Intracellular Localization of Two Enzymes Involved in Coumarin Biosynthesis in Melilotus alba

The localization of phenylalanine ammonia-lyase [EC 4.3.1.5] within sweet clover (Melilotus alba) leaves was investigated. Apical buds and axillary leaves contained 15 to 30 times more enzyme activity than did mature leaves. Mesophyll protoplasts were prepared by digesting young leaves with Cellulysin and Macerase and were gently ruptured yielding intact chloroplasts. These chloroplast preparations exhibited neither phenylalanine ammonia-lyase nor o-coumaric acid O-glucosyltransferase activities. The general enzymic properties of sweet clover leaf phenylalanine ammonia-lyase were similar to those described for this enzyme isolated from other plant species. The conversion of l-phenylalanine to trans-cinnamic acid, which occurred at an optimum pH of about 8.7, was strongly inhibited by the metabolites trans-cinnamic and o-coumaric acids. In contrast, o-coumaric acid glucoside, coumarin, p-coumaric acid, and melilotic acid had no significant effect on the reaction rate.     

Purification and biochemical properties of glutathione S-transferase from Lactuca sativa

A glutathione S-transferase (GST) from Lactuca sativa was purified to electrophoretic homogeneity approximately 403-fold with a 9.6% activity yield by DEAE-Sephacel and glutathione (GSH)-Sepharose column chromatography. The molecular weight of the enzyme was determined to be approximately 23,000 by SDS-polyacrylamide gel electrophoresis and 48,000 by gel chromatography, indicating a homodimeric structure. The activity of the enzyme was significantly inhibited by ShexylGSH and S-(2,4-dinitrophenyl) glutathione. The enzyme displayed activity towards 1-chloro-2,4-dinitrobenzene, a general GST substrate and high activities towards ethacrynic acid. It also exhibited glutathione peroxidase activity toward cumene hydroperoxide.     

Cholesterol-Esterifying Enzymes in Developing Rat Brain

Abstract: A cholesterol-esterifying enzyme which incorporates exogenous fatty acids into cholesterol esters in the presence of ATP and coenzyme A was demonstrated in 15-day-old rat brain. This enzyme was maximally active at pH 7.4 and distinct from the cholesterol-esterifying enzyme reported earlier (Eto and Suzuki, 1971), which has a pH optimum at 5.2 and does not require cofactors. Properties of the two enzymes have been compared. Both the enzymes showed negligible esterification with acetate and were maximally active with oleic acid. The pH 5.2 enzyme esterified desmosterol, lanosterol and cholesterol at about the same rate, while the pH 7.4 enzyme was only 50% as active with lanosterol as it was with cholesterol and desmosterol. Phosphatidyl serine stimulated the pH 5.2 enzyme but not the pH 7.4 enzyme. Phosphatidyl choline and sodium taurocholate showed no effect on either of the enzymes. Both the enzymes were associated with particulate fractions, but the pH 7.4 enzyme was localized more in the microsomes. Purified myelin showed 2.6-fold and 1.5-fold higher specific activities of pH 5.2 and 7.4 enzymes respectively, when compared with homogenate. About 7–10% of total activity of both the enzymes was associated with purified myelin. Brain stem and spinal cord showed higher specific activity of pH 5.2 enzyme than cerebral cortex and cerebellum, while pH 7.4 enzyme specific activity was higher in cerebellum and brain stem than in cerebral cortex and spinal cord. Microsomal pH 7.4 activity showed progressive increase prior to the active period of myelination, reaching a maximum on the 15th day after birth and declined to 20% of the peak activity by 30 days. In contrast, pH 5.2 enzyme reached maximum activity about the 6th day after birth and remained at this level well into adulthood. In 15-day-old rat brain, pH 7.4 enzyme had five to six times higher specific activity than pH 5.2 enzyme, while in adults the activities were equal. The pH 7.4 enzyme showed a threefold higher specific activity than pH 5.2 enzyme in myelin from 15-day-old rats, but in adults the reverse was true.     

