Evidence for two histidine ligands at the diiron site of methane monooxygenase.

Circular dichroism spectroscopy has shown the hydroxylase component of methane monooxygenase to have a high helical content. The apoprotein has the same secondary structure as the holoenzyme. Chemical modification shows 12 histidines to be reactive with diethylpyrocarbonate in the holoenzyme, whereas 14 are reactive in the apoenzyme. Two histidine residues are implicated as iron ligands. Further chemical modification results suggest a cysteine residue is in close proximity to the diiron centre.     

Structural role of histidine residues in NAD(P)-glutamate dehydrogenase from the bovine liver

Photooxidation of bovine liver glutamate dehydrogenase (GDH, EC 1.4.1.3) in the presence of methylene blue at a low light intensity occurs in two stages. At the first stage, the duration of which depends on temperature and dye concentration, a slight activation is observed simultaneously with the oxidation of two histidine residues. At the second stage, the inactivation is concomitant with the oxidation of three histidine and one tryptophan residues. The inactivation is a first order reaction (k = 3,22 X 10(-2) min-1) and is correlated with changes in the circular dichroism spectra. These data testify to the structural role of histidine residues in the GDH molecule. The kinetic behaviour of GDH during its modification with diethylpyrocarbonate (DEP) depends on pH and the reagent concentration. Four histidine residues undergo carbethoxylation at pH 6.0 and 7.5, but the modification rate is much higher at pH 7.5. At low DEP concentrations, a remarkable activation is observed with a simultaneous modification of one histidine residue, which is independent of pH. At high DEP concentrations, a rapid inactivation takes place at pH 7.5. Treatment of the carbethoxylated inactive enzyme with hydroxylamine results in the deacylation of histidine residues without any noticeable reactivation. The data on the combined effect of DEP and pyridoxal-5'-phosphate suggest that GDH inactivation by DEP at pH 7.5 is a result of modification of an essential epsilon-NH2 group of lysine-126.     

The incorporation of divalent metal ions into recombinant human tyrosine hydroxylase apoenzymes studied by intrinsic fluorescence and 1H-NMR spectroscopy.

Three isoforms of human tyrosine hydroxylase were expressed in Escherichia coli and purified to homogeneity as the apoenzymes (metal-free). The apoenzymes exhibit typical tryptophan fluorescence emission spectra when excited at 250-300 nm. The emission maximum (342 nm) was not shifted by the addition of metal ions, but reconstitution of the apoenzymes with Fe(II) at pH 7-9 reduced the fluorescence intensity by about 35%, with an end point at 1.0 iron atom/enzyme subunit. The fluorescence intensity of purified bovine adrenal tyrosine hydroxylase, containing 0.78 mol tightly bound iron/mol subunit, was reduced by only 6% on addition of an excess amount of Fe(II). Other divalent metal ions [Zn(II), Co(II), Mn(II), Cu(II) and Ni(II)] also reduced the fluorescence intensity of the human enzyme by 12-30% when added in stoichiometric amounts. The binding of Co(II) at pH 7.2 was also found to affect its 1H-NMR spectrum and this effect was reversed by lowering the pH to 6.1. The quenching of the intrinsic fluorescence of the human isoenzymes by Fe(II) was reversed by the addition of metal chelators. However, the addition of stoichiometric amounts of catecholamines, which are potent feedback inhibitors of tyrosine hydroxylase, to the iron-reconstituted enzyme, prevented the release of iron by the metal chelators. Fluorescence quenching, nuclear magnetic relaxation measurements and EPR spectroscopy all indicate that the reconstitution of an active holoenzyme from the isolated apoenzyme, with stoichiometric amounts of Fe(II) at neutral pH, occurs without a measurable change in the redox state of the metal. However, on addition of dopamine or suprastoichiometric amounts of iron, the enzyme-bound iron is oxidized to a high-spin Fe(III) (S = 5/2) form in an environment of nearly axial symmetry, thus providing an explanation for the inhibitory action of the catecholamines.     

