Diethyl pyrocarbonate inactivates CD39/ecto-ATPDase by modifying His-59

Diethyl pyrocarbonate (DEPC) in conditions that favour carbethoxylation of histidyl residues strongly inactivated E-type ATPase activity of a rat lung membrane preparation, as well as ecto-ATPase activity of rat vessels and human Epstein-Barr virus-transformed B lymphocytes. Inactivation of the enzyme (up to 70%) achieved at concentrations of DEPC below 0.5 mM could be fully reversed by 200 mM hydroxylamine at pH 7.5, thus confirming histidine-selective modification. UTP effectively protected the enzyme activity from DEPC inactivation. This was taken to indicate that the conformation adopted by the enzyme molecule upon substrate binding was not compatible with DEPC reaching and/or modifying the relevant histidyl residue. Substrate activation curves were interpreted to show the enzyme molecule to be inactive, at all substrate concentrations tested, when the target histidyl residue had been modified by DEPC. Comparison of known sequences of CD39-like ecto-ATP(D)ases with the results on inactivation by DEPC revealed His-59 and His-251 (according to the human CD39 sequence) as equally possible targets of the inactivating DEPC modification. Potato apyrase lacks a homologue for the former residue, while the latter is preserved in the enzyme sequence. Therefore, this enzyme was exposed to DEPC, and since hydrolysis of ATP and ADP by potato apyrase was insensitive to modification with DEPC, it was concluded that His-59 is the essential residue in CD39 that is affected by DEPC modification in a way that causes inactivation of the enzyme.     

Reaction of Ascaris suum phosphofructokinase with diethylpyrocarbonate. Inactivation and desensitization to allosteric modulation

Reaction of the phosphofructokinase from Ascaris suum with the reagent, diethylpyrocarbonate (DEPC), results in the loss of enzymatic activity. Treatment of the inactivated enzyme with hydroxylamine brings about the recovery of almost 80% of the original activity suggesting that the modified residues are histidines. Further evidence for the modification of histidines is that concomitant with the loss of activity, there is a change in A242 nm that corresponds to the derivatization of 5-6 histidines per subunit. There is no change in A278 nm during the derivatization process, thereby ruling out the modification of tyrosines by DEPC. Analyses of the first order inactivation rate constant for DEPC derivatization at different pH values resulted in the determination of a pKa of 6.4 +/- 0.1 for the group on the enzyme that reacts with DEPC. Derivatization of the enzyme with DEPC in the presence of fructose 6-phosphate (Fru-6-P) protected the enzyme against inactivation by 80%. ATP or MgATP gave no protection against DEPC inactivation. When the Fru-6-P-protected enzyme was further reacted with DEPC in the absence of Fru-6-P, a total of 2 histidines were modified per subunit, and the derivatization of one of these could be correlated with activity loss. When the phosphofructokinase that had been derivatized by DEPC in the presence of Fru-6-P was assayed, it was found that it no longer exhibited allosteric properties and appeared to be desensitized to ATP inhibition. This loss of ATP inhibition could be correlated with the modification of 2 histidines per subunit by DEPC. The first order rate constant for desensitization was determined at different pH values and a pKa value of 7.0 +/- 0.2 was obtained for the group(s) responsible for the desensitization. Regulatory studies with the desensitized enzyme revealed that the enzyme was not stimulated by AMP, NH4+, K+, phosphate, sulfate, or hexose bisphosphates. It is concluded that histidine may be involved both in the active site and the ATP inhibitory site of the ascarid phosphofructokinase.     

