme where the NMN(H) moiety of NAD(H) resides.     

Characterization of Ustilago Ribonuclease U2. Effects of chemical modification at glutamic acid-61 and cystine-1 and of organic solvents on the enzymatic activity.

RNase U2 was purified and crystallized from the enriched culture medium (ammonium sulfate-urea-corn meal) of Ustilago sphaerogena and its characteristics were investigated. Chemical modification of RNase U2 was conducted with monoiodoacetic acid to carboxymethylate Glu-61 and with 2-methoxy-5-nitrotropone to nitrotroponylate the amino terminal residue. The amino terminal residue was modified reversibly by this reagent. Comparison of the 2'-AMP binding in the modified enzyme and the native one showed that Glu-61 is essential for the formation of the enzyme-substrate complex, while the amino terminal residue plays no important role in the enzymatic activity. The enzymatic activity and the structure of RNase U2 in aqueous organic solution were also investigated. The affinity of the enzyme for 2'-AMP, the inactivation by monoiodoacetic acid and the fluorescence intensity were examined. The profiles of the changes in the properties of the enzyme protein were consistent with those in the enzymatic activity. Fluorescence studies of the enzyme suggest that the tryptophan residue is closely related to the activity.     

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.     

Mechanism of action of cutinase: chemical modification of the catalytic triad characteristic for serine hydrolases

Cutinase from Fusarium solani f. sp. pisi was inhibited by diisopropyl fluorophosphate and phenylboronic acid, indicating the involvement of an active serine residue in enzyme catalysis. Quantitation of the number of phosphorylated serines showed that modification of one residue resulted in complete loss of enzyme activity. One essential histidine residue was modified with diethyl pyrocarbonate. This residue was buried in native cutinase and became accessible to chemical modification only after unfolding of the enzyme by sodium dodecyl sulfate. The modification of carboxyl groups with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide in the absence of sodium dodecyl sulfate did not result in inactivation of the enzyme; however, such modifications in the presence of sodium dodecyl sulfate resulted in complete loss of enzyme activity. The number of residues modified was determined by incorporation of [14C]glycine ethyl ester. Modification of cutinase in the absence of sodium dodecyl sulfate and subsequent unfolding of the enzyme with detergent in the presence of radioactive glycine ester showed that one buried carboxyl group per molecule of cutinase resulted in complete inactivation of the enzyme. Three additional peripheral carboxyl groups were modified in the presence of sodium dodecyl sulfate. Carbethoxylation of the essential histidine and subsequent incubation with the esterase substrate p-nitrophenyl [1-14C]acetate revealed that carbethoxycutinase was about 10(5) times less active than the untreated enzyme. The acyl-enzyme intermediate was stabilized under these conditions and was isolated by gel permeation chromatography. The results of the present chemical modification study indicate that catalysis by cutinase involves the catalytic triad and an acyl-enzyme intermediate, both characteristic for serine proteases.     

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.     

Carbodiimide inactivation of Na,K-ATPase. A consequence of internal cross-linking and not carboxyl group modification

