Biosynthesis of clorobiocin: investigation of the transfer and methylation of the pyrrolyl-2-carboxyl moiety

Clorobiocin is an aminocoumarin antibiotic containing a 5-methylpyrrolyl-2-carboxyl moiety, attached by an ester bond to a deoxysugar. This pyrrolyl moiety is important for the binding of the antibiotic to its biological target, the B subunit of gyrase. Inactivation experiments had shown that two putative acyl carrier proteins, CloN5 and CloN1, and two putative acyl transferases, CloN2 and CloN7, are involved in the transfer of the pyrrolyl-2-carboxyl moiety to the deoxysugar. In this study, pyrrolyl-2-carboxyl-N-acetylcysteamine thioester was synthesized and fed to cloN1 ⁻ , cloN2 ⁻ and cloN7 ⁻ mutants, and secondary metabolite formation was analyzed by HPLC and HPLC-MS. Transfer of the pyrrolyl-2-carboxyl moiety was observed in the cloN1 ⁻ and cloN2 ⁻ mutants, but not in the cloN7 ⁻ mutant, suggesting that CloN7 is responsible for this reaction. The product of this transfer, novclobiocin 109, was not further methylated to the 5-methylpyrrolyl-2-carboxyl compound, i.e. clorobiocin, suggesting that methylation does not take place after the acyl transfer. Additional investigations for the presence of 5-methylpyrrolyl-2-carboxylic acid in the mutants, and inactivation experiments with the methyltransferase gene cloN6, suggested that methylation by CloN6 and acyl transfer by CloN7 take place in a concerted fashion, requiring the presence of both proteins for efficient product formation. A mechanism for the methylation/acyl transfer process in the late steps of clorobiocin biosynthesis, involving CloN1, CloN2, CloN5, CloN6 and CloN7 is suggested.     

Installation of the pyrrolyl-2-carboxyl pharmacophore by CouN1 and CouN7 in the late biosynthetic steps of the aminocoumarin antibiotics clorobiocin and coumermycin A1

The 5-methyl-2-pyrrolylcarbonyl moiety of the aminocoumarin antibiotics clorobiocin and coumermycin A1 is the key pharmacophore for targeting the ATP-binding site of GyrB for inhibition of the bacterial type-II topoisomerase DNA gyrase. During the late stage of clorobiocin and coumermycin A1 biosynthesis, the pyrrolyl-2-carboxyl group is transferred from the peptidyl carrier proteins Clo/CouN1 to the 3'-hydroxyl of the 4-methoxy-L-noviosyl scaffold by the action of the acyltransferases Clo/CouN7. CouN1 and CouN7 have now been heterologously expressed and purified from Escherichia coli. The apo form of CouN1 is converted to the acyl-holo form by loading with pyrrolyl-2-carboxyl-S-pantetheinyl moieties from synthetic pyrrolyl- and 5-methylpyrrolyl-CoAs by the action of the phosphopantetheinyl transferase Sfp. CouN7 acts as an acyltransferase, moving the pyrrole acyl moieties from CouN1 to the noviose sugar of descarbamoylnovobiocin. When the 5-methylpyrrolyl-2-carboxyl-thioester of CouN1 is the cosubstrate, the in vitro product differs from clorobiocin only in a CH3 for Cl group change on the coumarin ring. Double transfer of this acyl moiety by CouN7 to the penultimate intermediate in coumermycin A1 assembly completes that antibiotic biosynthetic pathway.     

Structural and kinetic evidence that catalytic reaction of human UDP-glucose 6-dehydrogenase involves covalent thiohemiacetal and thioester enzyme intermediates

