Reexamination of the mechanisms of oxidative transformation of the insect cuticular sclerotizing precursor, 1,2-dehydro-N-acetyldopamine

1,2-dehydro-N-acetyldopamine (dehydro NADA) is an important catecholamine derivative formed during the sclerotization of insect cuticle. Earlier we have reported that tyrosinase-catalyzed oxidation of dehydro NADA produces a reactive quinone methide imine amide that forms adducts and cross-links through its side chain, thereby accounting for sclerotization reactions. Recently, laccase has also been identified as a key enzyme associated with sclerotization. Hence, we re-examined oxidation of dehydro NADA by tyrosinase and laccase using high performance liquid chromatography – tandem mass spectrometry. Tyrosinase-catalyzed oxidation of dehydro NADA not only generated dimers as reported earlier, but also generated significant amounts of oligomers. The course of laccase-catalyzed oxidation of dehydro NADA significantly differed from the tyrosinase reaction kinetically and mechanistically. Laccase failed to produce any detectable quinone or quinone methide as the primary two-electron oxidation product. Since laccases are known to generate primarily semiquinones as the initial products, lack of accumulation of two-electron oxidation products indicated that laccase reaction is primarily occurring via free radical coupling mechanism. Consistent with this proposal, laccase-catalyzed oxidation of dehydro NADA, resulted in the production of largely dimeric products and failed to produce any significant amount of oligomeric materials. These studies call for radical coupling as yet another major mechanism for sclerotization of insect cuticle.     

Oxidation chemistry of 1,2-dehydro-N-acetyldopamines: direct evidence for the formation of 1,2-dehydro-N-acetyldopamine quinone

Two-electron oxidation of catecholamines either by phenol oxidase or by chemical oxidants such as sodium periodate produces their corresponding o-quinones as observable products. But, in the case of 1,2-dehydro-N-acetyldopamine, an important insect cuticular sclerotizing precursor, phenol oxidase catalyzed oxidation has been reported to generate a quinone methide analog as a transient, but first observable product. ?Sugumaran, M., Semensi, V., Kalyanaraman, B., Bruce, J. M., and Land, E. J. (1992) J. Biol. Chem. 267, 10355-10361. The corresponding quinone has escaped detection until now. However, in this paper, for the first time, we present direct evidence for the formation of dehydro-N-acetyldopamine quinone and show that it can readily be produced from the tautomeric quinone methide imine amide during the chemical oxidation of dehydro-N-acetyldopamine under acidic conditions. This situation is in sharp contrast to other known alkyl-substituted catechol oxidations, where quinone is the first observable product and quinone methide is the subsequently generated product. Dehydro-N-acetyldopamine quinone thus formed is also highly unstable. Semiempirical molecular orbital calculation also indicates that quinone methide imine amide is more stable than the quinone. Chemical considerations indicate that the quinone methide tautomer, and not the dehydro-N-acetyldopamine quinone, is responsible for crosslinking the structural proteins and chitin polymer in the insect cuticle. Therefore, the quinone methide tautomer, and not the quinone, is the key reactive intermediate aiding the hardening of insect cuticle.     

Mechanism of activation of 1,2-dehydro-N-acetyldopamine for cuticular sclerotization