Active site characterization of the exo-N-acetyl-beta-D- glucosaminidase from thermotolerant Bacillus sp. NCIM 5120: involvement of tryptophan, histidine and carboxylate residues in catalytic activity

The exo-N-acetyl-beta-d-glucosaminidase (EC 3.2.1.30) from thermotolerant Bacillus sp. NCIM 5120 is a homotetramer with a molecular mass of 240000 kDa. Chemical modification studies on the purified exo-N-acetyl-beta-d-glucosaminidase revealed the involvement of a single tryptophan, histidine and carboxylate, per monomer, in the catalytic activity of the enzyme. Spectral analysis and maintenance of total enzyme activities indicated that N-acetylglucosamine (competitive inhibitor) and p-nitrophenyl-N-acetyl-beta-d-glucosaminide (substrate) prevented the modification of a single essential tryptophan, histidine and carboxylate residue. Kinetic parameters of partially inactivated enzyme (by NBS/HNBB) showed the involvement of tryptophan in substrate binding while that of histidine (by photooxidation/DEPC) and carboxylate (by EDAC/WRK) in catalysis. The Bacillus sp. NCIM 5120 exo-N-acetyl-beta-d-glucosaminidase deviates from the reported N-acetyl-beta-d-glucosaminidases and beta-hexosaminidases that utilize anchimeric assistance in their hydrolytic mechanism.     

Evidence for the involvement of histidine at the active site of glutathione S-transferase psi from human liver

The inhibition of catalytic activity of glutathione S-transferase psi (pI 5.5) of human liver by diethylpyrocarbonate (DEPC) has been studied. It is demonstrated that DEPC causes a concentration dependent inactivation of GST psi with a concomitant modification of 1-1.3 histidyl residues/subunit of the enzyme. This inactivation of GST psi could be reversed by treatment with hydroxylamine. Glutathione afforded complete protection to the enzyme from inactivation by DEPC. It is suggested that a functional histidyl residue is essential for the catalytic activity of the enzyme and that this residue is most likely to be present at or near the glutathione binding site (G-site).     

Proteolytic specificity of the neutral zinc proteinase from Bacillus mesentericus strain 76 determined by digestion of an alpha-globin chain

The proteolytic specificity of the neutral zinc proteinase from Bacillus mesentericus strain 76 (MCP 76)/Bacillus subtilis was determined by using the alpha-chain of walrus hemoglobin as substrate. The resulting peptides were fractionated by gel filtration and than isolated by reversed-phase HPLC. The peptides were identified on the basis of their amino-acid compositions and aligned with the known sequence of the walrus alpha-chain. The proteolytic specificity of MCP 76, deduced from the experimental cleavage pattern is compared to that of thermolysin. The amino-acid residues in positions P1 and P'1 on both sides of the scissible bond are considered as most important for the cleavage. MCP 76 prefers leucine, valine, phenylalanine and threonine in position P'1 as well as lysine, threonine, leucine and alanine in position P1 and thus differs from thermolysin which shows no preference for threonine in P'1 and accepts numerous amino-acid residues of different type in P1.     

Modification of the Red Beet Plasma Membrane H-ATPase by Diethylpyrocarbonate

Incubation of the red beet (Beta vulgaris L.) plasma membrane H⁺-ATPase with micromolar concentrations of diethylpyrocarbonate (DEPC) resulted in inhibition of both ATP hydrolytic and proton pumping activity. Enzyme activity was restored when DEPC-modified protein was incubated with hydroxylamine, suggesting specific modification of histidine residues. Kinetic analyses of DEPC inhibition performed on both membrane-bound and solubilized enzyme preparations suggested the presence of at least one essential histidine moiety per active site. Inclusion of either ATP (substrate) or ADP (product and competitive inhibitor) in the modification medium reduced the amount of inhibition observed in the presence of DEPC. However, protection was not entirely effective in returning activity to noninhibited control values. These results suggest that the modified histidine does not reside directly in the ATP binding region of the enzyme, but is more likely involved in enzyme regulation through subtle conformational effects.     

