On the mechanism of side chain oxidation of N-beta-alanyldopamine by cuticular enzymes from Sarcophaga bullata

The metabolism of N-beta-alanyldopamine (NBAD) by Sarcophaga bullata was investigated. Incubation of NBAD with larval cuticular preparations resulted in the covalent bindings of NBAD to the cuticle and generation of N-beta-alanyl-norepinephrine (NBANE) as the soluble product. When the reaction was carried out in presence of a powerful quinone trap viz., N-acetylcysteine, NBANE formation was totally abolished; but a new compound characterized as NBAD-quinone-N-acetylcysteine adduct was generated. These results indicate that NBAD quinone is an obligatory intermediate for the biosynthesis of NBANE in sarcophagid cuticle. Accordingly, phenylthiourea--a well-known phenoloxidase inhibitor--completely inhibited the NBANE production even at 5 microM level. A soluble enzyme isolated from cuticle converted exogenously supplied NBAD quinone to NBANE. Chemical considerations indicated that the enzyme is an isomerase and is converting NBAD quinone to its quinone methide which was rapidly and nonenzymatically hydrated to form NBANE. Consistent with this hypothesis is the finding that NBAD quinone methide can be trapped as beta-methoxy NBAD by performing the enzymatic reaction in 10% methanol. Moreover, when the reaction was carried out in presence of kynurenine, two diastereoisomeric structures of papiliochrome II-(Nar-[alpha-3-aminopropionyl amino methyl-3,4-dihydroxybenzyl]-L-kynurenine) could be isolated as by-products, indicating that the further reactions of NBAD quinone methide with exogenously added nucleophiles are nonenzymatic and nonstereoselective. Based on these results, it is concluded that NBAD is metabolized via NBAD quinone and NBAD quinone methide by the action of phenoloxidase and quinone isomerase respectively. The resultant NBAD quinone methide, being highly reactive, undergoes nonenzymatic and nonstereoselective Michael-1,6-addition reaction with either water (to form NBANE) or other nucleophiles in cuticle to account for the proposed quinone methide 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.     

Further studies on the mechanism of oxidation of N-acetyldopamine by the cuticular enzymes from Sarcophaga bullata and other insects

In accordance with our earlier results, quinone methide formation was confirmed to be the major pathway for the oxidation of N-acetyldopamine (NADA) by cuticle-bound enzymes from Sarcophaga bullata larvae. In addition, with the use of a newly developed HPLC separation condition and cuticle prepared by gentle procedures, it could be demonstrated that 1, 2-dehydro-NADA and its dimeric oxidation products are also generated in the reaction mixture containing a high concentration of NADA albeit at a much lower amount than the NADA quinone methide water adduct, viz., N-acetylnorepinephrine (NANE). By using different buffers, it was also possible to establish the accumulation of NADA quinone in reaction mixtures containing NADA and cuticle. That the 1,2-dehydro-NADA formation is due to the action of a NADA desaturase system was established by pH and temperature studies and by differential inhibition of NANE production. Of the various cuticle examined, adult cuticle of Locusta migratoria, presclerotized cuticle of Periplaneta americana, and white puparial cases of Drosophila melanogaster exhibited more NADA desaturase activity than NANE generating activity, while the reverse was observed with the larval cuticle of Tenebrio molitor and pharate pupal cuticle of Manduca sexta. These studies indicate that both NADA quinone methide and 1, 2-dehydro NADA are formed during enzymatic activation of NADA in insect cuticle. Based on these results, a unified mechanism for β-sclerotization involving quinone methides as the reactive species is presented.     

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.     

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 oxidation of 3,4-dihydroxyphenethyl alcohol and 3,4-dihydroxyphenyl glycol by cuticular enzyme(s) from Sarcophaga bullata

