Structural and mechanistic studies of arylalkylhydrazine inhibition of human monoamine oxidases A and B

The structure and mechanism of human monoamine oxidase B (MAO B) inhibition by hydrazines are investigated and compared with data on human monoamine oxidase A (MAO A). The inhibition properties of phenylethylhydrazine, benzylhydrazine, and phenylhydrazine are compared for both enzymes. Benzylhydrazine is bound more tightly to MAO B than to MAO A, and phenylhydrazine is bound weakly by either enzyme. Phenylethylhydrazine stoichiometrically reduces the covalent FAD moieties of MAO A and of MAO B. Molecular oxygen is required for the inhibition reactions, and the level of O2 consumption for phenylethylhydrazine is 6-7-fold higher with either MAO A or MAO B than for the corresponding reactions with benzylhydrazine or phenylhydrazine. Mass spectral analysis of either inhibited enzyme shows the major product is a single covalent addition of the hydrazine arylalkyl group, although lower levels of dialkylated species are detected. Absorption and mass spectral data of the inhibited enzymes show that the FAD is the major site of alkylation. The three-dimensional (2.3 A) structures of phenylethylhydrazine- and benzylhydrazine-inhibited MAO B show that alkylation occurs at the N(5) position on the re face of the covalent flavin with loss of the hydrazyl nitrogens. A mechanistic scheme is proposed to account for these data, which involves enzyme-catalyzed conversion of the hydrazine to the diazene. From literature data on the reactivities of diazenes, O2 then reacts with the bound diazene to form an alkyl radical, N2 and superoxide anion. The bound arylalkyl radical reacts with the N(5) of the flavin, while the dissociated diazene reacts nonspecifically with the enzyme through arylalkylradicals.     

Characterization of a transient covalent adduct formed during dimethylarginine dimethylaminohydrolase catalysis

Dimethylarginine dimethylaminohydrolase (DDAH) regulates the concentrations of human endogenous inhibitors of nitric oxide synthase, N(omega)-methyl-l-arginine (NMMA), and asymmetric N(omega),N(omega)-dimethyl-l-arginine (ADMA). Pharmacological regulation of nitric oxide synthesis is an important goal, but the catalytic mechanism of DDAH remains largely unexplored. A DDAH from Pseudomonas aeruginosa was cloned, and asymmetrically methylated arginine analogues were shown to be the preferred substrates, with ADMA displaying a slightly higher k(cat)/K(M) value than NMMA. DDAH is similar to members of a larger superfamily of guanidino-modifying enzymes, some of which have been shown to use an S-alkylthiouronium intermediate during catalysis. No covalent intermediates were found to accumulate during steady-state turnover reactions of DDAH with NMMA or ADMA. However, identification of a new substrate with an activated leaving group, S-methyl-l-thiocitrulline (SMTC), enabled acid trapping and ESI-MS characterization of a transient covalent adduct with a mass of 158 +/- 10 Da that accumulates during steady-state turnover. Subsequent trapping, proteolysis, peptide mapping and fragmentation by mass spectrometry, and site-directed mutagenesis demonstrated that this covalent adduct was attached to an active site residue and implicates Cys249 as the catalytic nucleophile required for intermediate formation. The use of covalent catalysis clearly links DDAH to this superfamily of enzymes and suggests that an S-alkylthiouronium intermediate may be a conserved feature in their mechanisms.     

The importance of intercalation in the covalent binding of benzo(a)pyrene diol epoxide to DNA

The primary mode of non-covalent interaction of the strong carcinogen, benzo(a)pyrene diol epoxide, with DNA is through intercalation. It has variously been suggested that intercalative complexes may be prerequisite for either covalent binding or DNA-catalysed hydrolysis of the epoxide or both. Geacintov [Geacintov, N. E. (1986). Carcinogenesis 7, 589.] has recently argued that intercalation is important in covalent binding and presented theoretical constructs consistent with this proposal. A more general theoretical model is presented here which includes the possibilities that either catalysis of hydrolysis or covalent binding of benzo(a)pyrene diol epoxide DNA can occur (a) in an intercalation complex, or (b) without formation of a detectable, physically bound complex. It is shown that a variety of possible mechanisms formulated under this general theory lead to equations for overall reaction rates and covalent binding fractions which are all of the same form with respect to DNA concentration dependence. A consequence of this is that experimental studies of the dependence of hydrolysis rates and covalent binding fractions on DNA concentration do not distinguish between the various possible mechanisms. These findings are discussed in relation to the interactions of benzo(a)pyrene diol epoxide with chromatin in cells.     