The mechanism of oxidation of 1,2-dehydro-N-acetyldopamine (dehydro NADA) was examined to resolve the controversy between our group and Andersen's group regarding the reactive species involved in β-sclerotization. While Andersen has indicated that dehydro NADA quinone is the β-sclerotizing agent [Andersen, 1989], we have proposed quinone methides as the reactive species for this process [Sugumaran, 1987; Sugumaran, 1988]. Since dehydro NADA quinone has not been isolated or identified till to date, we studied the enzymatic oxidation of dehydro NADA in the presence of quinone traps to characterize this intermediate. Accordingly, both N-acetylcysteine and o-phenylenediamine readily trapped the transiently formed dehydro NADA quinone as quinone adducts. Interestingly, when the enzymatic oxidation was performed in the presence of o-aminophenol or different catechols, adduct formation between the dehydro NADA side chain and the additives had occurred. The structure of the adducts is in conformity with the generation and reactions of dehydro NADA quinone methide (or its radical). This, coupled with the fact that 4-hydroxyl or amino-substituted quinones instantly transformed into p-quinonoid structure, indicates that dehydro NADA quinone is only a transient intermediate and that it is the dehydro NADA quinone methide that is the thermodynamically stable product. However, since this compound is chemically more reactive due to the presence of both quinone methide and acylimine structure on it, the two side chain carbon atoms are “activated.” Based on these considerations, it is suggested that the quinone methide derived from dehydro NADA is the reactive species responsible for cross-link formation between dehydro NADA and cuticular components during β-sclerotization.     

On the mechanism of formation of N-acetyldopamine quinone methide in insect cuticle

The mechanism of formation of quinone methide from the sclerotizing precursor N-acetyldopamine (NADA) was studied using three different cuticular enzyme systems viz. Sarcophaga bullata larval cuticle, Manduca sexta pharate pupae, and Periplaneta americana presclerotized adult cuticle. All three cuticular samples readily oxidized NADA. During the enzyme-catalyzed oxidation, the majority of NADA oxidized became bound covalently to the cuticle through the side chain with the retention of o-diphenolic function, while a minor amount was recovered as N-acetylnorepinephrine (NANE). Cuticle treated with NADA readily released 2-hydroxy-3′,4′-dihydroxyacetophenone on mild acid hydrolysis confirming the operation of quinone methide sclerotization. Attempts to demonstrate the direct formation of NADA-quinone methide by trapping experiments with N-acetylcysteine surprisingly yielded NADA-quinone-N-acetylcysteine adduct rather than the expected NADA-quinone methide-N-acetylcysteine adduct. These results are indicative of NADA oxidation to NADA-quinone and its subsequent isomerization to NADA-quinone methide. Accordingly, all three cuticular samples exhibited the presence of an isomerase, which catalyzed the conversion of NADA-quinone to NADA-quinone methide as evidenced by the formation of NANE—the water adduct of quinone methide. Thus, in association with phenoloxidase, newly discovered quinone methide isomerase seems to generate quinone methides and provide them for quinone methide sclerotization.     

N-acetyldopamine quinone methide/1,2-dehydro-N-acetyl dopamine tautomerase. A new enzyme involved in sclerotization of insect cuticle

The enzyme system causing the side chain desaturation of the sclerotizing precursor, N-acetyldopamine (NADA), was solubilized from the larval cuticle of Sarcophaga bullata and resolved into three components. The first enzyme, phenoloxidase, catalyzed conversion of NADA to NADA quinone and provided it for the second enzyme (NADA quinone isomerase), which makes the highly unstable NADA quinone methide. Quinone methide was hydrated rapidly and nonenzymatically to form N-acetylnorepinephrine. In addition, it also served as the substrate for the last enzyme, quinone methide tautomerase, which converted it to 1,2-dehydro-NADA. Reconstitution of NADA side chain desaturase activity was achieved by mixing the last enzyme fraction with NADA quinone isomerase, obtained from the hemolymph of the same organism, and mushroom tyrosinase. Therefore, NADA side chain desaturation observed in insects is caused by the combined action of three enzymes rather than the action of a single specific NADA desaturase, as previously thought.     

Oxidation of 3,4-dihydroxybenzyl alcohol: a sclerotizing precursor for cockroach ootheca.