GSTB1-1 from Proteus mirabilis: a snapshot of an enzyme in the evolutionary pathway from a redox enzyme to a conjugating enzyme

The native form of the bacterial glutathione transferase B1-1 (EC ) is characterized by one glutathione (GSH) molecule covalently linked to Cys-10. This peculiar disulfide, only found in the Beta and Omega class glutathione S-transferases (GSTs) but absent in all other GSTs, prompts questions about its role and how GSH can be activated and utilized in the reaction normally performed by GSTs. Stopped-flow and spectroscopic experiments suggest that, in the native enzyme (GSTB1-1ox), a second GSH molecule is present, albeit transiently, in the active site. This second GSH binds to the enzyme through a bimolecular interaction followed by a fast thiol-disulfide exchange with the covalently bound GSH. The apparent pK(a) of the non-covalently bound GSH is lowered from 9.0 to 6.4 +/- 0.2 in similar fashion to other GSTs. The reduced form of GSTB1-1 (GSTB1-1red) binds GSH 100-fold faster and also induces a more active deprotonation of the substrate with an apparent pK(a) of 5.2 +/- 0.1. Apparently, the absence of the mixed disulfide does not affect k(cat) and K(m) values in the GST conjugation activity, which is rate-limited by the chemical step both in GSTB1-1red and in GSTB1-1ox. However, GSTB1-1ox follows a steady-state random sequential mechanism whereas a rapid-equilibrium random sequential mechanism is adopted by GSTB1-1red. Remarkably, GSTB1-1ox and GSTB1-1red are equally able to catalyze a glutaredoxin-like catalysis using cysteine S-sulfate and hydroxyethyl disulfide as substrates. Cys-10 is an essential residue in this redox activity, and its replacement by alanine abolishes this enzymatic activity completely. It appears that GSTB1-1 behaves like an "intermediate enzyme" between the thiol-disulfide oxidoreductase and the GST superfamilies.     

Purification and characterization of membrane-bound prostaglandin E synthase from bovine heart.

Prostaglandin (PG) E synthase was solubilized with 6 mM sodium deoxycholate from the microsomal fraction of bovine hearts. The enzyme was purified by about 800-fold to apparent homogeneity. The specific activity of the purified enzyme was about 830 mU/mg of protein, and the K(m) value for PGH(2) was 24 microM. The molecular weight of the enzyme was about 31000 on SDS-polyacrylamide gel electrophoresis and was about 60000 by gel filtration. The enzyme was separated from glutathione (GSH) S-transferase by DEAE-Toyopearl column chromatography, and did not exhibit any GSH S-transferase activity towards four different substrates. The purified enzyme was active in the absence of GSH, but it was activated by various SH-reducing reagents including dithiothreitol, GSH, or beta-mercaptoethanol. This is the first reported purification of membrane-bound PGE synthase to apparent homogeneity.     

Inhibition and recognition studies on the glutathione-binding site of equine liver glutathione S-transferase.

Equine liver glutathione S-transferase has been shown to consist of two identical subunits of apparent Mr 25,500 and a pl of 8.9. Kinetic data at pH 6.5 with 1-chloro-2,4-dinitrobenzene as a substrate suggests a random rapid-equilibrium mechanism, which is supported by inhibition studies using glutathione analogues. S-(p-Bromobenzyl)glutathione and the corresponding N alpha-, CGlu- and CGly-substituted derivatives have been found, at pH 6.5, to be linear competitive inhibitors, with respect to GSH, of glutathione transferase. N-Acetylation of S-(p-bromobenzyl)glutathione decreases binding by 100-fold, whereas N-benzoylation and N-benzyloxycarbonylation abolish binding of the derivative to the enzyme. The latter effect has been attributed to a steric constraint in this region of the enzyme. Amidation of the glycine carboxy group of S-(p-bromobenzyl)glutathione decreases binding by 13-fold, whereas methylation decreases binding by 70-fold, indicating a steric constraint and a possible electrostatic interaction in this region of the enzyme. Amidation of both carboxy groups decreases binding significantly by 802-fold, which agrees with electrostatic interaction of the glutamic acid carboxy group with a group located on the enzyme.     