Biosynthesis of UDP-glucuronic acid by UDP-glucose 6-dehydrogenase (UGDH) occurs through the four-electron oxidation of the UDP-glucose C6 primary alcohol in two NAD⁺-dependent steps. The catalytic reaction of UGDH is thought to involve a Cys nucleophile that promotes formation of a thiohemiacetal enzyme intermediate in the course of the first oxidation step. The thiohemiacetal undergoes further oxidation into a thioester, and hydrolysis of the thioester completes the catalytic cycle. Herein we present crystallographic and kinetic evidence for the human form of UGDH that clarifies participation of covalent catalysis in the enzymatic mechanism. Substitution of the putative catalytic base for water attack on the thioester (Glu¹⁶¹) by an incompetent analog (Gln¹⁶¹) gave a UGDH variant (E161Q) in which the hydrolysis step had become completely rate-limiting so that a thioester enzyme intermediate accumulated at steady state. By crystallizing E161Q in the presence of 5 mm UDP-glucose and 2 mm NAD⁺, we succeeded in trapping a thiohemiacetal enzyme intermediate and determined its structure at 2.3 Å resolution. Cys²⁷⁶ was covalently modified in the structure, establishing its role as catalytic nucleophile of the reaction. The thiohemiacetal reactive C6 was in a position suitable to become further oxidized by hydride transfer to NAD⁺. The proposed catalytic mechanism of human UGDH involves Lys²²⁰ as general base for UDP-glucose alcohol oxidation and for oxyanion stabilization during formation and breakdown of the thiohemiacetal and thioester enzyme intermediates. Water coordinated to Asp²⁸⁰ deprotonates Cys²⁷⁶ to function as an aldehyde trap and also provides oxyanion stabilization. Glu¹⁶¹ is the Brønsted base catalytically promoting the thioester hydrolysis.     

Naphthalene metabolism by pseudomonads: purification and properties of 1,2-dihydroxynaphthalene oxygenase.

1,2-Dihydroxynaphthalene oxygenase was purified from Pseudomonas putida NCIB 9816 grown on naphthalene as the sole source of carbon and energy. The enzyme had a subunit molecular weight of 19,000 and in a medium containing phosphate buffer, 1 mM mercaptoethanol, and 10% (vol/vol) ethanol had a native molecular weight greater than 275,000. The enzyme required Fe2+ for activity. It was inactivated slowly on standing, and inactivation was accelerated by dilution with aerated buffers and by H2O2. Bathophenanthroline sulfonate, o-phenanthroline, 8-hydroxyquinoline, and 2,2'-dipyridyl also inhibited the enzyme. The inactive enzyme was reactivated by anaerobic incubation with ferrous sulfate and ferrous ammonium sulfate. Thiol reagents and acetone, ethanol, or glycerol decreased the rate of loss of activity. The enzyme was most active with 1,2-dihydroxynaphthalene, for which the Km was 2.8 X 10(-4) M. 3-Methyl- and 4-methylcatechols were oxidized at 3 and 1.5%, respectively, of the rate of 1,2-dihydroxynaphthalene, and the Km for 3-methylcatechol was 1.5 X 10(-4) M. Purified 1,2-dihydroxynaphthalene oxygenase catalyzed the oxidation of 1,2-dihydroxynaphthalene, leading to the appearance of 2-hydroxychromene-2-carboxylic acid, but 3-methylcatechol was oxidized by this enzyme to 2-hydroxy-6-oxoheptadienoic acid. Thus, a product structurally analogous to 2-hydroxychromene-2-carboxylic acid was not observed when 3-methylcatechol was oxidized. This may indicate that 2-hydroxychromene-2-carboxylic acid results from cyclization of a ring fission product before release from the enzyme.     

Sequence of the cysteinyl-containing peptides of 4-aminobutyrate aminotransferase. Identification of sulfhydryl residues involved in intersubunit linkage

Three cysteine-containing tryptic peptides were isolated and sequenced from mitochondrial 4-aminobutyrate aminotransferase using DABIA (4-dimethylaminoazobenzene-4-iodoacetamide) as specific labeling reagent for sulfhydryl groups. The enzyme is a dimer made up of two identical subunits, but four out of the six cysteinyl residues/dimer form disulfide bonds when treated with iodosobenzoate to yield inactive enzyme species. To identify the cysteinyl residues undergoing reversible oxidation/reduction, the S-DABIA-labeling patterns of the fully reduced (active) and fully oxidized (inactive) forms of the enzyme were compared. Tryptic digests of the reduced enzyme contained three labeled peptides. If the enzyme was treated with iodosobenzoate prior to reaction with DABIA and tryptic digestion, only one labeled peptide was detected and identified (peptide I), indicating that the two missing cysteinyl-containing peptides (peptides II, III) have been oxidized. The sulfhydryl groups undergoing oxidation/reduction were found to be intersubunit, based on SDS/polyacrylamide gel electrophoresis results. The loss of catalytic activity of 4-aminobutyrate aminotransferase by oxidation of sulfhydryl residues is related to constraints imposed at the subunit interface by the insertion of disulfide bonds.     

The purification and properties of p-cresol-(acceptor) oxidoreductase (hydroxylating), a flavocytochrome from Pseudomonas putida.