The oxidation of 3,4-dihydroxybenzyl alcohol, one of the sclerotizing precursors for the tanning of the ootheca of cockroach Periplaneta americana, is reported for the first time. Mushroom tyrosinase catalyzed oxidation of 3,4-dihydroxybenzyl alcohol generated the corresponding quinone which was found to be unstable and readily transformed to produce 3,4-dihydroxybenzaldehyde as the stable product probably through the intermediary formation of a quinone methide. Phenoloxidase isolated from the left collateral gland of P. americana also catalyzed this new reaction. When the enzymatic oxidation of 3,4-dihydroxybenzyl alcohol was performed in the presence of a test protein such as lysozyme, the reactive species formed, caused the oligomerization of test protein. Similar studies with collateral gland proteins, failed to generate oligomers, but produced insoluble polymeric proteins. The probable fate of 3,4-dihydroxybenzyl alcohol for the tanning of cockroach ootheca is discussed.     

Enhancement of the peroxidase-mediated oxidation of butylated hydroxytoluene to a quinone methide by phenolic and amine compounds

We have recently demonstrated that butylated hydroxyanisole (BHA) markedly stimulates the peroxidase-dependent oxidation of butylated hydroxytoluene (BHT) to the potentially toxic BHT-quinone methide. Using both horseradish peroxidase and prostaglandin H synthase we now report the ability of a wide variety of compounds to stimulate peroxidase-dependent activation of BHT. These compounds include several phenolic compounds commonly present in pharmacologic preparations or occurring naturally in foods. The ability of a given compound to stimulate BHT oxidation was found to depend on the type of radical it forms upon peroxidase oxidation. Compounds which have been shown to form phenoxy radicals or nitrogen-centered cation radicals were observed to enhance BHT oxidation. Conversely, compounds which are known to form peroxy radicals or semiquinone radicals either inhibited or had no effect on BHT oxidation. Compounds which enhanced BHT oxidation (monitored by covalent binding of [14C]BHT to protein) were also observed to stimulate the formation of BHT-quinone methide and stilbenequinone. This suggested a common mechanism of interaction of these compounds with BHT. The stimulation of BHT covalent binding by BHA was also seen in various human and animal tissues using either arachidonic acid or hydrogen peroxide as substrate. The possible toxicologic implications of the enhancement of peroxidase-catalyzed BHT oxidation to BHT-quinone methide are discussed.     

Sequence-specific delivery of a quinone methide intermediate to the major groove of DNA.

Silyl-protected phenol derivatives serve as convenient precursors for generating highly electrophilic quinone methide intermediates under biological conditions. Reaction is initiated by addition of fluoride and has previously exhibited proficiency in DNA alkylation and cross-linking. This approach has now been extended to the modification of duplex DNA through triplex recognition and fluoride-dependent quinone methide induction. Both oligonucleotides of a model duplex were alkylated in a sequence specific manner by an oligonucleotide conjugate that is consistent with triplex association. Optimum reaction required the presence of the two complementary target sequences and a pH of below 6.5. In addition, one guanine in each strand adjacent to the triplex region was the predominant site of alkylation. The yield of modification varied from approximately 20% for the purine-rich strand to only 4% for the pyrimidine-rich strand. This surprising difference indicates that the linker between the recognition and reactive elements may limit productive interaction between the quinone methide and the reactive nucleophiles of DNA. Restricted orientation of this intermediate may also be responsible for the lack of target cross-linking at detectable levels.     

Evidence for phosgene formation during liver microsomal oxidation of chloroform

When aerobically incubated with liver microsomes and NADPH, chloroform produces a stable adduct with cysteineas a nucleophilic trapping agent. The adduct was identified by thin layer chromatography, gas-liquid chromatography and combined gas chromatography-mass spectrometry as the reaction product of cysteine with phosgene.     