The catabolic fate of 3,4-dihydroxyphenethyl alcohol (DHPA) and 3,4-dihydroxyphenylethyl glycol (DHPG) in insect cuticle was determined for the first time using cuticular enzyme(s) from Sarcophaga bullata and compared with mushroom tyrosinase-medicated oxidation. Mushroom tyrosinase converted both DHPA and DHPG to their corresponding quinone derivatives, while cuticular enzyme(s) partly converted DHPA to DHPG. Cuticular enzyme(s)-mediated oxidation of DHPA also accompanied the covalent binding of DHPA to the cuticle. Cuticle-DHPA adducts, upon pronase digestion, released peptides that had bound catechols. 3,4-Dihydroxyphenyl-acetaldehyde, the expected product of side chain desaturation of DHPA, was not formed at all. The presence of N-acetylcysteine, a quinone trap, in the reaction mixture containing DHPA and cuticle resulted in the generation of DHPA-quinone-N-acetylcysteine adduct and total inhibition of DHPG formation. The insect enzyme(s) converted DHPG to its quinone at high substrate concentration and to 2-hydroxy-3′,4′-dihydroxyacetophenone at low concentration. They converted exogenously added DHPA-quinone to DHPG, but acted sluggishly on DHPG-quinone. These results are consistent with the enzymatic transformations of phenoloxidase-generated quinones to quinone methides and subsequent nonenzymatic transformation of the latter to the observed products. Thus, quinone methide formation in insect cuticle seems to be caused by the combined action of two enzymes, phenoloxidase and quinone tautomerase, rather than the action of quinone methide-generating phenoloxidase (Sugumaran: Arch Insect Biochem Physiol 8, 73–88, 1988). It is proposed that DHPA and DHPG in combination can be used effectively to examine the participation of (1) quinone, (2) quinone methide, and (3) dehydro derivative intermediates in the metabolism of 4-alkylcatechols for cuticular 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.     

Characterization of a new enzyme system that desaturates the side chain of N-acetyldopamine

A novel enzyme system that desaturates the side chain of the catecholamine derivative, N-acetyldopamine (NADA), was isolated and characterized from the larval cuticle of Sarcophaga bullata. The NADA desaturase system which converts NADA to 1,2-dehydro-NADA, surprisingly, does not resemble dehydrogenases such as succinate dehydrogenase. It uniquely performs the desaturation reaction by oxidizing NADA to its corresponding quinone and subsequently converting the resultant quinone to 1,2-dehydro-NADA via NADA quinone methide. Accordingly, desaturase enzyme preparation contained both o-diphenoloxidase activity and NADA quinone:NADA quinone methide isomerase activity. In addition, inhibition studies as well as trapping experiments also confirmed the obligatory formation of NADA quinone as the transient intermediate of the NADA desaturation. It is the first report of a cell-free system causing the side chain desaturation of any catecholamine derivative.     

Differential mechanism of oxidation of N-acetyldopamine and N-acetylnorepinephrine by cuticular phenoloxidase from Sarcophaga bullata

The mechanism of oxidation of two related sclerotizing precursors—N-acetyldopamine and N-acetylnorepinephrine—by the cuticular phenoloxidase from Sarcophaga bullata was studied and compared with mushroom tyrosinase-mediated oxidation. While the fungal enzyme readily generated the quinone products from both of these catecholamine derivatives, sarcophagid enzyme converted N-acetyldopamine to a quinone methide derivative, which was subsequently bound to the cuticle with the regeneration of o-dihydroxy phenolic function as outlined in an earlier publication [Sugumaran: Arch Insect Biochem Physiol, 8, 73 (1988)]. However, it converted N-acetylnorepinephrine to its quinone and not to the quinone methide derivative. Proteolytic digests of N-acetyldopamine-treated cuticle liberated peptides that had covalently bound catechols, while N-acetylnorepinephrine-treated cuticle did not release such peptides. Acid hydrolysis of N-acetyldopamine-treated cuticle, but not N-acetylnorepinephrine-treated cuticle liberated 2-hydroxy-3′,4′-dihydroxyacetophenone and arterenone. These results further confirm the unique conversion of N-acetyldopamine to its corresponding quinone methide derivative and N-acetylnorepinephrine to its quinone derivative by the cuticular phen-oloxidase. Significance of this differential mechanism of oxidation for sclerotization of insect cuticle is discussed.     

Studies on the enzymes involved in puparial cuticle sclerotization in Drosophila melanogaster.