Molecular mechanisms of the radiation destruction and formation of cross links in chromatin in aqueous solutions

The modified gel-electrophoresis techniques were used to study DNA destruction in oligonucleosomes of the chromatin and the formation of DNA-protein cross-links under the effect of 60Co-gamma-rays. The yields of DNA destruction were evaluated in different conditions of chromatin irradiation: they were comparable with the yields of single-strand breaks. The bonds in the DNA-protein polymer formed were found to be covalent. It was shown that the processes of formation of cross-links and peroxide radicals (hydroperoxides) were mutually exclusive.     

Peroxidase-catalyzed oxidation of eugenol: formation of a cytotoxic metabolite(s)

The oxidation of eugenol (4-allyl-2-methoxyphenol) by horseradish peroxidase was studied. Following the initiation of the reaction with hydrogen peroxide, eugenol was oxidized via a one-electron pathway to a phenoxyl radical which subsequently formed a transient, yellow-colored intermediate which was identified as a quinone methide. The eugenol phenoxyl radical was detected using fast-flow electron spin resonance. The radicals and/or quinone methide further reacted to form an insoluble complex polymeric material. The stoichiometry of the disappearance of eugenol versus hydrogen peroxide was approximately 2:1. The addition of glutathione or ascorbate prevented the appearance of the quinone methide and also prevented the disappearance of the parent compound. In the presence of glutathione, a thiyl radical was detected, and increases in oxygen consumption and in the formation of oxidized glutathione were also observed. These results suggested that glutathione reacted with the eugenol phenoxyl radical and reduced it back to the parent compound. Glutathione also reacted directly with the quinone methide resulting in the formation of a eugenol-glutathione conjugate(s). Using 3H-labeled eugenol, extensive covalent binding to protein was observed. Finally, the oxidation products of eugenol/peroxidase were observed to be highly cytotoxic using isolated rat hepatocytes as target cells.     

The egg-shell of Drosophila melanogaster III. Covalent crosslinking of the chorion proteins involves endogenous hydrogen peroxide

Utilizing two cytochemical methods, namely, diaminobenzidine for the assay of peroxidases and cerium(III) chloride for the localization of hydrogen peroxide it was found that the enzyme exists in two out of the five egg-shell layers: the innermost choronic layer and the endochorion. In addition, hydrogen peroxide which acts as a substrate for the enzyme in vitro enabling the formation of covalent bonding between the egg-shell proteins, was found to be produced at the follicle cell plasma membrane during the last stage of oogenesis. It is concluded that hydrogen peroxide is an endogenous, programmed product of the follicle cells, responsible for the action of peroxidase in order to oxidize the tyrosyl residues producing di-tyrosine and tri-tyrosine bonds between the chorion polypeptides.     

Oxidative cell injury in the killing of cultured hepatocytes by allyl alcohol

The killing of cultured hepatocytes by allyl alcohol depended on the metabolism of this hepatotoxin by alcohol dehydrogenase to the reactive electrophile, acrolein. An inhibitor of alcohol dehydrogenase, pyrazole, prevented both the toxicity of allyl alcohol and the rapid depletion of GSH. Treatment of the hepatocytes with a ferric iron chelator, deferoxamine, or an antioxidant, N,N'-diphenyl-p-phenylenediamine (DPPD), prevented the cell killing but not the metabolism of allyl alcohol and the resulting depletion of GSH. Inhibition of glutathione reductase by 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) sensitized the hepatocytes to allyl alcohol, an effect that was not attributable to the reduction in GSH with BCNU. The cell killing with allyl alcohol was preceded by the peroxidation of cellular lipids as evidence by an accumulation of malondialdehyde in the cultures. Deferoxamine and DPPD prevented the lipid peroxidation in parallel with their protection from the cell killing. These data indicate that acrolein produces an abrupt depletion of GSH that is followed by lipid peroxidation and cell death. Such oxidative cell injury is suggested to result from the inability to detoxify endogenous hydrogen peroxide and the ensuing iron-dependent formation of a potent oxidizing species. Oxidative cell injury more consistently accounts for the hepatotoxicity of allyl alcohol than does the covalent binding of acrolein to cellular macromolecules.     