Irreversible inhibition of Na,K-ATPase and K+-dependent p-nitrophenylphosphatase activities was produced by incubation of purified Na,K-ATPase enzyme with 1-ethyl-3(3-dimethylaminopropyl)carbodiimide (EPC). Inhibition was time and [EPC] dependent and displayed first order kinetics with respect to time. The [EPC] to reduce the enzyme velocity by 50% for Na,K-ATPase and phosphatase activities was 1.6 and 2.2 mM, respectively. Analysis of the kinetics of inhibition by EPC indicated that reaction at one site was sufficient to produce inhibition. Inhibition was greatly reduced by the presence of Mg2+, Na+, K+, choline, or Tris (decreasing order of effectiveness); ATP was without effect. This suggests that cation-bound enzyme forms were less reactive with the carbodiimide than free enzyme; ATP-bound enzyme was as reactive. Apparently the cations Na+, Mg2+, Tris, and choline stabilize E1 forms of the enzyme which are different from the E1 form stabilized by ATP. Addition of [14C]glycine ethyl ester (Gly-OEt) resulted in incorporation of radioactivity into both alpha and beta subunits that was dependent upon the presence of EPC, and the incorporation was reduced by the cations which reduced the inhibition due to EPC. Simultaneous addition of Gly-OEt with EPC prevented inhibition, although 14C incorporation still took place. If Gly-OEt addition was delayed the initial inactivation was not affected, but little subsequent inactivation occurred. The protection against inactivation by EPC occurs on the addition of other exogenous nucleophiles, such as aminoethane or ethylenediamine. Dicyclohexylcarbodiimide, a more potent hydrophobic carbodiimide inhibitor, shows similar effects; the inhibition due to dicyclohexylcarbodiimide is also prevented by the simultaneous presence of a nucleophile. After treatment with a carbodiimide and exogenous nucleophile the Na,K-ATPase has modified carboxyl residues but is not inhibited. Thus, modification of the cation-protectable carboxyl groups does not by itself cause inhibition. It seems likely that the inhibition of activity due to carbodiimide alone is not due to the modification of a carboxyl group per se but to the formation of an intramolecular bond between the carbodiimide-activated carboxylic acid and an endogenous nucleophile. The formation of such bonds suggests the close juxtaposition of amine and carboxyl groups in the secondary structure of the enzyme.     

Preparation of potent cytotoxic ribonucleases by cationization: enhanced cellular uptake and decreased interaction with ribonuclease inhibitor by chemical modification of carboxyl groups.

Carboxyl groups of bovine RNase A were amidated with ethylenediamine (to convert negative charges of carboxylate anions to positive ones), 2-aminoethanol (to eliminate negative charges), and taurine (to keep negative charges), respectively, by a carbodiimide reaction. Human RNase 1 was also modified with ethylenediamine. Surprisingly, the modified RNases were all cytotoxic toward 3T3-SV-40 cells despite their decreased ribonucleolytic activity. However, their enzymatic activity was not completely eliminated by the presence of excess cytosolic RNase inhibitor (RI). As for native RNase A and RNase 1 which were not cytotoxic, they were completely inactivated by RI. More interestingly, within the cytotoxic RNase derivatives, cytotoxicity correlated well with the net positive charge. RNase 1 and RNase A modified with ethylenediamine were more cytotoxic than naturally occurring cytotoxic bovine seminal RNase. An experiment using the fluorescence-labeled RNase derivatives indicated that the more cationic RNases were more efficiently adsorbed to the cells. Thus, it is suggested that the modification of carboxyl groups could change complementarity of RNase to RI and as a result endow RNase cytotoxicity and that cationization enhances the efficiency of cellular uptake of RNase so as to strengthen its cytotoxicity. The finding that an extracellular human enzyme such as RNase 1 could be effectively internalized into the cell by cationization suggests that cationization is a simple strategy for efficient delivery of a protein into cells and may open the way of the development of new therapeutics.     

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)     

Mitochondrial nicotinamide nucleotide transhydrogenase: active site modification by 5'-[p-(fluorosulfonyl)benzoyl]adenosine

Membrane-bound and purified mitochondrial energy-linked nicotinamide nucleotide transhydrogenase (TH) was inhibited by incubation with 5'-[p-(fluorosulfonyl)benzoyl]adenosine (FSBA), which is an analogue of TH substrates and their competitive inhibitors, namely, 5'-, 2'-, or 3'-AMP. NAD(H) and analogues, NADP, 5'-AMP, 5'-ADP, and 2'-AMP/3'-AMP mixed isomers protected TH against inhibition by FSBA, but NADPH accelerated the inhibition rate. In the absence of protective ligands or in the presence of NADP, FSBA appeared to modify the NAD(H) binding site of TH, because, unlike unmodified TH, the enzyme modified by FSBA under these conditions did not bind to an NAD-affinity column (NAD-agarose). However, when the NAD(H) binding site of TH was protected in the presence of 5'-AMP or NAD, then FSBA modification resulted in an inhibited enzyme that did bind to NAD-agarose, suggesting FSBA modification of the NADP(H) binding site or an essential residue outside the active site. [3H]FSBA was covalently bound to TH, and complete inhibition corresponded to the binding of about 0.5 mol of [3H]FSBA/mol of TH. Since purified TH is known to be dimeric in the isolated state, this binding stoichiometry suggests half-of-the-sites reactivity. A similar binding stoichiometry was found earlier for complete inhibition of TH by [14C]DCCD [Phelps, D.C., & Hatefi, Y. (1984) Biochemistry 23, 4475-4480]. The active site directed labeling of TH by radioactive FSBA should allow isolation of appropriate peptides for sequence analysis of the NAD(H) and possibly the NADP(H) binding domains.     