N-alpha-carbobenzoxy pyroglutamyl diazomethyl ketone as active-site-directed inhibitor for pyroglutamyl peptidase

Pyroglutamyl-peptidase (L-pyroglutamyl-peptide hydrolase, EC 3.4.19.3) from Bacillus amyloliquefaciens was covalently labeled with a newly synthesized N-carbobenzoxy-L-pyroglutamyl diazomethyl ketone (Z-PGDK) and was completely inactivated. The inactivation reaction proceeded in pseudo-first order. The kinetic studies demonstrated a rate-limiting step in the inhibition reaction, resulting in the formation of a reversible (enzyme.reagent) complex. The calculated KI,app is 0.12 mM at pH 7.58. The rate of inactivation was pH dependent with an extrapolated pK value of approx. 8.6. The enzyme could be protected against inactivation by a poor substrate, pyroglutamyl-valine. The PCMB-inactivated enzyme, that could be reversibly reactivated by mercaptoethanol, failed to react with Z-PGDK. The enzyme was insensitive toward the D-isomer of Z-PGDK and other diazomethyl ketone derivatives of carbobenzoxy amino acids such as Z-L-proline and Z-L-phenylalanine. These results strongly suggest that the Z-PGDK reacts as an affinity label, presumably with a cysteine residue as the site of alkylation in pyroglutamyl-peptidase, as was reported for chloromethyl ketone derivatives of pyroglutamic acid and its N-carbobenzoxy derivative.     

Purification and partial characterization of iodothyronine 5'-deiodinase from rat liver microsomes

We have isolated and purified iodothyronine 5'-deiodinase from rat liver microsomes to homogeneity as judged by PAGE and analytical HPLC. The enzyme progressively lost activity after solubilization, and specific activity enhancement was a modest 22-fold, but the final preparation still had substantial activity and was used for molecular characterization. The enzyme had an Mr of 56,000 with a single band in SDS-PAGE, suggesting absence of subunit structure. The high Km, and the GSH-responsive low Km, activities were co-purified, but the low Km enzyme lost GSH-responsiveness upon pretreatment with dithiothreitol (DTT) and urea. The enzyme was strongly inhibited by the iron chelator, alpha,alpha'-dipyridyl and showed a broad absorbance band at 410 nm. Spectral analysis with diethylpyrocarbonate (DEPC) revealed 5 histidine residues/mol enzyme, while enzyme activity was inhibited by DEPC in a pseudo-first order process with modification of 1 histidine residue/mol.     

An essential histidine residue in GTP binding domain of bovine brain glutamate dehydrogenase isoproteins

Greater than 90% of the original activity of the enzymes remained after modification of histidine residues of glutamate dehydrogenase (GDH) isoproteins from bovine brains with diethyl pyrocarbonate (DEPC). This suggests that the DEPC modified histidine residues are not critically involved in the catalysis of the GDH isoproteins. The influence of DEPC modified histidine residue(s) on binding of GTP to GDH isoproteins was investigated by protection studies. These studies showed that inhibition of GDH isoproteins by GTP was protected by preincubation of GDH isoproteins with DEPC. The amount of protection was dependent on the concentration of DEPC. The GTP inhibition was fully protected by preincubation of GDH isoproteins with DEPC at saturating concentrations. These results indicate that the histidine residues may play an important role in the GTP binding on GDH isoproteins. Spectrophotometric studies showed that three histidine residues per enzyme subunit were able to react with DEPC in the absence of GTP, whereas two histidine residues per enzyme subunit interacted with DEPC when the enzymes were preincubated with GTP. These results indicate that one of the histidine residues is involved in the GTP binding domain of GDH isoproteins. The quantitative affinity chromatographic studies showed that the influence of GTP on the binding of GDH isoproteins to DEPC-Sepharose was significantly distinct for the two GDH isoproteins. GDH I was more sensitively affected by GTP than GDH II in the binding affinity for DEPC-Sepharose. ADP, another well-known allosteric regulator, showed no significant changes in the interaction of DEPC with GDH isoproteins.     