On the mechanism of formation of arterenone in insect cuticular hydrolyzates

Arterenone (2-amino-3′,4′-dihydroxy acetophenone) is an important hydrolytic product generated from lightly colored sclerotized cuticle that use N-acyldopamine derivatives for crosslinking reactions. It seems to arise from 1,2-dehydro-N-acetyldopamine (dehydro NADA) that has been crosslinked to the cuticular components. However, the mechanism of generation of arterenone, which has two protons on the α-carbon and no proton on the β-carbon atom from dehydro NADA crosslinks that have one proton each on these two side chain carbons, remained elusive and undetermined. To investigate the mechanism of this transformation, we synthesized specifically labeled β-deuterated dehydro NADA and incubated with Sarcophaga bullata cuticle undergoing larval puparial transformation. We also isolated the dimeric products formed during the tyrosinase-mediated oxidation of dehydro NADA. Hydrolysis of both β-deuterated dehydro NADA treated cuticle and β-deuterated dehydro NADA dimer generated arterenone as the major hydrolytic product. Liquid chromatography-mass spectrometric analysis of this arterenone revealed the retention of deuterium from the β-position of dehydro NADA at the α-carbon atom of arterenone. Hydrolysis of β-deuterated dehydro NADA also generated the labeled arterenone under oxidative conditions, but not under anaerobic conditions. These results indicate the unique hydride shift from β-carbon to α-carbon during acid hydrolysis and reveal the mechanism of liberation of arterenone and related compounds from dehydro NADA linked cuticle.     

Evidence for the formation of a steroid S-glutathione conjugate from an epoxysteroid precursor.

Biotransformation of [4-¹⁴C]cholesterol α-epoxide (5α,6α-epoxycholestan-3β-ol) to the S-glutathione conjugate, 3β,5α-dihydroxycholestan-6β-yl-S-glutathione, by S-glutathione transferase of the rat liver soluble supernatant fraction, has been described. After the isolation from the biological incubation mixture by n-butanol extraction, followed by the Amberlite XAD-2 column treatment, the conjugate was chromatographically identified with a synthetic specimen which was prepared from cholesterol α-epoxide and glutathione in an ethanolic solution of sodium hydroxide. Further identification of the biologically formed conjugate with the synthetic one, including structural assignment, was established from the result that they yielded the same desulfrization product, 3β,5α-dihydroxycholestane, by the treatment with Raney nickel in an atmosphere of hydrogen.     

Biosynthesis of dehydro-N-acetyldopamine by a soluble enzyme preparation from the larval cuticle of Sarcophaga bullata involves intermediary formation of N-acetyldopamine quinone and N-acetyldopamine quinone methide

The enzymes involved in the side chain hydroxylation and side chain desaturation of the sclerotizing precursor N-acetyldopamine (NADA) were obtained in the soluble form from the larval cuticle of Sarcophaga bullata and the mechanism of the reaction was investigated. Phenylthiourea, a well-known inhibitor of phenoloxidases, drastically inhibited both the reactions, indicating the requirement of a phenoloxidase component. N-acetylcysteine, a powerful quinone trap, trapped the transiently formed NADA quinone and prevented the production of both N-acetylnorepinephrine and dehydro NADA. Exogenously added NADA quinone was readily converted by these enzyme preparations to N-acetylnorepinephrine and dehydro NADA. 4-Alkyl-o-quinone:2-hydroxy-p-quinone methide isomerase obtained from the cuticular preparations converted chemically synthesized NADA quinone to its quinone methide. The quinone methide formed reacted rapidly and nonenzymatically with water to form N-acetylnorepinephrine as the stable product. Similarly 4-(2-hydroxyethyl)-o-benzoquinone was converted to 3,4-dihydroxyphenyl glycol. When the NADA quinone-quinone isomerase reaction was performed in buffer containing 10% methanol, beta-methoxy NADA was obtained as an additional product. Furthermore, the quinones of N-acetylnorepinephrine and 3,4-dihydroxyphenyl glycol were converted to N-acetylarterenone and 2-hydroxy-3',4'-dihydroxyacetophenone, respectively, by the enzyme. Comparison of nonenzymatic versus enzymatic transformation of NADA to N-acetylnorepinephrine revealed that the enzymatic reaction is at least 100 times faster than the nonenzymatic rate. Resolution of the NADA desaturase system on Benzamidine Sepharose and Sephacryl S-200 columns yielded the above-mentioned quinone isomerase and NADA quinone methide:dehydro NADA isomerase. The latter, on reconstitution with mushroom tyrosinase and hemolymph quinone isomerase, catalyzed the biosynthesis of dehydro NADA from NADA with the intermediary formation of NADA quinone and NADA quinone methide. The results are interpreted in terms of the quinone methide model elaborated by our group [Sugumaran: Adv. Insect Physiol. 21:179-231, 1988; Sugumaran et al.: Arch. Insect Biochem. Physiol. 11:109, 1989] and it is concluded that the two enzyme beta-sclerotization model [Andersen: Insect Biochem. 19:59-67, 375-382, 1989] is inadequate to account for various observations made on insect cuticle.     