Iron coordination geometry in full-length, truncated, and dehydrated forms of human tyrosine hydroxylase studied by Mössbauer and X-ray absorption spectroscopy

Full-length human tyrosine hydroxylase 1 (hTH1) and a truncated enzyme lacking the 150 N-terminal amino acids were expressed in Escherichia coli and purified either with or without (6×histidine) N-terminal tags. After reconstitution with ⁵⁷Fe(II), the Mössbauer and X-ray absorption spectra of the enzymes were compared before and after dehydration by lyophilization. Before dehydration, >90% of the iron in hTH1 had Mössbauer parameters typical for high-spin Fe(II) in a six-coordinate environment [isomer shift δ(1.8–77?K)=1.26–1.24?mm s^–1 and quadrupole splitting ΔE _Q=2.68?mm s^–1]. After dehydration, the Mössbauer spectrum changed and 63% of the area could be attributed to five-coordinate high-spin Fe(II) (δ=1.07?mm s^–1 and ΔE _Q=2.89?mm s^–1 at 77?K), whereas 28% of the iron remained as six-coordinate high-spin Fe(II) (δ=1.24?mm s^–1 and ΔE _Q=2.87?mm s^–1 at 77?K). Similar changes upon dehydration were observed for truncated TH either with or without the histidine tag. After rehydration of hTH1 the spectroscopic changes were completely reversed. The X-ray absorption spectra of hTH1 in solution and in lyophilized form, and for the truncated protein in solution, corroborate the findings derived from the Mössbauer spectra. The pre-edge peak intensity of the protein in solution indicates six-coordination of the iron, while that of the dehydrated protein is typical for a five-coordinate iron center. Thus, the active-site iron can exist in different coordination states, which can be interconverted depending on the hydration state of the protein, indicating the presence or absence of a water molecule as a coordinating ligand to the iron. The present study explains the difference in iron coordination determined by X-ray crystallography, which has shown a five-coordinate iron center in rat TH, and by our recent spectroscopic study of human TH in solution, which showed a six-coordinated iron center.     

Regulation of recombinant human tyrosine hydroxylase isozymes by catecholamine binding and phosphorylation. Structure/activity studies and mechanistic implications.

Three isozymes of human tyrosine hydroxylase (hTH1, hTH2 and hTH4) were expressed in Escherichia coli and purified to homogeneity. Natural catecholamines and related synthetic compounds were found to be potent inhibitors, competitive to the tetrahydrobiopterin cofactor, of all the isozymes. Combining visible spectroscopy and equilibrium-binding studies, it was found that catecholamines bind to hTH1 and hTH2 with a stoichiometry of about 1.0 mol/mol enzyme subunit, interacting with the catalytic iron at the active site. All the isozymes tested were excellent substrates for cAMP-dependent protein kinase (Km = 5 microM, Vmax = 9.5 mumol.min-1.mg kinase-1). The incorporation of about 1.0 mol phosphate/subunit at Ser40 decreased the affinity of dopamine binding by a factor of 10. Conversely, the addition of stoichiometric amounts of Fe(II) and dopamine to the apoenzymes reduced both the affinity and stoichiometry of phosphorylation by cAMP-dependent protein kinase by 2-3-fold. These data provide evidence for a mutual interaction between the presumed regulatory and catalytic domains of hTH, and show that activation of the enzyme by phosphorylation and inactivation by binding of catecholamines are related events, which probably represent important mechanisms for the regulation of the enzyme activity in vivo.     

Identification of essential histidines in cyclodextrin glycosyltransferase isoform 1 from Paenibacillus sp. A11

The isoform 1 of cyclodextrin glycosyltransferase (CGTase, EC 2.4.1.19) from Paenibacillus sp. A11 was purified by a preparative gel electrophoresis. The importance of histidine, tryptophan, tyrosine, and carboxylic amino acids for isoform 1 activity is suggested by the modification of the isoform 1 with various group-specific reagents. Activity loss, when incubated with diethylpyrocarbonate (DEP), a histidine modifying reagent, could be protected by adding 25 mM methyl-beta-cyclodextrin substrate prior to the modification. Inactivation kinetics of isoform 1 with DEP resulted in second-order rate constants (k(inactivation)) of 29.5 M(-1)s(-1). The specificity of the DEP-modified reaction for the histidine residue was shown by the correlation between the loss of isoform activity and the increase in the absorbance at 246 nm of N-carbethoxyhistidine. The number of histidines that were modified by DEP in the absence and presence of a protective substrate was estimated from the increase in the absorbance using a specific extinction coefficient of N-carbethoxyhistidine of 3,200 M(-1)cm(-1). It was discovered that methyl-beta-CD protected per mole of isoform 1, two histidine residues from the modification by DEP. To localize essential histidines, the native, the DEP-modified, and the protected forms of isoform 1 were digested by trypsin. The resulting peptides were separated by HPLC. The peptides of interest were those with R(t) 11.34 and 40.93 min. The molecular masses of the two peptides were 5,732 and 2,540 daltons, respectively. When the data from the peptide analysis were checked with the sequence of CGTase, then His-140 and His-327 were identified as essential histidines in the active site of isoform 1.     