Modification of rabbit muscle phosphorylase b by a water-soluble carbodiimide.

Glycogen phosphorylase b from rabbit muscle was rapidly inactivated by incubation with 1-cyclohexyl-3-(2-morpholinyl-(4)-ethyl)carbodiimide metho-p-toluenesulfonate (CMC) at pH 5.1. The inactivation was pH-dependent and was not restored by treatment with hydroxylamine. The addition of glycine ethyl ester or N-(2,4-dinitrophenyl)-ethylenediamine (DNP-EDA) markedly increased the rate of inactivation. Of the various amino analogs of glucose tested, only glucosyl amine accelerated the inactivation, although they are all bound to the glucose 1-phosphate site of the enzyme. In the absence of amines, incorporation of about 3 mol of [metho-14C]CMC per protein monomer was observed on complete inactivation. In the presence of DNP-EDA, however, only 2 mol of [metho-14C]CMC and 1 mol of DNP-EDA were incorporated before the activity was completely lost. The treatment of phosphorylase b with CMC did not change the Km values of the enzyme for glucose 1-phosphate and AMP, in spite of the 56% inactivation. It is suggested that, in the phosphorylase-catalyzed reaction, an essential carboxyl group of the enzyme plays a role in the protonation of the glucosidic oxygen of glucose 1-phosphate.     

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.     

The mechanisms of inhibition of anion exchange in human erythrocytes by 1-ethyl-3-[3-(trimethylammonio)propyl]carbodiimide

Treatment of human erythrocytes with the membrane-impermeant carbodiimide 1-ethyl-3-[3-(trimethylammonio)propyl]carbodiimide (ETC) in citrate-buffered sucrose leads to irreversible inhibition of phosphate-chloride exchange. The level of transport inhibition produced was dependent on the concentration of citrate present during treatment, with a maximum of approx. 60% inhibition. [14C]Citric acid was incorporated into Band 3 (Mr = 95,000) in proportion to the level of transport inhibition, reaching a maximum stoichiometry of 0.7 mol citrate per mol Band 3. The citrate label was localized to a 17 kDa transmembrane fragment of the Band 3 polypeptide. Citrate incorporation was prevented by the transport inhibitors 4,4'-diisothiocyano- and 4,4'-dinitrostilbene-2,2'-disulfonate. ETC plus citrate treatment also dramatically reduced the covalent labeling of Band 3 by [3H]4,4'-diisothiocyano-2,2'-dihydrostilbene disulfonate (3H2DIDS). Noncovalent binding of stilbene disulfonates to modified Band 3 was retained, but with reduced affinity. We propose that the inhibition of anion exchange in this case is due to carbodiimide-activated citrate modification of a lysine residue in the stilbenedisulfonate binding site, forming a citrate-lysine adduct that has altered transport function. The evidence is consistent with the hypothesis that the modified residue may be Lys a, the lysine residue involved in the covalent reaction with H2DIDS. Treatment of erythrocytes with ETC in the absence of citrate resulted in inhibition of anion exchange that reversed upon prolonged incubation. This reversal was prevented by treatment in the presence of hydrophobic nucleophiles, including phenylalanine ethyl ester. Thus, inhibition of anion exchange by ETC in the absence of citrate appears to involve modification of a protein carboxyl residue(s) such that both the carbodiimide- and the nucleophile-adduct result in inhibition.     