Conjugation of a hairpin pyrrole-imidazole polyamide to a quinone methide for control of DNA cross-linking

A series of quinone methide precursors designed for DNA cross-linking were prepared and conjugated to a pyrrole-imidazole polyamide for selective association to the minor groove. Although reaction was only observed for DNA containing the predicted recognition sequence, yields of strand alkylation were low. Interstrand cross-linking was more efficient than alkylation but still quite modest and equivalent to that generated by a comparable conjugate containing the N-mustard chlorambucil. Varying the length of the linker connecting the polyamide and quinone methide derivative did not greatly affect the yield of DNA cross-linking. Instead, intramolecular trapping of the quinone methide intermediate by nucleophiles of the attached polyamide appears to be the major determinant that limits its reaction with DNA. Self-adducts of the quinone methide conjugate form readily and irreversibly as detected by a combination of chromatography and mass spectroscopy. This result is unlike comparable self-adducts observed for oligonucleotide conjugates that form more slowly and remain reversible. Equivalent intramolecular alkylation of a polyamide by its attached chlorambucil mustard was not observed under similar condition. The presence of DNA, however, did facilitate hydrolysis of this mustard conjugate.     

Formation of DNA adducts by microsomal and peroxidase activation of p-cresol: role of quinone methide in DNA adduct formation.

We have investigated the activation of p-cresol to form DNA adducts using horseradish peroxidase, rat liver microsomes and MnO(2). In vitro activation of p-cresol with horseradish peroxidase produced six DNA adducts with a relative adduct level of 8.03+/-0.43 x 10(-7). The formation of DNA adducts by oxidation of p-cresol with horseradish peroxidase was inhibited 65 and 95% by the addition of either 250 or 500 microM ascorbic acid to the incubation. Activation of p-cresol with phenobarbital-induced rat liver microsomes with NADPH as the cofactor; resulted in the formation of a single DNA adduct with a relative adduct level of 0.28+/-0.08 x 10(-7). Similar incubations of p-cresol with microsomes and cumene hydroperoxide yielded three DNA adducts with a relative adduct level of 0.35+/-0.03 x 10(-7). p-Cresol was oxidized with MnO(2) to a quinone methide. Reaction of p-cresol (QM) with DNA produced five major adducts and a relative adduct level of 20.38+/-1.16 x 10(-7). DNA adducts 1,2 and 3 formed by activation of p-cresol with either horseradish peroxidase or microsomes, are the same as that produced by p-cresol (QM). This observation suggests that p-cresol is activated to a quinone methide intermediate by these activation systems. Incubation of deoxyguanosine-3'-phosphate with p-cresol (QM) resulted in a adduct pattern similar to that observed with DNA; suggesting that guanine is the principal site for modification. Taken together these results demonstrate that oxidation of p-cresol to the quinone methide intermediate results in the formation of DNA adducts. We propose that the DNA adducts formed by p-cresol may be used as molecular biomarkers of occupational exposure to toluene.     

Molecular mechanisms for mammalian melanogenesis. Comparison with insect cuticular sclerotization.