Purification, characterization and identification of rat liver histidine-pyruvate aminotransferase isoenzymes.

1. Histidine-pyruvate aminotransferase (isoenzyme 1) was purified to homogeneity from the mitochondrial and supernatant fractions of rat liver, as judged by polyacrylamide-gel electrophoresis and isolectric focusing. Both enzyme preparations were remarkably similar in physical and enzymic properties. Isoenzyme 1 had pI8.0 and a pH optimum of 9.0. The enzyme was active with pyruvate as amino acceptor but not with 2-oxoglutarate, and utilized various aromatic amino acids as amino donors in the following order of activity: phenylalanine greater than tyrosine greater than histidine. Very little activity was found with tryptophan and 5-hydroxytryptophan. The apparent Km values were about 2.6mM for histidine and 2.7 mM for phenylalanine. Km values for pyruvate were about 5.2mM with phenylalanine as amino donor and 1.1mM with histidine. The aminotransferase activity of the enzyme towards phenylalanine was inhibited by the addition of histidine. The mol.wt. determined by gel filtration and sucrose-density-gradient centrifugation was approx. 70000. The mitochondrial and supernatant isoenzyme 1 activities increased approximately 25-fold and 3.2-fold respectively in rats repeatedly injected with glucagon for 2 days. 2. An additional histidine-pyruvate aminotransferase (isoenzyme 2) was partially purified from both the mitochondrial and supernatant fractions of rat liver. Nearly identical properties were observed with both preparations. Isoenzyme 2 had pI5.2 and a pH optimum of 9.3. The enzyme was specific for pyruvate and did not function with 2-oxoglutarate. The order of effectiveness of amino donors was tyrosine = phenylalanine greater than histidine greater than tryptophan greater than 5-hydroxytryptophan. The apparent Km values for histidine and phenylalanine were about 0.51 and 1.8 mM respectively. Km values for pyruvate were about 3.5mM with phenylalanine and 4.7mM with histidine as amino donors. Histidine inhibited phenylalanine aminotransferase activity of the enzyme. Gel filtration and sucrose-density-gradient centrifugation yielded a mol.wt. of approx. 90000. Neither the mitochondrial nor the supernatant isoenzyme 2 activity was elevated by glucagon injection.     

Sulphur metabolism in Paracoccus denitrificans. Purification, properties and regulation of serine transacetylase, O-acetylserine sulphydrylase and beta-cystathionase.

1. Serine transacetylase, O-acetylserine sulphydrylase and beta-cystathionase were purified from Paracoccus denitrificans strain 8944. 2. Serin transacetylase was purified 150-fold. The enzyme has a pH optimum between 7.5 and 8.0, is specific for L-serine and is inhibited by sulphydryl-group reagents. The apparent Km values for serine and acetyl-CoA are 4.0 - 10(-4) and 1.0 - 10(-4) M, respectively. Serine transacetylase is strongly inhibited by cysteine. 3. O-Acetylserine sulphydrylase was purified 450-fold. The enzymes has a sharp pH optimum at pH 7.5. In addition to catalysing the synthesis of cysteine, O-acetylserine sulphydrylase catalyses the synthesis of selenocysteine from O-acetylserine and selenide. The Km values for sulphide and O-acetylserine are 2.7 - 10(-3) and 1.25 - 10(-3) M, respectively. The enzyme was stimulated by pyridoxal phosphate and was inhibited by cystathionine, homocysteine and methionine. 4. beta-Cystathionase was purified approx. 50-fold. beta-Cystathionase has a pH optimum between pH 9.0 and 9.5, is sensitive to sulphydryl-group reagents, required pyridoxal phosphate for maximum activity and has an apparent Km for cystathionine of 4.2 - 10 (-3) M. beta-Cystathionase also catalyses the release of keto acid from lanthionine, djenkolic acid and cystine. Cysteine, O-acetylserine, homocysteine and glutathione strongly inhibit beta-cystathionase activity and homocysteine and methionine represses enzyme activity. 5. O-Acetylserine lyase was identified in crude extracts of Paracoccus denitrificans. The enzyme is specific for O-acetyl-L-serine, requires pyridoxal phosphate and is inhibied by KCN and hydroxylamine. The enzyme has a high Km value for O-acetylserine (50--100 mM).     