The properties of cuticular enzymes involved in sclerotization of Drosophila melanogaster puparium were examined. The cuticle-bound phenoloxidase from the white puparium exhibited a pH optimum of 6.5 in phosphate buffer and oxidized a variety of catecholic substrates such as 4-methylcatechol, N-beta-alanyldopamine, dopa, dopamine, N-acetyldopamine, catechol, norepinephrine, 3,4-dihydroxyphenylglycol, 3,4-dihydroxybenzoic acid, and 3,4-dihydroxyphenylacetic acid. Phenoloxidase inhibitors such as potassium cyanide and sodium fluoride inhibited the enzyme activity drastically, but phenylthiourea showed marginal inhibition only. This result, coupled with the fact that syringaldazine served as the substrate for the insoluble enzyme, confirmed that cuticular phenoloxidase is of the "laccase" type. In addition, we also examined the mode of synthesis of the sclerotizing precursor, 1,2-dehydro-N-acetyldopamine. Our results indicate that this catecholamine derivative is biosynthesized from N-acetyldopamine through the intermediate formation of N-acetyldopamine quinone and N-acetyldopamine quinone methide as established for Sarcophaga bullata [Saul, S. and Sugumaran, M., F.E.B.S. Letters 251, 69-73 (1989)]. Accordingly, successful solubilization and fractionation of cuticular enzymes involved in the introduction of a double bond in the side chain of N-acetyldopamine indicated that they included o-diphenoloxidase, 4-alkyl-o-quinone:p-quinone methide isomerase, and N-acetyldopamine quinone methide:dehydro N-acetyldopamine isomerase and not any side chain desaturase.     

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.     

Model reactions for insect cuticle sclerotization: cross-linking of recombinant cuticular proteins upon their laccase-catalyzed oxidative conjugation with catechols

The quinone-tanning hypothesis for insect cuticle sclerotization proposes that N-acylcatecholamines are oxidized by a phenoloxidase to quinones and quinone methides, which serve as electrophilic cross-linking agents to form covalent cross-links between cuticular proteins. We investigated model reactions for protein cross-linking that occurs during insect cuticle sclerotization using recombinant pupal cuticular proteins from the tobacco hornworm, Manduca sexta, fungal or recombinant hornworm laccase-type phenoloxidase, and the cross-linking agent precursor N-acylcatecholamines, N-beta-alanydopamine (NBAD) or N-acetyldopamine (NADA). Recombinant M. sexta pupal cuticular proteins MsCP36, MsCP20, and MsCP27 were expressed and purified to near homogeneity. Polyclonal antisera to these recombinant proteins recognized the native proteins in crude pharate brown-colored pupal cuticle homogenates. Furthermore, antisera to MsCP36, which contains a type-1 Rebers and Riddiford (RR-1) consensus sequence, also recognized an immunoreactive protein in homogenates of larval head capsule exuviae, indicating the presence of an RR-1 cuticular protein in a very hard, sclerotized and nonpigmented cuticle. All three of the proteins formed small and large oligomers stable to boiling SDS treatment under reducing conditions after reaction with laccase and the N-acylcatecholamines. The optimal reaction conditions for MsCP36 polymerization were 0.3mM MsCP36, 7.4mM NBAD and 1.0U/mul fungal laccase. Approximately 5-10% of the monomer reacted to yield insoluble oligomers and polymers during the reaction, and the monomer also became increasingly insoluble in SDS solution after reaction with the oxidized NBAD. When NADA was used instead of NBAD, less oligomer formation occurred, and most of the protein remained soluble. Radiolabeled NADA became covalently bound to the MsCP36 monomer and oligomers during cross-linking. Recombinant Manduca laccase (MsLac2) also catalyzed the polymerization of MsCP36. These results support the hypothesis that during sclerotization, insect cuticular proteins are oxidatively conjugated with catechols, a posttranslational process termed catecholation, and then become cross-linked, forming oligomers and subsequently polymers.     

On the latency and nature of phenoloxidase present in the left colleterial gland of the cockroach Periplaneta americana

The phenoloxidase system responsible for the sclerotization of cockroach ootheca is found to be present as an inactive form in the left colleterial gland of Periplaneta americana. The supernatant fraction obtained by centrifugation of the milky white secretions contained the inactive phenoloxidase which required both sodium dodecyl sulfate (SDS) and the insoluble sediment for exhibiting enzyme activity. Bovine serum albumin could replace the sediment in the activation process. Proteins separated from the supernatant fraction by molecular sieve chromatography on Sephadex G-25 did not require either albumin or the sediment, but required SDS for exhibiting the phenoloxidase activity. Among the detergents tested, SDS (anionic) and cetylpyridinium chloride (cationic) activated the phenoloxidase, but CHAPS (zwitterionic) or nonionic detergents failed to activate the enzyme. The activation caused by SDS occurred well below the critical micellar concentration of SDS indicating that SDS is causing the activation by binding to the protein and altering its conformation. Chloroform-methanol extracts of vestibulum or right gland could replace SDS confirming the presence of endogenous activator(s) of phenoloxidase system. A variety of exogenously added lipids could activate the latent enzyme, among which linoleate, oleate, laurate, linolenate, phosphatidylethanolamine, and phosphatidylglycerol proved to be the effective activators of the latent phenoloxidase. Partially purified phenoloxidase was found to be extremely labile and lost its activity on a) freezing and thawing, b) dialysis, and c) heating for 10 min at 55 degrees C. It exhibited a pH optimum of 7 and was inhibited drastically by phenylthiourea and diethyldithiocarbamate. It readily oxidized a number of o-diphenols such as 3,4-dihydroxybenzylalcohol, 3,4-dihydroxyphenethyl alcohol, catechol, N-acetyldopamine, N-acetylnorepinephrine, dopa, dopamine, etc., but failed to oxidize both 3,4-dihydroxybenzoic acid and 3,4-dihydroxybenzaldehyde. It neither converted the typical laccase substrate syringaldazine to its quinone methide product, nor oxidized the p-diphenols, hydroquinone and methylhydroquinone. Therefore, the enzyme participating in the quinone tanning of cockroach ootheca appears to be a typical o-diphenol oxidase and not a laccase as previously thought.     