Melanogenesis is an important biochemical process for the production of skin pigments which protect many animals from the damage of solar radiation. The abnormalities in melanogenesis are associated with albinism, vitiligo, as well as malignant melanoma in humans. In the lower forms of animals viz., insects, the exoskeleton is hardened to protect their soft bodies by a process called sclerotization, which is often accompanied by melanization. Recent advances in the biochemistry of sclerotization and melanization reveal remarkable similarity between these two processes. The seven stages of sclerotization are: (a) enzymatic oxidation of N-acyldopamine, (b) Michael-1,4-addition reactions of N-acyldopamine quinone, (c) tautomerization of quinone to quinone methide, (d) Michael-1,6-addition of quinone methides, (e) tautomerization of N-acyldopamine quinone methide to 1,2-dehydro-N-acyldopamine, (f) enzymatic oxidation of 1,2-dehydro-N-acyldopamine, and (g) the reactions of resultant quinonoid compounds. Amazingly, striking similarities in the reaction sequences are found in the melanization process starting from dopa. These comparisons predict a central role for quinone methides as reactive intermediates during melanization. Accordingly, recent studies provide increasing evidence in favor of this proposition.     

Synthesis and cytotoxicity of desmethoxycallipeltin B: lack of a quinone methide for the cytotoxicity of callipeltin B

The desmethoxy analogue of the cytotoxic, cyclic depsipeptide callipeltin B was synthesized to evaluate the role of its beta-MeOTyr residue. The IC(50) of desmethoxycallipeltin B, in which the beta-MeOTyr residue was replaced by d-Tyr, against HeLa cells was found to be 128+/-10 microM in an MTT assay, compared to 98+/-5 microM for the natural product itself. The roughly comparable cytotoxicities suggest that the cytotoxicity of callipeltin B does not arise through the formation of a quinone methide intermediate.     

Glyceraldehyde-3-phosphate dehydrogenase as a quinone reductase in the suppression of 1,2-naphthoquinone protein adduct formation

1,2-Naphthoquinone (1,2-NQ) is electrophilic, and forms covalent bonds with protein thiols, but its two-electron reduction product 1,2-dihydroxynaphthalene (1,2-NQH(2)) is not, so enzymes catalyzing the reduction with reduced pyridine nucleotides as cofactors could protect cells from electrophile-based chemical insults. To assess this possibility, we examined proteins isolated from the 9000g supernatant from mouse liver for 1,2-NQ reductase activity using an HPLC assay procedure for the hydroquinone of 1,2-NQ and Cibacron Blue 3GA column chromatography and Western blot analysis with specific antibody to determine 1,2-NQ-bound proteins. Among the proteins with high affinities for pyridine nucleotides that also inhibited 1,2-NQ-protein adduct formation in the presence of NADH, a 37-kDa protein was found and identified as glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Using recombinant human GAPDH, we found that this glycolytic enzyme indeed catalyzes the two-electron reduction of 1,2-NQ accompanied by extensive NADH consumption under 20% oxygen conditions. When either 1,2-NQH(2) or 1,2-NQ was incubated with GAPDH in the presence of NADH, minimal covalent bonding to the enzyme occurred compared to that in its absence. These results indicate that GAPDH can inhibit 1,2-NQ-based electrophilic protein modification by conversion to the nonelectrophilic 1,2-NQH(2) via an NADH-dependent process.     

o-quinone/quinone methide isomerase: a novel enzyme preventing the destruction of self-matter by phenoloxidase-generated quinones during immune response in insects

Melanization and encapsulation of invading foreign organisms observed during the immune response in insects is known to be due to the action of activated phenoloxidase. Phenoloxidase-generated quinones are deposited either directly or after self-polymerization on foreign objects accounting for the observed reactions. Since the reactions of quinones are nonenzymatic, they do not discriminate self from nonself and hence will also destroy self-matter. In this report we present evidence for the presence of a novel quinone/quinone methide isomerase in the hemolymph of Sarcophaga bullata which destroys long-lived quinones and hence acts to protect the self-matter. Quinone methides, formed by the action of this enzyme on physiologically important quinones, being unstable undergo rapid hydration to form nontoxic metabolites.