Purification and characterization of p-coumaroyl-D-glucose hydroxylase of sweet potato (Ipomoea batatas) roots

p-Coumaroyl-D-glucose hydroxylase in sweet potato (Ipomoea batatas Lam.) has been purified to apparent electrophoretic homogeneity using a combination of anion-and cation-exchange, hydrophobic and gel filtration chromatography. The purified enzyme was a monomer with a molecular weight of 33,000 and pI of 8.3. The purified enzyme showed not only hydroxylase activity but also polyphenol oxidase activity. L-Ascorbic acid was the best electron donor for the hydroxylation reaction, which had an optimum pH of 7.0. The enzyme hydroxylated p-coumaroyl-D-glucose, p-coumaric acid, and p-cresol but did not act on o-coumaric acid, m-coumaric acid, 4-hydroxy-3-methoxycinnamic acid, p-hydroxybenzoic acid or L-tyrosine. While the enzyme utilized p-coumaroyl-D-glucose and p-coumaric acid equally at pH 7.0, it hydroxylated only p-coumaroyl-D-glucose at pH 5.5. The enzyme oxidized diphenols such as D,L-(3,4-dihydroxyphenyl) alanine and caffeic acid, but exhibited no clear pH optimum in this reaction characteristic of polyphenol oxidase. Both the hydroxylase and the polyphenol oxidase activities were strongly inhibited by beta-mercaptoethanol, diethyldithiocarbamate, KCN, and p-coumaric acid (in concentrations higher than 5 mM). Ammonium sulfate and sodium chloride activated the hydroxylase activity but not the polyphenol oxidase activity of the enzyme. The enzyme activity and L-ascorbic acid contents changed in a manner suggesting their involvements in chlorogenic acid biosynthesis during incubation of sliced sweet potato root tissues.     

Purification and characterization of the flavoenzyme glutathione reductase from rat liver.

Glutathione reductase from rat liver has been purified greater than 5000-fold in a yield of 20%. The molecular weights of the enzyme and its subunits were estimated to be 125,000 and 60,000, respectively, indicating that the native enzyme is a dimer. The enzyme molecular contains 2 FAD molecules, which are reducible by NADPH, GSH or dithioerythritol. The reduced flavin is instantaneously reoxidized by addition of GSSG. The steady state kinetic data are consistent with a branching reaction mechanism previously proposed for glutathione reductase from yeast (MANNERVIK, B. (1973) Biochem. Biophy. Res. Commun. 53, 1151-1158). This mechanism is also favored by the nonlinear inhibition pattern produced by NADP-+. However, at low GSSG concentrations the rate equation can be approximated by that of a simple ping pong mechanism. NADPH and the mixed disulfide of coenzyme A and GSH were about 10% as active as NADPH and GSSG, respectively, whereas some sulfenyl derivatives related to GSSG were less active as substrates. The pH activity profiles of these substrates differed from that of the NADPH-GSSG substrate pair.     