Identification of essential histidine residues in 3-deoxy-D-manno-octulosonic acid 8-phosphate synthase: analysis by chemical modification with diethyl pyrocarbonate and site-directed mutagenesis

The enzyme 3-deoxy-D-manno-octulosonic acid 8-phosphate (KDO 8-P) synthase from Escherichia coli that catalyzes the aldol-type condensation of D-arabinose 5-phosphate (A 5-P) and phosphoenolpyruvate (PEP) to give KDO 8-P and inorganic phosphate (P(i)) is inactivated by diethyl pyrocarbonate (DEPC). The inactivation is first-order in enzyme and DEPC. A second-order rate constant of 340 M(-1) min(-1) is obtained at pH 7.6 and 4 degrees C. The rate of inactivation is dependent on pH and the pH-inactivation rate data imply the involvement of an amino acid residue with a pK(a) value of 7.3. KDO 8-P synthase activity is not restored to the DEPC-inactivated enzyme following treatment with hydroxylamine. Complete loss of KDO 8-P synthase activity correlates with the ethoxyformylation of three histidine residues by DEPC. KDO 8-P synthase is protected against DEPC inactivation by PEP and partially protected against inactivation by A 5-P. To provide further evidence for the involvement or role of the histidine residues in the aldol-type condensation catalyzed by KDO 8-P synthase, all six histidines were individually mutated to either glycine or alanine. The kinetic constants for the three mutants H40A, H67G, and H246G were unaffected as compared to the wild type enzyme. In contrast, H241G demonstrates a >10-fold increase in K(M) for both PEP and A 5-P and a 4-fold reduction in k(cat), while H97G demonstrates an increase in K(M) for only A 5-P and a 2-fold reduction in k(cat). The activity of the H202G mutant was too low to be measured accurately but the data obtained indicated an approximate 400-fold reduction in k(cat). Circular dichroism measurements of the wild-type and mutant enzymes indicate modest structural changes in only the fully active H67G and H246G mutants. The H241G mutant is protected against DEPC inactivation by PEP and A 5-P to the same extent as the wild-type enzyme, suggesting that the functionally important H241 may not be located in the vicinity of the substrate binding sites. The H97G mutant is protected by PEP against DEPC inactivation to the same degree as the wild-type enzyme but is no longer protected by A 5-P. In the case of the H202G mutant, both A 5-P and PEP protect the mutant against DEPC inactivation but to different extents from those observed for the wild-type enzyme. The catalytic activity of the H97G mutant is partially restored (20% --> 60% of wild-type activity) in the presence of imidazole, while a minor amount of activity is restored to the H202G mutant (<1% --> 4% of wild-type activity) in the presence of imidazole.     

A histidine residue at the active site of avian liver phosphoenolpyruvate carboxykinase

The histidine-selective reagents diethylpyrocarbonate (DEPC) and dimethylpyrocarbonate were used to study active site residues of phosphoenolpyruvate carboxykinase. Both reagents show pseudo first-order inhibition of enzyme activity at 22 +/- 1 degree C with calculated second-order rate constants of 2.8 and 4.6 M-1 s-1, respectively. The inhibition appears partially reversible. Substrates affect the rate of inhibition: KHCO3 enhances the rate, Mn2+ has little effect, and phosphoenolpyruvate decreases the rate. The best protection is obtained by IDP or IDP and Mn2+. The kinetic studies show that modification of histidine is specific and leads to loss of enzymatic activity. Two histidines per enzyme are modified by DEPC, as measured by an absorption change at 240 nm, in the absence of substrate, leading to loss in activity. One histidine per molecule is modified in the presence of KHCO3, giving inactivation. Cysteine and lysine residues are not affected. A study of the inhibition rate constant as a function of pH gives a pKa of 6.7. Enzyme modified by DEPC in the absence of substrate (1% remaining activity) shows no binding of ITP or of phosphoenolpyruvate to the enzyme.Mn2+ complex as studied by proton relaxation rates. When enzyme is modified in the presence of KHCO3 (44% remaining activity), ITP and KHCO3 bind to the enzyme.Mn2+ complex similarly to the binding to native enzyme. Phosphoenolpyruvate binding to modified enzyme.Mn results in an enhancement of proton relaxation rates rather than the decrease observed with native enzyme.Mn. The CD spectra of histidine-modified enzyme show a decrease in alpha-helical and random structure with an increase in anti-parallel beta-sheet structure compared to native enzyme. These results show that avian phosphoenolpyruvate carboxykinase has 2 histidine residues which are reactive with DEPC and dimethylpyrocarbonate, and one of the 15 histidine residues in the protein is at or near the phosphoenolpyruvate binding site and is involved in catalysis.     