Modification of pig liver dimeric dihydrodiol dehydrogenase with diethylpyrocarbonate and by rose bengal-sensitized photooxidation: evidence for an active-site histidine residue.

Dihydrodiol dehydrogenase from pig liver was inactivated by diethylpyrocarbonate (DEP) and by rose bengal-sensitized photooxidation. The DEP inactivation was reversed by hydroxylamine and the absorption spectrum of the inactivated enzyme indicated that both histidine and tyrosine residues were carbethoxylated. The rates of inactivation by DEP and by photooxidation were dependent on pH, showing the involvement of a group with a pKa of 6.4. The kinetics of inactivation and spectrophotometric quantification of the modified residues suggested that complete inactivation was caused by modification of one histidine residue per active site. The inactivation by the two modifications was partially prevented by either NADP(H) or the combination of NADP+ and substrate, and completely prevented in the presence of both NADP+ and a competitive inhibitor which binds to the enzyme-NADP+ binary complex. The DEP-modified enzyme caused the same blue shift and enhancement of NADPH fluorescence as did the native enzyme, suggesting that the modified histidine is not in the coenzyme-binding site of the enzyme. The results suggest the presence of essential histidine residues in the catalytic region of the active site of pig liver dihydrodiol dehydrogenase.     

Role of tyrosine residues in mitochondrial aspartate aminotransferase from beef kidney.

Mitochondrial aspartate aminotransferase from beef kidney is 50% inhibited after 2 hr treatment with 2.5 mM tetranitromethane at pH 8. Two tyrosine residues per enzyme protomer (46,000 daltons) are modified by the reagent either in the holoenzyme or in the apoenzyme. In both cases the five SH groups titratable with p-mercuribenzoate are not modified by the reagent. However, with a tetranitromethane concentration higher than 2.5 mM and 10 mM mercaptoethanol, an additional tyrosine residue is nitrated in both holo- and apoenzymes. These results are not affected by the presence in the incubation mixture of the substrates alpha-ketoglutarate and glutamate both at ten times their Km values. Mercaptoethanol does not impair the recombination of native or nitrated apoenzyme with the coenzyme and does not reduce the coenzyme moiety of native or nitrated holoenzyme, but promotes a conformational change in the nitrated holoenzyme which causes inactivation. Hydrosulfite promotes the reduction of the coenzyme moiety of native and nitro holoenzyme resulting in their inactivation, largely in the nitrated form. The recombination of the coenzyme with native or nitrated apoenzyme is not influenced by hydrosulfite.     

Chemical modifications of histidine residues in cytoplasmic asparate aminotransferase from beef kidney

Summary Holo and apoenzyme of aspartate aminotransferase from beef kidney are 80% inactivated by photoxidation in the presence of 2 × 10^–6 m tetraiodofluroescein with the modification of two histidine residues per enzyme protomer. At a higher concentration (1 × 10^–5 m) a tyrosine residue is also modified. The keto substrates, ketoglutarate and oxalacetate, protect the enzyme from photoxidation.Diethylpyrocarbonate modifies three histidine residues per enzyme protomer and reduces the activity only 10%. These results suggest that the two histidine residues photoxidized through the sensitizer, are located in the active site of the enzyme, at least one of these appears to be involved in ketosubstrate binding. The other three histidines modified by diethylpyrocarbonate are likely located on the enzyme surface and are not involved in the catalytic activity of the enzyme.This work is part of a program supported by a grant from the Consiglio Nazionale delle Ricerche.     

Histidine residues at the active site of maize δ-aminolevulinic acid dehydratase

Modification of maize δ-aminolevulinic acid dehydratase (ALAD) by diethylpyrocarbonate (DEP) caused rapid and complete inactivation of the enzyme. The inactivation showed saturation kinetics with a half inactivation time at saturating DEP equal to 0.3 min and K_DEP  0.3 mM. Substrate δ-aminolevulinic acid (ALA) and competitive inhibitor levulinic acid protected against inactivation, thereby indicating that DEP modifies the active site. The modified enzyme showed an increase in absorbance at 240 nm which was lost upon treatment with 0.8 M hydroxylamine. Most of the activity lost by DEP treatment could be restored after treatment with 0.8 M hydroxylamine. The results suggest that DEP modifies 7.4 residues/mole of the enzyme. These histidine residues are essential for catalysis by ALAD.     