Metabolism of 2-ketoaldehydes in mold: purification and characterization of glyoxalase I from Aspergillus niger

Glyoxalase I catalyzing the conversion of methylglyoxal into S-lactoylglutathione in the presence of glutathione was purified approximately 1,400-fold with 2.9% activity yield from mold, Aspergillus niger. The enzyme consisted of a single polypeptide chain with a relative molecular weight of 36,000 on both SDS-polyacrylamide gel electrophoresis and Sephadex G-150 gel filtration. The enzyme was most active at pH 7.0, 35-37 degrees C. Among the various aldehydes tested, the enzyme was active on methylglyoxal and 4,5-dioxovalerate with Km values of 1.25 and 0.87 mM, respectively. The activity of the enzyme was completely inhibited by Zn2+ at 0.5 mM. An equimolar amount of EDTA (0.5 mM) protected the enzyme from inactivation by Zn2+. EDTA competitively (K1 = 1.3 mM) inhibited the activity of the enzyme. Fe2+ was a potent activator for the enzyme, the activation being approximately 2.4-fold at 0.5 mM.     

Purification and some properties of rabbit liver cytosol thioltransferase

Thioltransferase was purified 650-fold from rabbit liver by procedures including acid treatment, heat treatment, gel filtration on Sephadex G-50, column chromatography on DEAE-cellulose, isoelectric focusing (pH 3.5-10) and gel filtration on Sephadex G-75. The final enzyme preparation was almost homogeneous in polyacrylamide gel electrophoretic analysis. Only one active peak with an apparent molecular weight (Mr) of 13,000 was detected by gel filtration on Sephadex G-50 and only a single protein band with a molecular weight of 12,400 was detected by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Isoelectric focusing revealed only one enzyme species, having an isoelectric point (pI) of 5.3. The enzyme has an optimum pH about 3.0 with S-sulfocysteine and GSH as substrates. The purified enzyme utilized some disulfides including S-sulfocysteine, alpha-chymotrypsin, trypsin, bovine serum albumin, and insulin as substrates in the presence of GSH. The enzyme does not act as a protein : disulfide isomerase (the activity of which can be measured in terms of reactivation of randomly reoxidized soybean Kunitz trypsin inhibitor). The enzyme activity was inhibited by chloramphenicol, but not by bacitracin. The inhibition by chloramphenicol was non-competitive (apparent K1 of 0.5 mM). Thioltransferase activity was found in the cytosol of various rabbit tissues.     

Lipoxygenase-another pathway for glutathione conjugation of xenobiotics: A study with human term placental lipoxygenase and ethacrynic acid.

In this study, we examined the ability of human term placental lipoxygenase (HTPLO) to catalyze glutathione (GSH) conjugate formation from ethacrynic acid (EA) in the presence of linoleic acid (LA) and GSH. HTPLO purified by affinity chromatography was used in all the experiments. The results indicate that the process of EA-SG is enzymatic in nature. The reaction shows dependence on pH, the enzyme, and the concentration of GSH, LA, and EA. The optimal assay conditions to observe a maximal rate of EA-SG formation required the presence of 0.3 mM LA, 0.2 mM EA, 2.0 mM GSH, and approximately 300 microg HTPLO in the reaction medium buffered at pH 9.0. Under the experimental conditions employed, the reaction exhibited K(m) values of 1.1 mM, 200 microM, and 130 microM for GSH, LA, and EA, respectively. The estimated specific activity of HTPLO-catalyzed EA-GS formation was approximately 4.4 +/- 0.4 micromol/min/mg protein. This rate is more than twofold greater than the rate noted for the reaction mediated by the purified human term placental glutathione transferase. Under physiologically relevant conditions (20 microM LA, 2.0 mM GSH, at pH 7.4), HTPLO produced EA-SG at 56% of the maximal rate noted under optimal assay conditions. Nordihydroguaiaretic acid, the classical inhibitor of different lipoxygenases, significantly blocked the reaction. It is proposed that free radicals are involved in the process of EA-SG formation by HTPLO. The evidence gathered in this in vitro study suggests for the first time that lipoxygenase present in the human term placenta is capable of EA-SG formation.     