Enzymatical properties of psychrophilic phosphatase I

Phosphatase I purified from a psychrophile (Shewanella sp.) [Tsuruta et al. (1998) J. Biochem. 123, 219-225] dephosphorylated O-phospho-L-tyrosine and phospho-tyrosyl residues in phosphorylated poly(Glu4,Tyr1) random polymer (polyEY) and phosphorylated myelin basic protein (MBP) but not phosphoseryl and/or phosphothreonyl residues in phosphorylated histone H1, casein and phosphorylase a, indicating that the enzyme showed protein-tyrosine-phosphatase (PTPase, EC 3.1.3.48)-like activity in vitro. The enzyme was remarkably inhibited by diethylpyrocarbonate (DEPC), monoiodoacetic acid (MIAA), and monoiodoacetamide (MIAM). Binding of 1 mol of DEPC to 1 mol of the enzyme caused complete inhibition of the enzyme; and 0.88 mol of 1-carboxymethylated histidine per mole of the enzyme was found when 90% of enzyme activity was lost by modification with 14C-MIAA. These results indicated that this psychrophilic enzyme was a PTPase-like enzyme with histidine as its catalytic residue.     

Evidence for essential histidine and dicarboxylic amino-acid residues in the active site of UDP-glucose : solasodine glucosyltransferase from eggplant leaves

Effects of several chemical probes selectively modifying various amino-acid residues on the activity of UDP-glucose : solasodine glucosyltransferase from eggplant leaves was studied. It was shown that diethylpyrocarbonate (DEPC), a specific modifier of histidine residues, was strongly inhibitory. However, in the presence of excessive amounts of the enzyme substrates, i.e. either UDP-glucose or solasodine, the inhibitory effect of DEPC was much weaker indicating that histidine (or histidines) are present in the active site of the enzyme. Our results suggest also that unmodified residues of glutamic (or aspartic) acid, lysine, cysteine, tyrosine and tryptophan are necessary for full activity of the enzyme. Reagents modifying serine and arginine residues have no effect on the enzyme activity.     

甲基对硫磷水解酶参与催化相关结构的研究

甲基对硫磷水解酶（MPH）是一种新的有机磷水解酶。将完整的甲基对硫磷水解酶基因（mpd）构建入pUC19载体,使得mpd基因以自身的启动子在Escherichia coli DH5α中表达并得到了纯化。金属螯合实验发现MPH的活性不受金属螯合剂1, 10菲NFDA1啉的影响;但用电感耦合等离子发射光谱测定其金属含量显示MPH是金属酶,1mol酶中结合了2mol的Zn²⁺。为确定参与MPH催化活性的必需氨基酸,用化学修饰剂碳化二亚胺、二乙基焦磷酸酯、磷酸吡哆醛和丁二酮处理MPH,然后检测其残余酶活力,结果表明天冬氨酸、谷氨酸、赖氨酸和精氨酸残基与酶的催化活性无关;而二乙基焦磷酸酯对组氨酸侧链的化学修饰引起酶活性的大幅度的下降,其对酶活性的抑制率达到9.6h^-1,说明组氨酸是酶活力所必需的基团。这些结果为进一步研究酶的结构及对酶进行分子改造提供了必要的基础数据。     

Histidine 268 in 3-deoxy-D-arabino-heptulosonic acid 7-phosphate synthase plays the same role as histidine 202 in 3-deoxy-D-manno-octulosonic acid 8-phosphate synthase