The enzyme that catalyses the hydroxylation of the methyl group of p-cresol was purified from Pseudomonas putida. It has mol.wt. 115000 and appears to contain two subunits of equal molecular weight. One subunit is a c-type cytochrome and the other is a flavoprotein. Reduction of the cytochrome occurred on addition of substrate. The same enzyme catalyses both p-cresol hydroxylation and the further oxidation of the product, 4-hydroxybenzyl alcohol. The stoicheiometry of acceptor reduced per molecule of substrate oxidized is that for two dehydrogenation reactions. The Km for p-cresol is 7.3 x 10(-6) M and that for 4-hydroxybenzyl alcohol is 47.6 x 10(-6) M. The enzyme, which is assayed with phenazine methosulphate as electron acceptor, was stimulated by particulate material, which probably contains the acceptor in vivo.     

The catalytic activity of horse spleen apoferritin. Preliminary kinetic studies and the effect of chemical modification

1. Horse spleen apoferritin catalyses the oxidation of Fe(2+) to Fe(3+) with molecular O(2) as electron acceptor under conditions where a number of other proteins have no such effect. The product is similar to ferritin by a number of criteria. 2. The progress curve is hyperbolic and the increase in initial velocity is linear with increasing apoferritin concentration. With respect to Fe(2+) the reaction follows Michaelis-Menten kinetics. The pH-dependence of the reaction was determined between pH4.3 and 6.0. 3. Modification of both tryptophan residues/apoferritin subunit with 2-nitrophenylsulphenyl chloride does not affect either k(cat.) or K(m) for the oxidation. Neither does the guanidination of seven out of nine lysine residues/subunit, the modification of nine out of ten arginine residues/subunit with cyclohexanedione, or the nitration of one out of five tyrosine residues/subunit with tetranitromethane. 4. The carboxymethylation of two out of three cysteine residues/subunit and of one out of six histidine residues/subunit can be achieved with iodoacetic acid. This carboxymethylated apoferritin is completely inactive in Fe(2+) oxidation. 5. Apoferritin does not take up Fe(3+). It appears from these results that Fe(2+) is the form in which iron is taken up by ferritin in a reaction where the protein acts as an enzyme which traps the product in the interior of the protein shell.     

Purification and characterization of 3-hydroxyisobutyrate dehydrogenase from rabbit liver

3-Hydroxyisobutyrate dehydrogenase (3-hydroxy-2-methyl propanoate: NAD+ oxidoreductase, EC 1.1.1.31) was purified 1800-fold from rabbit liver by detergent extraction, differential solubility in polyethylene glycol and (NH4)2SO4, and column chromatography on DEAE-Sephacel, phenyl-Sepharose, CM(carboxymethyl)-Sepharose, Affi-Gel Blue, and Ultrogel AcA-34. The enzyme had a native Mr of 74,000 and appeared to be a homodimer with subunit Mr = 34,000. The enzyme was specific for NAD+. It oxidized both S-3-hydroxyisobutyrate and R-3-hydroxyisobutyrate, but the kcat/Km was approximately 350-fold higher for the S-isomer. Steady state kinetic analysis indicates an ordered Bi Bi reaction mechanism with NAD+ binding before 3-hydroxyisobutyrate. The enzyme catalyzed oxidation of S-3-hydroxyisobutyrate between pH 7.0 and 11.5 with optimal activity between pH 9.0 and 11.0. The enzyme apparently does not have a metal ion requirement. Essential sulfhydryl groups may be present at both the 3-hydroxyisobutyrate and NAD+ binding sites since inhibition by sulfhydryl-binding agents was differentially blocked by each substrate. The enzyme is highly sensitive to product inhibition by NADH which may play an important physiological role in regulating the complete oxidation of valine beyond the formation of 3-hydroxyisobutyrate.     