Rabbit muscle phosphofructokinase. 2. Inactivation by the affinity label 5'-[p-(fluorosulfonyl)benzoyl]-1,N6-ethenoadenosine

The reaction of the fluorescent affinity label 5'-[p-(fluorosulfonyl)benzoyl]-1,N6-ethenoadenosine with rabbit skeletal muscle phosphofructokinase results in an inactivation of the enzyme and in the covalent incorporation of up to one label/monomer. The substrates, MgATP and fructose 6-phosphate, each protect against inactivation of the enzyme, but neither diminishes the extent of covalent incorporation of the label, indicating that the inactivation is not the result of covalent incorporation of the label. Dithiothreitol reactivates the inactivated enzyme but does not reduce the extent of incorporation of the label. A determination of the number of free sulfhydryl groups on the enzyme as a function of the extent of inactivation by the reagent suggests that the inactivation is associated with the loss of two free sulfhydryl groups per phosphofructokinase monomer. The inactivation reaction appears to involve the reversible formation of an enzyme-reagent complex (Kd = 1.11 mM) prior to the conversion of the complex to inactive enzyme (k1 = 0.98 min-1). In view of the protection afforded by either substrate and the evidence suggesting the formation of an enzyme-reagent complex prior to inactivation, it would appear that the inactivation results from a reagent-mediated formation of a disulfide bond between two cysteinyl residues in close proximity, possibly in or near the catalytic site of the enzyme. The site of covalent attachment of the label appears to be the binding site specific for the activating adenine nucleotides cAMP, AMP, and ADP. The extent of covalent incorporation of the label at this site is diminished in the presence of cAMP, and phosphofructokinase modified at this site by this affinity label is no longer subject to activation by cAMP.     

Reaction of 3-amino-1:2:4-triazole with lactoperoxidase

Bovine lactoperoxidase (LPO) gradually lost its enzymatic activity when dialyzed against a solution of 3-amino-1:2:4-triazole (AT) and hydrogen peroxide at pH 7.0. Amino acid analysis of the completely inactive enzyme revealed the formation of a new ninhydrin-positive chromatographic peak. This peak which had been observed previously when catalases were similarly reacted with AT in the presence of hydrogen peroxide is attributed to the covalent reaction product of AT with a histidyl residue. Concurrently with the appearance of the new ninhydrin-positive peak, the histidine content of LPO decreased by approximately two residues. Four to five residues of tyrosine were also lost.     

Cross-linking and amyloid formation by N- and C-terminal cysteine derivatives of human apolipoprotein C-II

We have investigated the effect of disulfide cross-linking on amyloid formation by human apolipoprotein (apo) C-II. Three derivatives of apoC-II were generated by inserting a cysteine residue on either the N-terminus (C(N)-apoC-II), C-terminus (C(C)-apoC-II), or both termini (C(N)C(C)-apoC-II). Under reducing conditions, all derivatives formed amyloid with a fibrous ribbon morphology similar to that of wild-type apoC-II. Under oxidizing conditions, C(N)- and C(N)C(C)-apoC-II formed a highly tangled network of fibrils, suggesting that the addition of an N-terminal cysteine to apoC-II promotes interfibril disulfide cross-links. Fibrils formed by C(C)-apoC-II under oxidizing conditions were closely packed but less tangled than fibrils formed by the C(N) and C(N)C(C) derivatives. The frequency of closed ring structures was more than doubled for C(C)-apoC-II compared to wild-type apoC-II. The kinetics of fibril formation by all cysteine derivatives was markedly enhanced under oxidizing conditions, suggesting that disulfide cross-linking promotes amyloid formation. Substoichiometric levels of preformed C(N)- and C(C)-apoC-II dimers accelerate amyloid formation by wild-type apoC-II. These data suggest that the N- and C-termini of apoC-II are close together in the amyloid fibril such that covalent cross-linking of either the N or C end of apoC-II promotes nucleation and the "seeding" of fibril growth.     