Purification and characterization of an acid phosphatase that displays phosphotyrosyl-protein phosphatase activity from bovine cortical bone matrix

An acid phosphatase activity that displayed phosphotyrosyl-protein phosphatase has been purified from bovine cortical bone matrix to apparent homogeneity. The overall yield of the enzyme activity was greater than 25%, and overall purification was approximately 2000-fold with a specific activity of 8.15 mumol of p-nitrophenyl phosphate hydrolyzed per min/mg of protein at pH 5.5 and 37 degrees C. The purified enzyme was judged to be purified based on its appearance as a single protein band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (silver staining technique). The enzyme could be classified as a band 5-type tartrate-resistant acid phosphatase isoenzyme. The apparent molecular weight of this enzyme activity was determined to be 34,600 by gel filtration and 32,500 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of reducing agent, indicating that the active enzyme is a single polypeptide chain. Kinetic evaluations revealed that the acid phosphatase activity appeared to catalyze its reaction by a pseudo Uni Bi hydrolytic two-step transfer reaction mechanism and was competitively inhibited by transition state analogs of Pi. The enzyme activity was also sensitive to reducing agents and several divalent metal ions. Substrate specificity evaluation showed that this purified bovine skeletal acid phosphatase was capable of hydrolyzing nucleotide tri- and diphosphates, phosphotyrosine, and phosphotyrosyl histones, but not nucleotide monophosphates, phosphoserine, phosphothreonine, phosphoseryl histones, or low molecular weight phosphoryl esters. Further examination of the phosphotyrosyl-protein phosphatase activity indicated that the optimal pH at a fixed substrate concentration (50 nM phosphohistones) for this activity was 7.0. Kinetic analysis of the phosphotyrosyl-protein phosphatase activity indicated that the purified enzyme had an apparent Vmax of approximately 60 nmol of [32P]phosphate hydrolyzed from [32P]phosphotyrosyl histones per min/mg of protein at pH 7.0 and an apparent Km for phosphotyrosyl proteins of approximately 450 nM phosphate group. In summary, the results of these studies represent the first purification of a skeletal acid phosphatase to apparent homogeneity. Our observation that this purified bovine bone matrix acid phosphatase was able to dephosphorylate phosphotyrosyl proteins at neutral pH is consistent with our suggestion that this enzyme may function as a phosphotyrosyl-protein phosphatase in vivo.     

Partial Purification and Characterization of Hydroxycinnamoyl-Coenzyme A:Tyramine Hydroxycinnamoyltransferase from Cell Suspension Cultures of Solanum tuberosum

A pathogen elicitor-inducible soluble acyltransferase (tyramine hydroxycinnamoyltransferase [THT], EC 2.3.1), which catalyzes the transfer of hydroxycinnamic acids from hydroxycinnamoyl-coenzyme A (CoA) esters to tyramine in the formation of N-hydroxycinnamoyltyramine, was partially purified with a 380-fold enrichment and a 6% recovery from cell-suspension cultures of potato (Solanum tuberosum L. cv Datura). The enzyme showed specific activities of 33 mkat (kg protein)-1 (formation of feruloyltyramine). The apparent native Mr was found to be approximately 49,000. Highest activity was at pH 6.8 in K-phosphate. The isoelectric point of the enzyme was approximately pH5.2. The apparent energy of activation was calculated to be 96 kJ mol-1. The enzyme activity was stimulated more than 5-fold by 10 mM Ca2+ or Mg2+. The apparent Km values were 36 [mu]M for feruloyl-CoA and 85 and 140 [mu]M for cinnamoyl- and 4-coumaroyl-CoA, respectively. The Km value for tyramine in the presence of feruloyl-CoA was 22 [mu]M. In the presence of 4-coumaroyl-CoA, however, the Km for tyramine increased to about 230 [mu]M. The mode of action was an iso-ordered bi bi mechanism in which A, B, P, and Q equal hydroxycinnamoyl-CoA, tyramine, N-hydroxycinnamoyltyramine, and CoA, respectively. Thus, the reaction occurred in a ternary complex of the enzyme and substrates. The equilibrium constant of the reaction was determined to be 1.3 x 104. This gave a [delta]G[deg][prime] eq value of -23.5 kJ mol-1.     