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.     

Optimum modification for the highest cytotoxicity of cationized ribonuclease

Cationization of a protein is considered to be a powerful strategy for internalizing a functional protein into cells. Cationized proteins appear to adsorb to the cell surface by electrostatic interactions, then enter the cell in a receptor- and transporter-independent fashion. Thus, in principle, all cell types appear to take up cationized proteins. Since ribonucleases (RNases) have a latent cytotoxic potential, cationized RNases could be useful cancer chemotherapeutics. In this study, we investigated the effect of the degree of cationization on the cytotoxicity of RNase A by modifying carboxyl groups with ethylenediamine. We found that there is an optimum degree of modification for cytotoxicity, in which 5 to 7 out of 11 carboxyl groups in RNase A are modified, toward MCF-7 and 3T3-SV-40 cells. More interestingly, the cytotoxicity of cationized RNase As correlates well with the value of [RNase activity] x [estimated concentration of RNase free from RNase inhibitor], mimicking the practical enzymatic activity of cationized RNase As in cytosol. The results indicate that cationization of a protein to an optimum level is important for maintaining protein function in the cytosol. Sophisticated protein cationization techniques will help to advance protein transduction technology.     

Native Enzyme Mobility Shift Assay (NEMSA): a new method for monitoring carboxyl group modification of carboxymethylcellulase from Aspergillus niger

A simple, sensitive, accurate and more informative assay for determining the number of modified groups during the course of carboxyl group modification is described. Monomeric carboxymethylcellulase (CMCase) from Aspergillus niger was modified by 1-ethyl-3(3-dimethylaminopropyl)carbodiimide (EDC) in the presence of glycinamide. The different time-course aliquots were subjected to non-denaturing PAGE and the gel stained for CMCase activity. The number of carboxyl groups modified are directly read from the ladder of the enzyme bands developed at given time. This method showed that after 75 min of modification reaction there were five major species of modified CMCases in which 6 to 10 carboxyls were modified.     

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 an arginine residue of a base-nonspecific ribonuclease from Aspergillus saitoi.

1. A base-nonspecific ribonuclease from Aspergillus saitoi [RNase Ms, EC 3.1.4.23; molecular weight, 12,500] was modified with phenylglyoxal (PG) and 1,2-cyclohexanedione (CHD) in order to determine whether a single arginine residue was involved in the active site of the enzyme. 2. RNase Ms was inactivated by both PG and CHD with concomitant loss of one arginine residue. A competitive inhibitor of RNase Ms, 2',(3')-AMP, protected the enzyme from inactivation by PG. These findings strongly suggest that one arginine residue is involved in the active site of RNase Ms. 3. Difference CD spectra were measured at pH 5.5 for the binding of 2'-AMP and adenosine to native RNase Ms and the CHD- and PG-modified enzyme derivatives to determine the association constants. The arginine modification brought about a marked decrease in the binding affinity of 2'-AMP for the enzyme, but only a slight decrease for adenosine, suggesting that the arginine residue had interacted with the phosphate groups of the substrate.     

Chemical modification of N6-(N-threonylcarbonyl) adenosine. Part II. Condensation of the carboxyl group with amines.

Carboxyl group of N6-/N-threonylcarbonyl/adenosine was quantitatively modified with amines/aniline, glycine ethyl ester and ethylenediamine/in the presence of a water-soluble carbodiimide, yielding the respective amides. The reaction was carried out in a water solution of pH about 4 at 20 degrees C and was finished within minutes. The structure of the products was confirmed by UV and PMR spectra, and by chemical reactivity. Under conditions applied for modification of T6A, four common nucleosides and internucleotide linkage of UpA were unreactive, while 5'-AMP was transformed to the respective phosphoramides. At pH 4, the rate of 5'-AMP modification was over 100 times lower than the rate of t6A reaction.