Chemical modification of sheep-liver 6-phosphogluconate dehydrogenase by diethylpyrocarbonate. Evidence for an essential histidine residue

Sheep liver 6-phosphogluconate dehydrogenase is shown to be inactivated by diethylpyrocarbonate in a biphasic manner at pH 6.0, 25 degrees C. After allowing for the hydrolysis of the reagent, rate constants of 56 M-1 s-1 and 11.0 M-1 s-1 were estimated for the two processes. The complete reactivation of partially inactivated enzyme by neutral hydroxylamine, the elimination of the possibility that modification of cysteine or tyrosine residues are responsible for inactivation, and the magnitudes of the rate constants for inactivation relative to the experimentally determined value for the reaction of diethylpyrocarbonate with N alpha-acetylhistidine (2.2 M-1 s-1), all suggested that enzyme inactivation occurs solely by modification of histidine residues. Comparison of the experimental plot of residual fractional activity versus the number of modified histidine residues per subunit with simulated plots for three hypothetical models, each predicting biphasic kinetics, indicated that inactivation results from the modification of at most one essential histidine residue per subunit, although it appears that other (non-essential) histidines react independently. This histidine is thought to be His-242 and is present in the active site. Evidence in support of its role in catalysis is briefly discussed. Both 6-phosphogluconate and organic phosphate protect against inactivation, and a kinetic analysis of the protection indicated a dissociation constant of 2.1 X 10(-6) M for the enzyme--6-phosphogluconate complex. NADP+ also protected, but this might be due, at least in part, to a reduction in the effective concentration of diethylpyrocarbonate.     

Vitamin K2 (menaquinone) biosynthesis in Escherichia coli: evidence for the presence of an essential histidine residue in o-succinylbenzoyl coenzyme A synthetase.

o-Succinylbenzoyl coenzyme A (OSB-CoA) synthetase, when treated with diethylpyrocarbonate (DEP), showed a time-dependent loss of enzyme activity. The inactivation follows pseudo-first-order kinetics with a second-order rate constant of 9.2 x 10(-4) +/- 1.4 x 10(-4) microM(-1) min(-1). The difference spectrum of the modified enzyme versus the native enzyme showed an increase in A242 that is characteristic of N-carbethoxyhistidine and was reversed by treatment with hydroxylamine. Inactivation due to nonspecific secondary structural changes in the protein and modification of tyrosine, lysine, or cysteine residues was ruled out. Kinetics of enzyme inactivation and the stoichiometry of histidine modification indicate that of the eight histidine residues modified per subunit of the enzyme, a single residue is responsible for the enzyme activity. A plot of the log reciprocal of the half-time of inactivation against the log DEP concentration further suggests that one histidine residue is involved in the catalysis. Further, the enzyme was partially protected from inactivation by either o-succinylbenzoic acid (OSB), ATP, or ATP plus Mg2+ while inactivation was completely prevented by the presence of the combination of OSB, ATP, and Mg2+. Thus, it appears that a histidine residue located at or near the active site of the enzyme is essential for activity. When His341 present in the previously identified ATP binding motif was mutated to Ala, the enzyme lost 65% of its activity and the Km for ATP increased 5.4-fold. Thus, His341 of OSB-CoA synthetase plays an important role in catalysis since it is probably involved in the binding of ATP to the enzyme.     

NADPH- and NADH-nitrate reductases from soybean leaves.