Quinone methide as a new intermediate in eumelanin biosynthesis

The conversion of dopachrome to dihydroxyindole(s), a key reaction in eumelanin biosynthetic pathway, has been shown to be under the control of dopachrome conversion factor. Dopachrome conversion factor isolated from the hemolymph of Manduca sexta larvae, which is devoid of any tyrosinase activity, exhibits a narrow substrate specificity and readily bleaches the iminochromes derived from the oxidation of L-dopa, L-dopa methyl ester, and alpha-methyl-L-dopa, but failed to attack the corresponding D-isomers. The product formed in the case of L-dopachrome was identified to be 5,6-dihydroxyindole. Therefore, aromatization of dopachrome seems to accompany its decarboxylation as well. However, the enzyme also converts L-dopachrome methyl ester to an indole derivative indicating that it can deprotonate the alpha-hydrogen when the carboxyl group is blocked. These results are accounted for by the transient formation and further transformation of a reactive quinone methide intermediate during the dopachrome conversion factor-catalyzed reaction. The fact that the enzyme-catalyzed conversion of alpha-methyl dopachrome methyl ester (where both decarboxylation and deprotonation are blocked) resulted in the generation of a stable quinone methide in the reaction mixture confirms this contention and supports our recent proposal that quinone methide and not indolenine is the key transient intermediate in the conversion of dopachrome to dihydroxyindole observed during melanogenesis.     

Characterization of quinone tautomerase activity in the hemolymph of Sarcophaga bullata larvae

The hemolymph of Sarcophaga bullata larvae was activated with either zymosan or proteolytic enzymes such as chymotrypsin or subtilisin and assayed for phenoloxidase activity by two different assays. While oxygen uptake studies readily attested to the wide specificty of activated phenoloxidase, visible spectral studies failed to confirm the accumulation of quinone products in the case of 4-alkyl substituted catechols such as N-acetyldopamine and N-β-alanyldopamine. Sepharose 6B column chromatography of the activated hemolymph resolved phenoloxidase activity into two fractions, designated as A and B. Peak A possessed typical o-diphenoloxidase (o-diphenol, oxygen oxidoreductase EC 1.10.3.1) activity, while peak B oxidized physiologically important catecholamine derivatives such as N-acetyldopamine, N-acetylnorepinephrine, and N-β-alanyldopamine into N-acetylnorepinephrine, N-acetylarterenone, and N-β-alanylnorepinephrine, respectively, and converted 3,4-dihydroxyphenylacetic acid, 3,4-dihydroxymandelic acid, and 3,4-dihydroxyphenylglycol into 3,4-dihydroxymandelic acid, 3,4-dihydroxybenzaldehyde, and 2-hydroxy-3′,4′-dihydroxyacetophenone, respectively. These transformations are consistent with the conversion of phenoloxidase-generated quinones to quinone methides and subsequent non-enzymatic transformations of quinone methides. Accordingly, Peak B contained both o-diphenoloxidase activity and quinone tautomerase activity. Sepharose 6B column chromatography of unactivated hemolymph resulted in the separation of quinone tautomerase from prophenoloxidase. The tautomerase rapidly converted both chemically made and mushroom tyrosinase-generated quinones to quinone methides. Thus the failure to observe the accumulation of quinones with N-acyl derivatives of dopamine and related compounds in the whole hemolymph is due to the rapid conversion of these long lived toxic quinones to short lived quinone methides. The latter, being unstable, undergo rapid non-enzymatic transformations to form side-chain-oxygenated products that are non-toxic. The possible roles of quinone isomerase and its reaction products—quinone methides—as essential components of sclerotization of cuticle and defense reaction of Sarcophaga bullata are discussed.     