Identification and characterization of the Rhizobium sp. strain GIN611 glycoside oxidoreductase resulting in the deglycosylation of ginsenosides

Using enrichment culture, Rhizobium sp. strain GIN611 was isolated as having activity for deglycosylation of a ginsenoside, compound K (CK). The purified heterodimeric protein complex from Rhizobium sp. GIN611 consisted of two subunits with molecular masses of 63.5 kDa and 17.5 kDa. In the genome, the coding sequence for the small subunit was located right after the sequence for the large subunit, with one nucleotide overlapping. The large subunit showed CK oxidation activity, and the deglycosylation of compound K was performed via oxidation of ginsenoside glucose by glycoside oxidoreductase. Coexpression of the small subunit helped soluble expression of the large subunit in recombinant Escherichia coli. The purified large subunit also showed oxidation activity against other ginsenoside compounds, such as Rb1, Rb2, Rb3, Rc, F2, CK, Rh2, Re, F1, and the isoflavone daidzin, but at a much lower rate. When oxidized CK was extracted and incubated in phosphate buffer with or without enzyme, (S)-protopanaxadiol [PPD(S)] was detected in both cases, which suggests that deglycosylation of oxidized glucose is spontaneous.     

Negative homotropic cooperativity in rat muscle AMP deaminase. A kinetic study on the inhibition of the enzyme by ATP

1. Rat skeletal muscle AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) at optimal KCl concentrations shows a biphasic response to increasing levels of the allosteric inhibitor ATP. 2. Up to 10 micrometer, ATP appears to convert the enzyme to a form exhibiting sigmoidal kinetics while at higher concentrations its inhibitory effect is manifested by an alteration of AMP binding to AMP deaminase indicative of negative homotropic cooperativity at about 50% saturation. 3. AMP deaminase is inactivated by incubation with the periodate oxidation product of ATP. The (oxidized ATP)--AMP deaminase complex stabilized by NaBH4 reduction shows kinetic properties similar to those of the native enzyme in the presence of high ATP concentrations. 4. A plausible explanation of the observed cooperativity is that ATP induces different conformational state of AMP deaminase subunits, causing the substrate to follow a sequential mechanism of binding to enzyme. 5. Binding of the radioactive oxidized ATP shows that 3.2 mol of this reagent bind per mol AMP deaminase.     

A study of the spectral and redox properties and covalent flavinylation of the flavoprotein component of p-cresol methylhydroxylase reconstituted with FAD analogues

The spectral and redox properties are described for the wild-type and Y384F mutant forms of the flavoprotein component (PchF) of flavocytochrome, p-cresol methylhydroxylase (PCMH), and cytochrome-free PchF that harbor FAD analogues. The analogues are iso-FAD (8-demethyl-6-methyl-FAD), 6-amino-FAD (6-NH(2)-FAD), 6-bromo-FAD (6-Br-FAD), 8-nor-8-chloro-FAD (8-Cl-FAD), and 5-deaza-5-carba-FAD (5-deaza-FAD). All of the analogues bound noncovalently and stoichiometrically to cytochrome-free apo-PchF, and the resulting holoproteins had high affinity for the cytochrome subunit, PchC. Noncovalently bound FAD, 6-Br-FAD, or 6-NH(2)-FAD can be induced to bind covalently by exposing holo-PchF to PchC. The rate of this process and the redox potential of the noncovalently bound flavin may be correlated. In addition, the redox potential of each FAD analogue was higher when it was covalently bound than when noncovalently bound to PchF. Furthermore, the potential of a covalently bound or noncovalently bound FAD analogue increased on association of the corresponding holo-PchF with PchC, and the activity increased as the flavin's redox potential increased. It was discovered also that 4-hydroxybenzaldehyde, the final p-cresol oxidation product, is an efficient competitive inhibitor for substrate oxidation by PchF since it binds tightly to this protein when the flavin is oxidized, although it binds more loosely to the enzyme with reduced flavin. Finally, the energies of the charge-transfer bands for the interaction of bound flavin analogues with 4-Br-phenol (a substrate mimic) increased as the potential decreases, although a simple global correlation was not seen. This is the case because the energy is also a function of the redox properties of the bound mimic. The implications of these findings to covalent flavinylation and catalysis are discussed.     

Chemoenzymatic formation of novel aminocoumarin antibiotics by the enzymes CouN1 and CouN7