Purification and characterization of glutathione reductase from Rhodospirillum rubrum.

Glutathione reductase (NAD(P)H:GSSG oxidoreductase EC 1.6.4.2.) was purified 1160-fold to homogeneity from the nonsulfurous purple bacteria Rhodospirillum rubrum (wild type). Specific activity of the pure preparation was 102 U/mg. The enzyme displayed a typical flavoprotein absorption spectrum with maxima at 274,365, and 459 nm and an absorbance ratio A280/A459 of 7.6. The amino acid analysis revealed an unusually high content of glycine and arginine residues. Titration of the enzyme with 5,5'-dithiobis(2-nitrobenzoic acid) showed a total of two free thiol groups per subunit, one of which is made accessible only under denaturing conditions. An isoelectric point of 5.2 was found for the native enzyme. Km values, determined at pH 7.5, were 6.1 and 90 microM for NADPH and GSSG, respectively. NADH was about 2% as active as NADPH as an electron donor. The enzyme's second choice in disulfide substrate was the mixed disulfide of coenzyme A and glutathione, for which the specific activity and Km values were 5.1 U/mg and 3.4 mM, respectively. A native molecular weight of 118,000 was found, while denaturing electrophoresis gave a value of 54,400 per subunit, thus suggesting that R. rubrum glutathione reductase exists as a dimeric protein. Other physicochemical constants of the enzyme, such as Stokes radius (4.2 nm) and sedimentation coefficient (5.71 S), were also consistent with a particle of 110,000.     

Purification and characterization of cathepsin L-like proteinase from goat brain

Cathepsin L-like proteinase was purified approximately 1708-fold with 40% activity yield to an apparent electrophoretic homogeneity from goat brain by homogenization, acid-autolysis at pH 4.2, 30-80% (NH4)2SO4 fractionation, Sephadex G-100 column chromatography and ion-exchange chromatography on CM-Sephadex C-50 at pH 5.0 and 5.6. The molecular weight of proteinase was found to be approximately 65,000 Da, by gel-filtration chromatography. The pH optima were 5.9 and 4.5 for the hydrolysis of Z-Phe-Arg-4mbetaNA (benzyloxycarbonyl-L-phenylalanine-L-arginine-4-methoxy-beta-naphthylamide) and azocasein, respectively. Of the synthetic chromogenic substrates tested, Z-Phe-Arg-4mbetaNA was hydrolyzed maximally by the enzyme (Km value for hydrolysis was 0.06 mM), followed by Z-Val-Lys-Lys-Arg-4mbetaNA, Z-Phe-Val-Arg-4mbetaNA, Z-Arg-Arg-4mbetaNA and Z-Ala-Arg-Arg-4mbetaNA. The proteinase was activated maximally by glutathione in conjunction with EDTA, followed by cysteine, dithioerythritol, thioglycolic acid, dithiothreitol and beta-mercaptoethanol. It was strongly inhibited by p-hydroxymercuribenzenesulphonic acid, iodoacetic acid, iodoacetamide and microbial peptide inhibitors, leupeptin and antipain. Leupeptin inhibited the enzyme competitively with Ki value 44 x 10(-9) M. The enzyme was strongly inhibited by 4 M urea. Metal ions, Hg(2+), Ca(2+), Cu(2+), Li(2+), K(+), Cd(2+), Ni(2+), Ba(2+), Mn(2+), Co(2+) and Sn(2+) also inhibited the activity of the enzyme. The enzyme was stable between pH 4.0-6.0 and up to 40 degrees C. The optimum temperature for the hydrolysis of Z-Phe-Arg-4mbetaNA was approximately 50-55 degrees C with an activation energy Ea of approximately 6.34 KCal mole(-1).     