Treatment of rabbit hemopexin with bromoacetic acid (BrAc) or with diethylpyrocarbonate (DEP) modified histidine residues and produced a concomitant decrease in the protein's ability to form a low-spin hemichrome complex with deuteroheme (ferrideuteroporphyrin IX). Deuteroheme bound to hemopexin before treatment decreased the extent of inactivation by either reagent. After exposure of deuteroheme-hemopexin to 0.16 m BrAc at pH 6.9 for 120 h, 10–11 of the 16 histidine residues of hemopexin were carboxymethylated, but 90–95% of the deuteroheme-hemopexin complex remained intact. Under the same conditions, 12 histidine residues of apo-hemopexin were carboxymethylated, and 95% of the protein's ability to form its normal hemichrome complex with heme (ferriprotoporphyrin IX) was abolished. The alkylated apo-protein, however, did retain a potential to interact with deuteroheme. The apparent dissociation constants for the complexes of metal-free deuteroporphyrin and deuteroheme with BrAc-treated apo-hemopexin were both about 10^?6m and nearly equal to that of the native deuteroporphyrin-hemopexin complex, as assessed by quenching of tryptophan fluorescence.Approximately 10 histidyl residues of the deuteroheme-hemopexin complex, but only about 4 residues of the apo-protein, were modified by DEP before heme-binding was appreciably affected. The effects of DEP on hemopexin were reversed by hydroxylamine at neutral pH, indicating that ethoxyformylation of histidine residues caused the observed inactivation of hemopexin. This and the results of BrAc treatment suggest that hemopexin contains several easily accessible histidine residues which are not critical for its interaction with heme.The conformation-sensitive positive ellipticity at 231 nm of hemopexin was affected by carboxymethylation and ethoxyformylation. Treatment with BrAc had only a small effect on the intrinsic ellipticity of apo-hemopexin, but eliminated the increase in ellipticity produced by interaction of unmodified hemopexin with heme. Treatment with DEP, on the other hand, decreased both intrinsic and extrinsic ellipticity.These results provide further evidence that the heme-hemopexin complex involves histidyl-heme iron coordination. In addition, they show that formation of the histidyl-heme complex not only greatly enhances the strength of the heme-hemopexin interaction but also is important for triggering conformational changes in the protein.     

Diethylpyrocarbonate inhibition of sodium-glucose cotransport in kidney brush-border membrane vesicles

Exposure of kidney brush-border membrane vesicles to the acylating reagent diethylpyrocarbonate resulted in inactivation of the glucose transporter, as demonstrated by inhibition of sodium-coupled D-glucose transport and phlorizin binding. The transport site(s) was protected against inactivation by the simultaneous presence of sodium ions and D-glucose, and were partially protected by phlorizin. Transport activity was not restored by hydroxylamine; this rules out the possibility of diethylpyrocarbonate interaction with histidine, serine or tyrosine transporter residues. Dithiothreitol, a thiol protector, slightly prevented diethylpyrocarbonate inactivation. It is therefore suggested that (an) amino group(s) in the translocation complex is involved, at the level of the sugar transport site and the preferential protection of D-glucose against diethylpyrocarbonate inactivation related to a conformation change caused by the simultaneous binding of sodium and D-glucose to the cotransporter.     

Chemical modification of dopamine beta-hydroxylase

Dopamine beta-hydroxylase (3,4- dihydroxyphenylethylamine ,ascorbate:oxygen oxidoreductase (beta-hydroxylating), EC 1.14.17.1) is the terminal enzyme in the biosynthetic pathway of norepinephrine. Chemical modification studies of this enzyme were executed to investigate contributions of specific amino-acid side-chains to catalytic activity. Sulfhydryl reagents were precluded, since no free cysteine residue was detected upon titration of the denatured or native protein with 2-chloromercuri-4-nitrophenol. Incubation of enzyme with diazonium tetrazole caused inactivation of the protein coupled with extensive reaction of lysine and tyrosine residues. Reaction with iodoacetamide resulted in complete loss of enzymatic activity with reaction of approximately three histidine residues; methionine reaction was also observed. Modification of the enzyme using diethylpyrocarbonate resulted in complete inactivation of the enzyme, and analysis of the reacted protein indicated a loss of approx. 1.7 histidine residues per protein monomer with no tyrosine or lysine modification observed. The correlation of activity loss with histidine modification supports the view that this residue participates in the catalytic function of dopamine beta-hydroxylase.     

Kinetics of inactivation of phytase (phy A) during modification of histidine residue by IAA and DEP

Chemical probing of histidine residues using specific modifiers, iodoacetic acid (IAA) and diethylpyrocarbonate (DEP) resulted in the inactivation of phytase (phy A). The kinetic theory of the substrate reaction during the modification of enzyme activity was applied to a study of the kinetics of the course of inactivation of phytase by IAA and DEP. The results suggested that histidine residues are involved in the active site of the enzyme. They also indicated that inactivation of the enzyme by IAA was via a complexing type inhibition, while the inhibition by DEP reaction involved a conformational change step before inactivation. The dissociation constant of the enzyme-inhibitor complex of IAA, the constant of the conformational change of DEP and the microscopic rate constants of two inhibitors were obtained.     