The aminocoumarin antibiotics novobiocin, clorobiocin, and coumermycin A1 are highly potent inhibitors of the bacterial type II topoisomerase DNA gyrase. The key pharmacophore of both clorobiocin and coumermycin A1, the 5-methyl-2-pyrrolylcarbonyl moiety, targets the ATP-binding site of GyrB. The 5-methyl-2-pyrrolylcarbonyl group is transferred by the acyltransferases Clo/CouN7 from the carrier proteins Clo/CouN1 to the 3'-hydroxyl of the l-noviosyl scaffold during the late steps of clorobiocin and coumermycin A1 biosynthesis. We first examined the substrate specificity of the purified thiolation domain protein CouN1 in becoming primed by the phosphopantetheinyltransferase Sfp using a variety of synthetic CoA analogues of the 5-methyl-2-pyrrolylcarbonyl moiety. The acyl-S-CouN1 thioesters were then assayed as donors to the 3'-OH group of descarbamoylnovobiocin by the acyltransferase CouN7, resulting in 21 novel variants with heterocyclic acyl groups installed on the noviosyl moiety of the aminocoumarin scaffold. Scaleup of a 5-methylthiophene derivative yielded a compound with activity against both Gram-negative and Gram-positive bacteria. The minimal inhibitory concentration found for the Gram-positive bacteria was comparable to that of novobiocin.     

Electronic probes of the mechanism of substrate oxidation by buttermilk xanthine oxidase: role of the active-site nucleophile in oxidation

Quinazolin-4(3H)-one derivatives substituted at the 6- and/or 7-position were studied as electronic probes of substrate oxidation by buttermilk xanthine oxidase. Since the enzyme active site possesses dimensional tolerance, the substituents exert an electronic effect rather than a steric effect on the catalytic parameters for oxidation. This feature permitted a Hammett plot to be made for quinazoline-oxygen substrate activity. The concave downward nature of this plot indicates that the rate-determining step for oxidation changes when electron-withdrawing substituents are placed on the substrate. This plot and kinetic isotope effects obtained with 2-deuterio derivatives of the substrates indicate the following: (i) oxidation involves nucleophile transfer to the C(2) center in concert with hydride transfer to the molybdenum center, and (ii) the formation of oxidized product is a three-step process, i.e., Michaelis complex formation, oxidation, and hydrolysis of the oxidized substrate-enzyme adduct. The role of the nucleophile in oxidation appears to be to increase the electron density in the substrate and thereby facilitate hydride transfer. The implication of this study is that similar electronic probes may be designed to study other purine-utilizing enzymes possessing a dimensionally tolerant active site.     

2-Chloro-2-phenylethylamine as a mechanistic probe and active site-directed inhibitor of monoamine oxidase from bovine liver mitochondria

The reaction of 2-chloro-2-phenylethylamine with monoamine oxidase B was investigated to study the mechanism of this enzyme and its inactivation by this compound. 2-Chloro-2-phenylethylamine is a substrate with a Km of 30 microM and a turnover number of 80 min-1 at pH 6.5 at 30 degrees C. Incubation of 2-chloro-2-phenylethylamine with the enzyme led to the normal oxidation product, 2-chloro-2-phenylacetaldehyde, but only traces (0.25 mol%) of 2-phenylacetaldehyde, the product anticipated if the oxidation of substrate involved a stabilized carbanion at C-1 and elimination of chloride ion. These data suggest that a carbanion is not a likely intermediate in the oxidation of amines by monoamine oxidase. During the mechanistic studies we noted time-dependent inactivation of monoamine oxidase B by 2-chloro-2-phenylethylamine under both aerobic and anaerobic conditions. Inactivation was not reversible. Aerobically 2-chloro-2-phenylethylamine is oxidized to 2-chloro-2-phenylacetaldehyde which covalently modifies the enzyme (tau 1/2 = 40 min). Benzyl alcohol, a substrate analog, gives substantial protection against inactivation under aerobic conditions (tau 1/2 = 320 min), suggesting that an active site residue is modified. Anaerobic reaction of 2-chloro-2-phenylethylamine with monoamine oxidase B probably proceeds by direct alkylation of an enzyme residue (tau 1/2 = 140 min). Reduction with [3H]NaBH4 of the inactivated enzyme gave from 0 to 0.7 and from 4.5 to 5.6 mol of hydride incorporation for enzyme inactivated anaerobically and aerobically, respectively. The latter results are in agreement with inactivation by unmodified inhibitor and inactivation by oxidized inhibitor for the anaerobic and aerobic reactions, respectively. It is suggested that 2-chloro-2-phenylethylamine or its oxidation product 2-chloro-2-phenylacetaldehyde may serve as an active site affinity reagent for monoamine oxidase.     