The catalytic mechanism of dye-decolorizing peroxidase DyP may require the swinging movement of an aspartic acid residue

The dye-decolorizing peroxidase (DyP)-type peroxidase family is a unique heme peroxidase family. The primary and tertiary structures of this family are obviously different from those of other heme peroxidases. However, the details of the structure-function relationships of this family remain poorly understood. We show four high-resolution structures of DyP (EC1.11.1.19), which is representative of this family: the native DyP (1.40 ?), the D171N mutant DyP (1.42 ?), the native DyP complexed with cyanide (1.45 ?), and the D171N mutant DyP associated with cyanide (1.40 ?). These structures contain four amino acids forming the binding pocket for hydrogen peroxide, and they are remarkably conserved in this family. Moreover, these structures show that OD2 of Asp171 accepts a proton from hydrogen peroxide in compound I formation, and that OD2 can swing to the appropriate position in response to the ligand for heme iron. On the basis of these results, we propose a swing mechanism in compound I formation. When DyP reacts with hydrogen peroxide, OD2 swings towards an optimal position to accept the proton from hydrogen peroxide bound to the heme iron.     

DNA strand transfer catalyzed by vaccinia topoisomerase: peroxidolysis and hydroxylaminolysis of the covalent protein-DNA intermediate

Vaccinia topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at sites containing the sequence 5'-CCCTT downward arrow. The covalently bound topoisomerase can religate the CCCTT strand to a 5'-OH-terminated polynucleotide or else transfer the strand to a non-DNA nucleophile such a water or glycerol. Here, we report that vaccinia topoisomerase also catalyzes strand transfer to hydrogen peroxide. The observed alkaline pH-dependence of peroxidolysis is consistent with enzyme-mediated attack by peroxide anion on the covalent intermediate. The reaction displays apparent first-order kinetics. From a double-reciprocal plot of k(obs) versus [H(2)O(2)] at pH 10, we determined a rate constant for peroxidolysis of 6.3 x 10(-)(3) s(-)(1). This rate is slower by a factor of 200 than the rate of topoisomerase-catalyzed strand transfer to a perfectly aligned 5'-OH DNA strand but is comparable to the rate of DNA strand transfer across a 1-nucleotide gap. Strand transfer to 2% hydrogen peroxide is 300 times faster than strand transfer to 20% glycerol and approximately 2000 times faster than topoisomerase-catalyzed hydrolysis of the covalent intermediate. Hydroxylamine is also an effective nucleophile in topoisomerase-mediated strand transfer (k(obs) = 6.4 x 10(-)(4) s(-)(1)). The rates of the peroxidolysis, hydroxylaminolysis, glycerololysis, and hydrolysis reactions catalyzed by the mutant enzyme H265A were reduced by factors of 100-700, in accordance with the 100- to 400-fold rate decrements in DNA cleavage and religation by H265A. We surmise that vaccinia topoisomerase catalyzes strand transfer to DNA and non-DNA nucleophiles via a common reaction pathway in which His-265 stabilizes the scissile phosphate in the transition state rather than acting as a general acid or base.     

Pattern of recognition of DNA by mammalian DNA topoisomerase II

The antitumor drug VP-16 stabilizes the topoisomerase II-DNA covalent complexes formed in an intermediate step of the isomerization reaction. The location of the sites of formation of these complexes and their relative strength were studied in vitro using pBR322. Sequences alignment of the regions containing the 24 detectable sites allows to identify GCGCGC-(N) alpha-TGAC with 9 less than or equal to alpha less than or equal to 25 as the DNA sequence recognized by topoisomerase II to form a cleavable complex. Changes in the last two nucleotides of the sequence determine weaker complexes.     