Trapping of transiently formed quinone methide during enzymatic conversion of N-acetyldopamine to N-acetylnorepinephrine

We have demonstrated that quinone methide formation is an important aspect of insect physiology and proposed that enzymatically generated quinone methides react nonenzymatically with water or other nucleophiles to form Michael-1,6-addition products [(1988) Adv. Insect Physiol. 21, 179-231; (1989) J. Cell. Biochem. suppl. 13C, 58]. Using a purified o-quinone isomerase from the larval cuticle of Sacrophaga bullata and mushroom tyrosinase, we now demonstrate that transiently formed N-acetyldopamine quinone methide from N-acetyldopamine can be trapped by methanol to produce beta-methoxy N-acetyldopamine. The methanol adduct thus formed was found to be a racemic mixture and can be resolved into the optical isomers on cyclodextrin chiral column. These results confirm our contention that enzymatically generated quinone methides are nonenzymatically and nonstereoselectively transformed to Michael-1,6-adducts by reaction with water or other nucleophiles.     

Quantitative determination of catecholic degradation products from insect sclerotized cuticles

Acid hydrolysates of cuticle from various insect species were quantitatively analyzed for five catecholic amino acid adducts. Four of the adducts are ketocatechols; in three of them the amino acid moiety, either lysine, glycine or beta-alanine, is connected via its amino group to the alpha-carbon atom of 3,4-dihydroxyacetophenone, in the fourth a tyrosine residue is connected to the same position via its phenolic group. The fifth adduct contains histidine linked via its imidazole-ring to the beta-position of the dopamine sidechain. The three ketocatecholic adducts containing alpha-amino acids were obtained in significant yields from adult cuticles of the locust Schistocerca gregaria, the cockroaches Blaberus craniifer and Periplaneta americana, and the beetles Pachynoda sinuata and Tenebrio molitor, but only in trace amounts from larval and pupal cuticles of T. molitor, pupal cuticles of the moths Manduca sexta and Hyalophora cecropia, and puparia of the blowfly Calliphora vicina. The beta-alanine-containing ketocatechol was not obtained from cuticle of locusts and T. molitor larvae and pupae, but it was present in the hydrolysates of the other cuticles. The beta-histidine-dopamine adduct was obtained from all the cuticles, the highest yield was obtained from adult P. sinuata and the lowest yield was from adult S. gregaria. The beta-histidine-dopamine adduct is derived from the product formed by reaction of p-quinone methides of N-acetyldopamine (NADA) or N-beta-alanyldopamine (NBAD) with histidine residues in the cuticular proteins. The ketocatecholic adducts are assumed to be degradation products of crosslinks formed when oxidized dehydro-NADA reacts with the cuticular proteins. The insect species investigated appear to use both pathways for sclerotization, but to widely differing extents; the dehydro-NADA pathway dominates in cuticles which are exposed to strong deforming forces, such as those of adult locusts and cockroaches, and the p-quinone methide pathway dominates in cuticle of lepidopteran pupae and blowfly puparia, which are not exposed to strong mechanical forces but have to be effectively protected against microbial and fungal attacks.     

Mass spectrometric profiling of glucosamine, glucosamine polymers and their catecholamine adducts. Model reactions and cuticular hydrolysates of Toxorhynchites amboinensis (Culicidae) pupae.

Glucosamine (Gln), glucosamine polymers, and their catecholamine adducts were characterized using positive ion electrospray mass spectrometry (ESMS) and tandem mass spectrometry (ESMS-MS). N-acetyldopamine (NADA), a catecholamine found in many insect cuticles, was oxidized using mushroom tyrosinase, and the resulting quinone derivatives were reacted with Gln, (Gln)3, and polymeric glucosamine (chitosan). Adducts of glucosamine and its trisaccharide with NADA were readily identified as [M + H]+ ions in ESMS spectra, and ESMS-MS of selected ions confirmed the condensation of 1-3 NADA residues with Gln. In addition to Gln modification by the quinone derivatives of NADA, other spectra were consistent with the formation of adducts with N-acetylnoradrenaline and moieties formed by intramolecular cyclization following oxidation. The primary amine of glucosamine was involved in initial adduct formation, but the sites for subsequent additions of oxidized NADA to glucosamine, presumably via hydroxyl groups, could not be identified by ESMS alone. The ESMS spectra of chitosan films infused into the spectrometer following solubilization in acidic methanol/water produced spectra similar to that of (Gln)3 up to m/z 502. Ions of gradually decreasing intensity consistent with (Gln)x, where x = 4-8, were observed. Modification of chitosan films following incubation with NADA plus tyrosinase rendered the films insoluble in dilute acid, simulating the cross-linking process proposed to occur during insect cuticle sclerotization. Acid hydrolysates of the pupal stage of the mosquito Toxorhynchites amboinensis, using only two pupal exuviae for the hydrolyses, were infused into the mass spectrometer without preliminary chromatography. Eight amino acids, glucosamine, N-acetylglucosamine, catecholamines, and a variety of polymers incorporating these compound classes were identified.     