Inactivation of two-electron reduced medium chain acyl-CoA dehydrogenase by 2-octynoyl-CoA

The acetylenic thioester, 2-octynoyl-CoA, inactivates medium chain acyl-CoA dehydrogenase from pig kidney by two distinct pathways depending on the redox state of the FAD prosthetic group. Inactivation of the oxidized dehydrogenase occurs with labeling of an active site glutamate residue and elimination of CoASH. Incubation of the reduced dehydrogenase with 2-octynoyl-CoA rapidly forms a kinetically stable dihydroflavin species which is resistant to reoxidation using trans-2-octenoyl-CoA, molecular oxygen, or electron transferring flavoprotein. The reduced enzyme derivative shows extensive bleaching at 446 nm with shoulders at 320 and 380 nm. Denaturation of the reduced derivative in 80% methanol yields a mixture of products which was characterized by HPLC, by uv/vis, and by radiolabeling experiments. Approximately 20% of the flavin is recovered as oxidized FAD, about 40% is retained covalently attached to the protein, and the remainder is distributed between several species eluting after FAD on reverse-phase HPLC. The spectrum of one of these species ressembles that of a N(5)-C(4a) dihydroflavin adduct. These data suggest that a primary reduced flavin species undergoes various rearrangements during release from the protein. The possibility that the inactive modified enzyme represents a covalent adduct between 2-octynoyl-CoA and reduced flavin is discussed. Analogous experiments using enzyme substituted with 1,5-dihydro-5-deaza-FAD show rapid and quantitative reoxidation of the flavin by 0.5 eq of 2-octynoyl-CoA.     

Studies on the structure and mechanism of Streptococcus faecium L-alpha-glycerophosphate oxidase

An FAD-containing L-alpha-glycerophosphate oxidase has been purified to homogeneity from Streptococcus faecium. The purified protein exists as a dimer (subunit Mr = 65,000); each subunit contains 1 mol of FAD. The enzyme contains no iron, as determined by atomic absorption spectroscopy. The alpha-glycerophosphate oxidase reacts reversibly with sulfite to form a covalent N(5) adduct; it preferentially binds the anionic form of the native oxidized FAD, and it also stabilizes the p-quinonoid form of 8-mercapto-FAD. The enzyme shows an unusually high reactivity with ferricyanide in the absence of oxygen; however, there is no evidence for any superoxide ion (O2-.) generation under standard assay conditions. Dithionite titrations of the enzyme reveal an unusual pH dependence for the stabilization of the flavin semiquinone; only at pH 8.5 does significant anionic semiquinone accumulate. L-alpha-Glycerophosphate rapidly reduces the enzyme-bound FAD; in addition, a small amount of catalytically insignificant red semiquinone appears under these conditions. The 5-deaza-FAD-reconstituted enzyme is also reduced by substrate, strongly suggesting that a radical mechanism is not involved in the oxidation of alpha-glycerophosphate. Furthermore, nitroethane anion reduces the native enzyme; this observation suggests that an electron transfer mechanism involving a substrate carbanion is possible with this enzyme.     

Microbial oxidation of methanol: Properties of crystallized alcohol oxidase from a yeast, Pichia sp

Alcohol oxidase (alcohol:oxygen oxidoreductase) was crystallized from a methanolgrown yeast, Pichia sp. The crystalline enzyme is homogenous as judged from polyacrylamide gel electrophoresis. Alcohol oxidase catalyzed the oxidation of short-chain primary alcohols (C₁ to C₆), substituted primary alcohols (2-chloroethanol, 3-chloro-1-propanol, 4-chlorobutanol, isobutanol), and formaldehyde. The general reaction with an oxidizable substrate is as follows: Primary alcohol + O₂ → aldehyde + H₂O₂ Formaldehyde + O₂ → formate + H₂O₂. Secondary alcohols, tertiary alcohols, cyclic alcohols, aromatic alcohols, and aldehydes (except formaldehyde) were not oxidized. The K_m values for methanol and formaldehyde are 0.5 and 3.5 mm, respectively. The stoichiometry of substrate oxidized (alcohol or formaldehyde), oxygen consumed, and product formed (aldehyde or formate) is 1:1:1. The purified enzyme has a molecular weight of 300,000 as determined by gel filtration and a subunit size of 76,000 as determined by sodium dodecyl sulfate-gel electrophoresis, indicating that alcohol oxidase consists of four identical subunits. The purified alcohol oxidase has absorption maxima at 460 and 380 nm which were bleached by the addition of methanol. The prosthetic group of the enzyme was identified as a flavin adenine dinucleotide. Alcohol oxidase activity was inhibited by sulfhydryl reagents (p-chloromercuribenzoate, mercuric chloride, 5,5′-dithiobis-2-nitrobenzoate, iodoacetate) indicating the involvement of sulfhydryl groups(s) in the oxidation of alcohols by alcohol oxidase. Hydrogen peroxide (product of the reaction), 2-aminoethanol (substrate analogue), and cupric sulfate also inhibited alcohol oxidase activity.     