Cross linking of proteins in vitro by peroxidase

The enzyme peroxidase, a substrate (hydrogen donor), and hydrogen peroxide aggregated and polymerized soluble proteins included in the reaction mixture. Gel filtration and acrylamide disk gel electrophoresis revealed newly formed dimers, trimers, and higher protein polymers. Some of the protein polymers withstood the denaturing conditions of dodecyl sulfate disk gel electrophoresis; thus the formation of some covalent cross links was indicated. It is suggested that peroxidase catalyzes the oxidation of hydrogen donors to form free radicals or quinones, which subsequently interact with, cross link, and alter the soluble proteins.     

DNA sequence recognition by the antitumor antibiotic CC-1065 and analogs of CC-1065

The DNA base pair preferences of the antitumor antibiotic CC-1065 and two analogs of CC-1065 were studied by following the rate of covalent bond formation (N-3 adenine adduct) with DNA oligomers containing the 5'NNTTA* and 5'NNAAA* sequences (N = nucleotide, A* = alkylated adenine). The rate of adduct formation of CC-1065 is greatly affected by DNA base changes at the fourth and fifth positions of the bonding site for the 5'NNAAA sequences, but not the 5'NNTTA sequences. However, an analog of CC-1065 containing the same alkylating moiety as CC-1065, but not the third fused ring system or additional methylene and oxygen substituents, shows similar rates of adduct formation for all sequences. A second analog of CC-1065 containing three fused ring systems, but not the methylene and oxygen substituents of CC-1065, shows rates of adduct formation with the same sequence dependence as CC-1065, but does not distinguish between the sequences to the degree shown by CC-1065. Adduct formation of CC-1065, but not the analogs, competes with a reversibly bound species. Thymine bases to the 3' side of a potentially reactive adenine or a cytosine base at the fifth position from the bonding adenine create reversible binding sites which decrease the rate of adduct formation of CC-1065. The sequence 5'GCGAATT binds CC-1065 only reversibly. This sequence can compete for CC-1065 with covalent bonding sequences if the sites are located in different oligomers, or if the sites are located (overlapped or not overlapped) in the same oligomer. The results of these competitive binding experiments suggest that the transfer of CC-1065 from the reversible binding site to the covalent bonding site with both sites located on a single DNA duplex, not overlapped, occurs through an equilibrium of CC-1065 in solution, not by migration of CC-1065 in the minor groove.     

N-2 acetylation of 2'-deoxyguanosine by coffee mutagens, methylglyoxal and hydrogen peroxide

Coffee shows direct-acting mutagenicity in Salmonella typhimurium TA100 and most of this mutagenicity is due to the synergistic effects of methylglyoxal and hydrogen peroxide. The modifications of deoxyribonucleosides by methylglyoxal plus hydrogen peroxide were studied in vitro. When 2'-deoxyguanosine (6.25 mumole) was treated with methylglyoxal (125 mumole) and hydrogen peroxide (125 mumole) in 5 ml of 0.1 M phosphate buffer (pH 7.4) at 37 degrees C for 3 h, N2-acetyl-2'-deoxyguanosine was formed with a yield of 1.1%. Its formation increased time-dependently. By contrast, no appreciable modification of other deoxynucleosides was detected after their incubation with methylglyoxal and hydrogen peroxide under similar conditions. N2-Acetyl-2'-deoxyguanosine was also formed during incubation of 2'-deoxyguanosine with instant coffee.     

Formation of aminoxyl radicals in the reaction between penicillins and hydrogen peroxide.

Aminoxyl radicals are formed in high yield in the reaction between penicillins and hydrogen peroxide in water solutions in the pH range between 7 and 8. The nine-line EPR spectrum, 3 x 3 (1:2:1), indicated an interaction of the unpaired electron with one 14N nucleus (aN = 1.44 mT) and two equivalent hydrogen nuclei (aH = 2.00 mT). The reaction involves an oxidative cleavage of the beta-lactam ring of the penicillins with the formation of a cyclic aminoxyl radical, in which the thiazolidine ring carries the nitroxide group (= N-O.). It is suggested that the reaction with the formation of aminoxyl radicals can also take place in vivo in the deactivation of penicillins by metabolically formed hydrogen peroxide.     