Tyrosinase catalyzes an unusual oxidative decarboxylation of 3,4-dihydroxymandelate

Tyrosinase usually catalyzes the conversion of monophenols to o-diphenols and oxidation of diphenols to the corresponding quinones. However, when 3,4-dihydroxymandelic acid was provided as the substrate, it catalyzed an unusual oxidative decarboxylation reaction generating 3,4-dihydroxybenzaldehyde as the sole product. The identity of the product was confirmed by high-performance liquid chromatography (HPLC) as well as ultraviolet and infrared spectral studies. None of the following enzymes tested catalyzed the new reaction: galactose oxidase, ceruloplasmin, superoxide dismutase, ascorbate oxidase, dopamine beta-hydroxylase, and peroxidase. Phenol oxidase inhibitors such as phenylthiourea, potassium cyanide, and sodium azide inhibited the reaction drastically, suggesting the participation of the active site copper of the enzyme in the catalysis. Mimosine, a well-known competitive inhibitor of tyrosinase, competitively inhibited the new reaction also. 4-Hydroxymandelic acid and 3-methoxy-4-hydroxymandelic acid neither served as substrates nor inhibited the reaction. Putative intermediates such as 3,4-dihydroxybenzyl alcohol and (3,4-dihydroxybenzoyl)formic acid did not accumulate during the reaction. Oxidation to a quinone methide derivative rather than conventional quinone accounts for this unusual oxidative decarboxylation reaction. Earlier from this laboratory, we reported the conversion of 4-alkylcatechols to quinone methides catalyzed by a cuticular phenol oxidase [Sugumaran, M., & Lipke, H. (1983) FEBS Lett. 155, 65-68]. Present studies demonstrate that mushroom tyrosinase will also catalyze quinone methide production with the same active site copper if a suitable substrate such as 3,4-dihydroxymandelic acid is provided.     

4-alkyl-o-quinone/2-hydroxy-p-quinone methide isomerase from the larval hemolymph of Sarcophaga bullata. I. Purification and characterization of enzyme-catalyzed reaction

An enzyme which catalyzes the conversion of certain 4-alkyl-o-benzoquinones to 2-hydroxy-p-quinone methides has been purified to apparent homogeneity from the hemolymph of Sarcophaga bullata by employing conventional protein purification techniques. The purified enzyme migrated with an approximate molecular weight of 98,000 on gel filtration chromatography. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, it migrated as a single band with a molecular weight of 46,000, indicating that it is made up of two identical subunits. It exhibited a pH optimum of 6.0 and readily converted chemically synthesized as well as enzymatically generated quinones derived from N-acetyldopamine, N-beta-alanyldopamine, and 3,4-dihydroxyphenethyl alcohol to highly unstable 2-hydroxy-p-quinone methides. The quinone methides thus formed were rapidly and nonenzymatically hydrated to form side chain hydroxylated o-diphenols as the stable product. In support of this proposition, when the enzyme reaction with N-acetyldopamine quinone was conducted in the presence of 10% methanol, racemic beta-methoxy-N-acetyldopamine was recovered as an additional product. The quinones of N-acetylnorepinephrine, N-beta-alanylnorepinephrine, and 3,4-dihydroxyphenylglycol were also attacked by the isomerase, resulting in the formation of N-acetylarterenone, N-beta-alanylarterenone and 2-hydroxy-3',4'-dihydroxyacetophenone, respectively as the stable products. The isomerase converted the dihydrocaffeiyl methyl amide quinone to its quinone methide analog which rapidly tautomerized to yield caffeiyl methyl amide. The importance of quinone isomerase in insect immunity and sclerotization of insect cuticle is discussed.