Characterization of pertussis toxin by LC-MS/MS

Liquid chromatography-mass spectrometry (LC-MS) with a dual spray electrospray ionization source has been used to measure the molecular weights of pertussis toxin (PT) subunits. Measurement accuracy better than 0.4 Da was achieved for all PT subunits in the molecular weight range of 11,000 to 27,000 Da. At this mass assignment accuracy level, the sequences of the PT subunits investigated in this study are easily determined based on molecular weight alone. The subunits 1, 2, and 5 of PT were observed to undergo oxidation under normal storage conditions as ammonium sulfate suspension at 2 to 8 degrees C. These oxidized subunits can be separated completely or partially by reverse-phase high-performance liquid chromatography (HPLC) from their native counterparts. For the determination of oxidation sites, the oxidized subunits and their nonoxidized counterparts were fraction collected, trypsin digested, and mapped by LC-MS. The oxidized peptides and their nonoxidized counterparts were further studied by liquid chromatography-tandem mass spectrometry (LC-MS/MS) to confirm their identities. The methionines at position 212 of subunit 1, at position 89 of subunit 2, and at position 40 of subunit 5 were found to be the primary sites of oxidation.     

Degradation of pentachlorophenol by the white rot fungus Phanerochaete chrysosporium grown in ammonium lignosulphonate media

Removal and degradation of pentachlorophenol (PCP) by Phanerochaete chrysosporium in static flask cultures was studied using ammonium lignosulphonates (LS), a waste product of the papermill industry, as a carbon and nitrogen source. After 3 days, cultures of P. chrysosporium grown in either a 2% LS (nitrogen-sufficient) medium or a 0.23% LS and 2% glucose (nitrogen-deficient) medium removed 72 to 75% of PCP, slightly less than the 95% removal seen using nitrogen-deficient glucose and ammonia medium. PCP dehalogenation occurred despite the fact that extracellular enzyme (LiP) activity, measured by a veratryl alcohol oxidation assay and by PCP disappearance in cell-free extracts, was inhibited by LS. This inactivation of LiP likely contributed to the lower percent of PCP dehalogenation observed using the LS media. In order to better understand the relationship between PCP disappearance and dehalogenation, we measured the fate of the chlorine in PCP. After 13 days, only 1.8% of the initial PCP added was recoverable as PCP. The remainder of the PCP was either mineralized or transformed to breakdown intermediates collectively identified as organic halides. The largest fraction of the original chlorine (58%) was recovered as organic (non-PCP) halide, most of which (73%) was associated with the cell mass. Of the remaining chlorine, 40% was released as chloride ion, indicating a level of dehalogenation in agreement with previously reported values.     

Degradation of pentachlorophenol by the white rot fungus Phanerochaete chrysosporium grown in ammonium lignosulphonate media

Removal and degradation of pentachlorophenol (PCP) by Phanerochaete chrysosporium in static flask cultures was studied using ammonium lignosulphonates (LS), a waste product of the papermill industry, as a carbon and nitrogen source. After 3 days, cultures of P. chrysosporium grown in either a 2% LS (nitrogen-sufficient) medium or a 0.23% LS and 2% glucose (nitrogen-deficient) medium removed 72 to 75% of PCP, slightly less than the 95% removal seen using nitrogen-deficient glucose and ammonia medium. PCP dehalogenation occurred despite the fact that extracellular enzyme (LiP) activity, measured by a veratryl alcohol oxidation assay and by PCP disappearance in cell-free extracts, was inhibited by LS. This inactivation of LiP likely contributed to the lower percent of PCP dehalogenation observed using the LS media. In order to better understand the relationship between PCP disappearance and dehalogenation, we measured the fate of the chlorine in PCP. After 13 days, only 1.8% of the initial PCP added was recoverable as PCP. The remainder of the PCP was either mineralized or transformed to breakdown intermediates collectively identified as organic halides. The largest fraction of the original chlorine (58%) was recovered as organic (non-PCP) halide, most of which (73%) was associated with the cell mass. Of the remaining chlorine, 40% was released as chloride ion, indicating a level of dehalogenation in agreement with previously reported values.