Enhanced nucleophilicity and depressed electrophilicity of peroxide by zinc(II), aluminum(III) and lanthanum(III) ions

The binuclear zinc(II) complex, [Zn2(HPTP)(CH3COO)]2+ was found highly active to cleave DNA (double-strand super-coiled DNA, pBR322 and phix174) in the presence of hydrogen peroxide. However, no TBARS (2-thiobarbituric acid reactive substance) formation was detected in a solution containing 2-deoxyribose (or 2'-deoxyguanosine, etc); where (HPTP) represents N,N,N'-N'-tetrakis(2-pyridylmethyl)-1,3-diamino-2-propanol. These facts imply that DNA cleavage reaction by the binuclear Zn(II)/H2O2 system should be due to a hydrolytic mechanism, which may be attributed to the enhanced nucleophilicity but depressed electrophilicity of the peroxide ion coordinated to the zinc(II) ion. DFT (density-functional theory) calculations on the peroxide adduct of monomeric zinc(II) have supported the above consideration. Similar DFT calculations on the peroxide adducts of the Al(III) and La(III) compounds have revealed that electrophilicity of the peroxide ion in these compounds is strongly reduced. This gives an important information to elucidate the fact that La3+ can enhance the growth of plants under certain conditions.     

Reaction of 2-thio-FAD-reconstituted p-hydroxybenzoate hydroxylase with hydrogen peroxide. Formation of a covalent flavin-protein linkage

Hydrogen peroxide reacts with 2-thio-FAD-reconstituted p-hydroxybenzoate hydroxylase to yield a long wavelength intermediate (lambda max = 360, 620 nm) which can be isolated in stable form on removal of excess H2O2. The blue flavin derivative slowly decays in a second peroxide-dependent reaction to yield a new flavin product lacking long wavelength absorbance (lambda max = 408, 472 nm). This final peroxide-modified enzyme binds p-hydroxybenzoate with a 10-fold lower affinity than does the native enzyme; furthermore, substrate binding leads to the inhibition of enzyme reduction by NADPH. Trichloroacetic acid treatment of the final peroxide-modified enzyme results in the quantitative conversion of the bound flavin to free FAD. However, gel filtration of the modified enzyme in guanidine hydrochloride at neutral pH leads to the co-elution of protein and modified flavin. The nondenatured peroxide product reacts rapidly with hydroxylamine to yield 2-NHOH-substituted FAD. These observations indicate that the secondary reaction of peroxide with the blue intermediate from 2-thio-FAD p-hydroxybenzoate hydroxylase results in the formation of an acid-labile covalent flavin-protein linkage within the enzyme active site, involving the flavin C-2 position.     

Covalent fusion inhibitors targeting HIV-1 gp41 deep pocket

Covalent inhibitors form covalent adducts with their target, thus permanently inhibiting a physiological process. Peptide fusion inhibitors, such as T20 (Fuzeon, enfuvirtide) and C34, interact with the N-terminal heptad repeat of human immunodeficiency virus type 1 (HIV-1) gp41 glycoprotein to form an inactive hetero six-helix bundle (6-HB) to prevent HIV-1 infection of host cells. A covalent strategy was applied to peptide fusion inhibitor design by introducing a thioester group into C34-like peptide. The modified peptide maintains the specific interaction with its target N36. After the 6-HB formation, a covalent bond between C- and N-peptides was formed by an inter-helical acyl transfer reaction, as characterized by various biophysical and biochemical methods. The covalent reaction between the reactive C-peptide fusion inhibitor and its N-peptide target is highly selective, and the reaction greatly increases the thermostability of the 6-HB. The modified peptide maintains high potency against HIV-1-mediated cell–cell fusion and infection.