The enzyme 3-deoxy-d-arabino-heptulosonate 7-phosphate (DAH 7-P) synthase (Phe) is inactivated by diethyl pyrocarbonate (DEPC). The inactivation is first order with respect to enzyme and DEPC concentrations with a pseudo-second order rate constant of inactivation by DEPC of 4.9 +/- 0.8 m(-1) s(-1) at pH 6.8 and 4 degrees C. The dependence of inactivation on pH and the spectral features of enzyme modified at specific pH values imply that both histidine and cysteine residues are modified, which is confirmed by site-directed mutagenesis. Analysis of the chemical modification data indicates that one histidine is essential for activity. DAH 7-P synthase (Phe) is protected against DEPC inactivation by phosphoenolpyruvate, whereas d-erythrose 4-phosphate offers only minimal protection. The conserved residues H-172, H-207, H-268, and H-304 were individually mutated to glycine. The H304G and H207G mutants retain some level of activity, whereas the H268G and H172G mutants are virtually inactive. A comparison of the circular dichroism spectra of wild-type enzyme and the various mutants demonstrates that H-172 may play a structural role. Comparison of the UV spectra of the H268G and wild-type enzymes saturated with Cu(2+) indicates that the metal-binding site of the H268G mutant resembles that of the wild-type enzyme. The residue H-268 may play a catalytic role based on the site-directed mutagenesis and spectroscopic studies. Cysteine 61 appears to influence the pK(a) of H-268 in the wild-type enzyme. The pK(a) of H-268 increases from 6.0 to 7.0 following mutation of C-61 to glycine.     

Mercury(II) binds to both of chymotrypsin's histidines,causing inhibition followed by irreversible denaturation/aggregation

The toxicity of mercury is often attributed to its tight binding to cysteine thiolate anions in vital enzymes. To test our hypothesis that Hg(II) binding to histidine could be a significant factor in mercury's toxic effects, we studied the enzyme chymotrypsin, which lacks free cysteine thiols; we found that chymotrypsin is not only inhibited, but also denatured by Hg(II). We followed the aggregation of denatured enzyme by the increase in visible absorbance due to light scattering. Hg(II)‐induced chymotrypsin precipitation increased dramatically above pH 6.5, and free imidazole inhibited this precipitation, implicating histidine‐Hg(II) binding in the process of chymotrypsin denaturation/aggregation. Diethylpyrocarbonate (DEPC) blocked chymotrypsin's two histidines (his₄₀ and his₅₇) quickly and completely, with an IC₅₀ of 35 ± 6 µM. DEPC at 350 µM reduced the hydrolytic activity of chymotrypsin by 90%, suggesting that low concentrations of DEPC react with his₅₇ at the active site catalytic triad; furthermore, DEPC below 400 µM enhanced the Hg(II)‐induced precipitation of chymotrypsin. We conclude that his₅₇ reacts readily with DEPC, causing enzyme inhibition and enhancement of Hg(II)‐induced aggregation. Above 500 µM, DEPC inhibited Hg(II)‐induced precipitation, and [DEPC] >2.5 mM completely protected chymotrypsin against precipitation. This suggests that his₄₀ reacts less readily with DEPC, and that chymotrypsin denaturation is caused by Hg(II) binding specifically to the his₄₀ residue. Finally, we show that Hg(II)‐histidine binding may trigger hemoglobin aggregation as well. Because of results with these two enzymes, we suggest that metal‐histidine binding may be key to understanding all heavy metal‐induced protein aggregation.     

Diethylpyrocarbonate inhibition of vacuolar H+-pyrophosphatase possibly involves a histidine residue