Screening, purification, and characterization of an extracellular prolyl oligopeptidase from Coprinopsis clastophylla

Culture filtrates of 22 mushrooms were screened for extracellular prolyl oligopeptidase activity. Four strains with relatively high enzyme activity were all from inky cap mushrooms. The production of Coprinopsis clastophylla prolyl oligopeptidase was associated with the growth of the fungus and the enzyme was not released by cell lysis. The enzyme was purified 285-fold to a specific activity of 52.05 U/mg. It was purified to a single band on a native polyacrylamide gel. However, the enzyme separated into three bands on a sodium dodecyl sulfate-polyacrylamide gel with mobility corresponding to molecular weights of approximately 84, 60, and 26 kDa. The results of tandem mass spectrometric analysis revealed that the 60 kDa protein was likely a degradation product of the 84 kDa protein. The isoelectric point of the purified enzyme was 5.2. The purified enzyme had an optimal pH and temperature of 8.0 and 37°C, respectively. Diisopropyl fluorophosphate (DFP), p-chloromercuribenzoaic acid (PCMB), Hg(2+), and Cu(2+) strongly inhibited C. clastophylla prolyl oligopeptidase. This enzyme is a serine peptidase and one or more cysteine residues of the enzyme are close to the active site.     

Functional mimicry of the active site of glutathione peroxidase by glutathione imprinted selenium-containing protein

For imitating the active site of antioxidant selenoenzyme glutathione peroxidase (GPx), an artificial enzyme selenosubtilisin was employed as a scaffold for reconstructing substrate glutathione (GSH) specific binding sites by a bioimprinting strategy. GSH was first covalently linked to selenosubtilisin to form a covalent complex GSH-selenosubtilisin through a Se-S bond, then the GSH molecule was used as a template to cast a complementary binding site for substrate GSH recognition. The bioimprinting procedure consists of unfolding the conformation of selenosubtilisin and fixing the new conformation of the complex GSH-selenosubtilisin. Thus a new specificity for naturally occurring GPx substrate GSH was obtained. This bioimprinting procedure facilitates the catalytic selenium moiety of the imprinted selenosubtilisin to match the reactive thiol group of GSH in the GSH binding site, which contributes to acceleration of the intramolecular catalysis. These imprinted selenium-containing proteins exhibited remarkable rate enhancement for the reduction of H2O2 by GSH. The average GPx activity was found to be 462 U/micromol, and it was approximately 100 times that for unimprinted selenosubtilisin. Compared with ebselen, a well-known GPx mimic, an activity enhancement of 500-fold was observed. Detailed steady-state kinetic studies demonstrated that the novel selenoenzyme followed a ping-pong mechanism similar to the naturally occurring GPx.     

Biosynthesis of pseudoisoeugenol-derivatives in liquid tissue cultures ofPimpinella anisum

The genusPimpinella contains rare phenylpropanoids. The 1-(E)-propenyl-2-hydroxy-5-methoxy benzene skeleton of these compounds is called pseudoisoeugenol. To study the biosynthesis of these compounds, we set up a tissue culture ofPimpinella anisum (PAD) that selectively promoted the production of epoxy-pseudoisoeugenol-(2-methylbutyrate), termed EPB. This compound served as the final molecule of the biosynthetic pathway in all labelling experiments conducted.The putative precursors were labelled with¹³C or¹⁴C. The incorporation of the label was followed by¹³C-NMR-spectroscopy and liquid scintillation, respectively. Based on our labelling experiments as well as on enzymic reactions in a cell homogenate we proposed a genaral biosynthetic pathway for EPB. The biosynthetic sequence found wasl-phenylalanine, trans-cinnamic acid, p-coumaric acid, p-coumaric aldehyde, p-coumaric alcohol, anol and trans-anethol. The biosynthetic step leading from trans-anethol to pseudo-isoeugenol involves migration of the side chain during the introduction of the second OH-group in the molecule (NIH-shift). The final biosynthetic steps to form EPB must be acylation and epoxidation of the propenyl double bond of pseudoisoeugenol.Abbreviations NMR Nuclear Magnetic Resonance - NOE Nuclear Overhauser Effect