Studies of histidine residues in soybean (Glycine max) urease

Soybean urease has been investigated extensively to reveal the presence of histidine residue (s) in the active site and their potential role in the catalysis. The spectrophotometric studies using diethylpyrocarbonate (DEP) showed the modification of 11.76 ± 0.1 histidine residues per mole of native urease. Therefore, the results are indicative of the presence of twelve histidine residues per urease molecule. It is presumed that the soybean urease, being a hexameric protein possess two histidine residues per subunit. Correlation plot showed that the complete inactivation of soybean urease corresponds to the modification of 1.97 histidine residues per subunit. Further, double logarithmic plot of kapp versus DEP concentration has resulted in a linear correlation and thereby demonstrating that only one of the two histidine residues per subunit is catalytically essential. Significant protection has been observed against inactivation when urea or acetohydroxamate (AHA) is incubated with DEP treated urease. The studies have demonstrated the presence of one histidine residue at the active site of soybean urease and its significance in catalysis.     

Evidence for the participation of histidine residues located in the 56 kDa C-terminal polypeptide domain of ADP-ribosyl transferase in its catalytic activity

Purified ADPRT protein was inactivated by the histidine specific reagent diethylpyrocarbonate, binding to two histidine residues, or by a relatively histidine selective photoinactivation method. Inactivation with up to 1.3 mM diethylpyrocarbonate was reversible by hydroxylamine. Enzymatic inactivation coincided with the loss of binding capacity of the enzyme protein to benzamide affinity matrix but not to DNA cellulose. Labelled diethylpyrocarbonate was identified exclusively in the 56 kDa carboxyl-terminal polypeptide where 2 out of 13 histidine residues were modified by this reagent. It is proposed that histidine residues in the 56 kDa polypeptide may participate as initiator sites for polyADP-ribosylation.     

Presence of essential histidine residues in nadp-malic enzyme from maize

Modification of maize leaf NADP-malic enzyme by diethylpyrocarbonate (DEP) caused rapid and complete inactivation of the enzyme. The inactivation followed pseudo-first-order reaction kinetics. The inactivation of the enzyme showed saturation kinetics with a half inactivation time, at saturating DEP, equal to 0.15 min and K_DEP = 20 mM. The rate of inactivation was faster at 25° as compared to 0° (t_0.5 0.75 min at 25° as against 5.6 min at 4° at 5 mM DEP). The enzyme was partially protected against DEP inactivation by NADP and complete protection was seen in the presence of NADP + Mg²⁺ + malate or its analogues, thereby indicating that DEP modifies the active site. The modified enzyme showed an increase in absorbance at 240 nm which was lost upon treatment with 0.25 M NH₂OH and almost complete recovery of the enzyme activity was also observed. The results suggest that DEP modifies 3.0 residues per subunit and of these at least two residue per subunit can be modified without loss of activity in the presence of substrate. Modification of about one histidine residue is correlated with the loss of enzyme activity.     

Chemical modification of cyclomaltodextrin glucanotransferase from Bacillus circulans var. alkalophilus.

Counting of integral numbers of cysteine residues of the reduced and denaturated form of cyclomaltodextrin glucanotransferase (CGTase) from Bacillus circulans var. alkalophilus (ATCC 21783) showed two cysteine residues per enzyme molecule. Titrations of the enzyme with 5,5'-dithiobis-(2-nitrobenzoic acid) led to the same result. No free SH-group was detected in denatured form of CGTase, indicating that the two cysteine residues are linked by one disulfide bridge. Cyclizing activity of the GdmCl-denaturated and reduced enzyme was 13% of that of the native one. Incubation of CGTase with diethylpyrocarbonate (DEP) showed a pseudo-first-order inhibition with second-order rate constant of 3.2 M-1 s-1. Reaction with hydroxylamine and spectroscopic studies implied that inactivation of CGTase by DEP is due to modification of one histidine residue concomitantly with a 50% decrease in the cyclizing activity (t1/2 = 10.8 min). The inhibition was partially reversible. CGTase was protected against inactivation by alpha- and beta-cyclodextrins suggesting that the modified histidine residue is at or near the active site. Conversion of starch with DEP-modified enzyme resulted in a decreased formation of cyclodextrins while the relative amount of reducing sugars increased. Preliminary results on modification of CGTase with other reagents, e.g., Woodward's reagent K, 2,3-butanedione and carbodiimide are included.