Vacuolar proton pumping pyrophosphatase (H⁺-PPase; EC 3.6.1.1) plays a pivotal role in electrogenic translocation of protons from cytosol to the vacuolar lumen at the expense of PP_i hydrolysis. A histidine-specific modifier, diethylpyrocarbonate (DEPC), could substantially inhibit enzymic activity and H⁺-translocation of vacuolar H⁺-PPase in a concentration-dependent manner. Absorbance of vacuolar H⁺-PPase at 240 nm was increased upon incubation with DEPC, demonstrating that an N-carbethoxyhistidine moiety was probably formed. On the other hand, hydroxylamine, a reagent that can deacylate N-carbethoxyhistidine, could reverse the absorption change at 240 nm and partially restore PP_i hydrolysis activity as well. The pK _a of modified residues of the enzyme was determined to be 6.4, a value close to that of histidine. Thus, we speculate that inhibition of vacuolar H⁺-PPase by DEPC possibly could be attributed to the modification of histidyl residues on the enzyme. Furthermore, inhibition of vacuolar H⁺-PPase by DEPC follows pseudo-first-order rate kinetics. A reaction order of 0.85 was calculated from a double logarithmic plot of the apparent reaction constant against DEPC concentration, suggesting that the modification of one single histidine residue on the enzyme suffices to inhibit vacuolar H⁺-PPase. Inhibition of vacuolar H⁺-PPase by DEPC changes V _max but not K _m values. Moreover, DEPC inhibition of vacuolar H⁺-PPase could be substantially protected against by its physiological substrate, Mg²⁺-PP_i. These results indicated that DEPC specifically competes with the substrate at the active site and the DEPC-labeled histidine residue might locate in or near the catalytic domain of the enzyme. Besides, pretreatment of the enzyme with N-ethylmaleimide decreased the degree of subsequent labeling of H⁺-PPase by DEPC. Taken together, we suggest that vacuolar H⁺-PPase likely contains a substrate-protectable histidine residue contributing to the inhibition of its activity by DEPC, and this histidine residue may located in a domain sensitive to the modification of Cys-629 by NEM.     

Evidence for a single catalytic site of honeybee alpha-glucosidase I by chemical modification with diethylpyrocarbonate.

Honeybee alpha-glucosidase I was inactivated with diethylpyrocarbonate (DEPC). The inactivation followed pseudo-first-order kinetics. The rate of the loss of activity was decreased by the addition of a substrate, maltose. Since there was no spectral change in the tyrosine absorption region, it was recognized that DEPC did not react with this residue. The alpha-glucosidase had one free sulfhydryl group, which was not involved in the catalytic reaction, and was not modified by DEPC. On the other hand, the specific reaction of DEPC with a histidyl residue was spectrophotometrically confirmed by an increase in absorption near 240 nm, and the activity of the inactivated enzyme was restored by hydroxylamine. The modification rate of one histidyl residue by DEPC was almost equal to the rate of the activity loss. These results indicate that there is one histidyl residue at or near the catalytic site, and that honeybee alpha-glucosidase I has a single active site.     

Primary structure of a zinc protease from Bacillus mesentericus strain 76

The amino acid sequence of the neutral zinc protease from Bacillus mesentericus strain 76 (MCP 76) has been determined by using peptides derived from digests with trypsin, chymotrypsin, and cyanogen bromide and from cleavage with o-iodosobenzoic acid. The peptides were purified by means of gel filtration and reversed-phase high-performance liquid chromatography and analyzed by automatic sequencing. The protein contains 300 amino acid residues. It proved to be identical with the neutral protease deduced from the DNA precursor sequence of Bacillus subtilis. The residues for zinc and substrate binding are conserved, whereas the number of calcium binding sites is reduced compared to thermolysin. A classification of the neutral zinc protease is discussed.     

Analysis of essential histidine residues of maize branching enzymes by chemical modification and site-directed mutagenesis

Incubation of maize branching enzyme, mBEI and mBEII, with 100 μM diethylpyrocarbonate (DEPC) rapidly inactivated the enzymes. Treatment of the DEPC-inactivated enzymes with 100–500 mM hydroxylamine restored the enzyme activities. Spectroscopic data indicated that the inactivation of BE with DEPC was the result of histidine modification. The addition of the substrate amylose or amylopectin retarded the enzyme inactivation by DEPC, suggesting that the histidine residues are important for substrate binding. In maize BEII, conserved histidine residues are in catalytic regions 1 (His320) and 4 (His508). His320 and His508 were individually replaced by Ala via site-directed mutagenesis to probe their role in catalysis. Expression of these mutants inE. coli showed a significant decrease of the activity and the mutant enzymes hadK _m values 10 times higher than the wild type. Therefore, residues His320 and His508 do play an important role in substrate binding.