Lignin-Derived Compounds as Efficient Laccase Mediators for Decolorization of Different Types of Recalcitrant Dyes

Ten phenols were selected as natural laccase mediators afterscreening 44 different compounds with a recalcitrant dye (ReactiveBlack 5) as a substrate. Their performances were evaluated atdifferent mediator/dye ratios and incubation times (up to 6h) by the use of Pycnoporus cinnabarinus and Trametes villosalaccases and were compared with those of eight known syntheticmediators (including -NOH- compounds). Among the six types ofdyes assayed, only Reactive Blue 38 (phthalocyanine) was resistantto laccase-mediator treatment under the conditions used. AcidBlue 74 (indigoid dye), Reactive Blue 19 (anthraquinoid dye),and Aniline Blue (triarylmethane-type dye) were partially decolorizedby the laccases alone, although decolorization was much moreefficient and rapid with mediators, whereas Reactive Black 5(diazo dye) and Azure B (heterocyclic dye) could be decolorizedonly in the presence of mediators. The efficiency of each naturalmediator depended on the type of dye to be treated but, withthe only exception being Azure B (<50% decolorization), nearlycomplete decolorization (80 to 100%) was attained in all cases.Similar rates were attained with the best synthetic mediators,but the reactions were significantly slower. Phenolic aldehydes,ketones, acids, and esters related to the three lignin unitswere among the best mediators, including p-coumaric acid, vanillin,acetovanillone, methyl vanillate, and above all, syringaldehydeand acetosyringone. The last two compounds are especially promisingas ecofriendly (and potentially cheap) mediators for industrialapplications since they provided the highest decolorizationrates in only 5 to 30 min, depending on the type of dye to betreated.

INTRODUCTION

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Introduction

Laccases are multicopper oxidases that catalyze the one-electronoxidation of substituted phenols, anilines, and aromatic thiolsto their corresponding radicals with the concomitant reductionof molecular oxygen to water. Laccases are produced by plantsand fungi, including white-rot basidiomycetes responsible forlignin degradation in nature (36, 46), although some bacteriallaccases have been recently described and fully characterized(17). It is because of the involvement of laccases in lignindegradation that they were first investigated for applicationsin the pulp and paper industry as substitutes for chlorine-containingreagents for pulp bleaching (38, 41).

The broad substrate specificities of laccases, together withthe fact that they use molecular oxygen as the final electronacceptor instead of the hydrogen peroxide used by ligninolyticperoxidases (38), make these enzymes highly interesting forthe pulp and paper industry as well as for other industrialand environmental applications. However, the low redox potentialsof laccases (0.5 to 0.8 V) compared to those of ligninolyticperoxidases (>1 V) only allow the direct degradation by laccasesof low-redox-potential phenolic compounds and not the oxidationof the most recalcitrant aromatics, including different industrialdyes (49). Nevertheless, insights into lignin degradation bysome white-rot fungi that only produce laccase showed a wayto a new type of laccase applications involving enzyme mediators.

The basis of the laccase-mediator concept is the use of low-molecular-weightcompounds that, once oxidized by the enzyme to stable radicals,act as redox mediators, oxidizing other compounds that in principleare not substrates of laccase. From the description of the firstlaccase mediator, 2,2'-azino-bis-(3-ethylbenzothiazoline-6-sulfonicacid) (ABTS) (4), to the more recent use of the -NOH- type,synthetic mediators, including 1-hydroxybenzotriazole (HBT),violuric acid (VIO), and N-hydroxyacetanilide (NHA), a largenumber of studies have been produced on the mechanisms of oxidationof nonphenolic substrates (2, 3, 48), the search for new mediators(5, 18), and their use in pulp bleaching (7, 20, 39). More recently,applications of the laccase-mediator system in the degradationof aromatic xenobiotics (including polychlorinated biphenyls,fungicides, industrial dyes, and polycyclic and other aromatichydrocarbons) have been investigated (26, 27, 28, 37, 42). Nevertheless,the laccase-mediator system has yet to be applied at the millscale due to the cost of mediators and the lack of studies thatguarantee the absence of toxic effects of these compounds ortheir derivatives.

The use of naturally occurring laccase mediators would presentenvironmental and economic advantages. Compounds involved inthe natural degradation of lignin by white-rot fungi may bederived from oxidized lignin units or directly from fungal metabolism(16, 25, 34). In addition to enabling the oxidation of compoundsthat are not oxidized by laccases (e.g., the nonphenolic ligninmoiety), the mediators can diffuse far away from the myceliumto sites that are difficult to reach by the enzyme itself (e.g.,the lignin macromolecule inside the plant cell wall).

The purpose of the present study was to evaluate the potentialof several naturally occurring (mostly phenolic) compounds tomediate the oxidative reactions catalyzed by laccase with theaim of identifying cheaper, more efficient and ecofriendly mediatorsfor the decolorization of recalcitrant dyes and for other industrialand environmental applications. To evaluate the mediating capabilitiesof these compounds, we used a test based on the decolorizationof Reactive Black 5, a recalcitrant dye that is not oxidizedby laccase alone (12). Once selected, the new natural mediatorswere assayed for the decolorization of different types of industrialdyes by laccase.

MATERIALS AND METHODS

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Materials and Methods

Chemicals.
The compounds mentioned in Fig. 1 as well as the synthetic compoundsHBT, VIO, promazine (PZ), 2-nitroso-1-naphthol-4-sulfonic acid(HNNS), 1-nitroso-2-naphthol-3,6-disulfonic acid (NNDS), and2,2,6,6-tetramethylpiperidin-1-yloxy (TEMPO) were purchasedfrom Sigma-Aldrich. ABTS was supplied by Roche. 3-Hydroxyanthranilicacid (HAA), a Pycnoporus cinnabarinus metabolite (16), was alsoobtained from Sigma-Aldrich.

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FIG. 1. Screening for natural mediators based on decolorization of Reactive Black 5 (50 µM) after a 2-h treatment with P. cinnabarinus laccase in the presence of 44 phenolic compounds (50 µM) monitored at 598 nm. No decolorization was obtained with the following 18 compounds (even with a 500 µM concentration): 4-aminobenzoic acid, 4-aminophenol, catechol, 3,5-diaminobenzoic acid, ferulic acid, histidine, homovanillyl alcohol, hydroxylamine, 4-hydroxyacetophenone, 1,4-hydroquinone, 2-methoxyhydroquinone, 4-methoxyphenol, 4-(methylamino)benzoic acid, 2-methyl-1,4-hydroquinone, methyl 4-hydroxybenzoate, phenylalanine, protocatechuic acid, and vanillylacetone.

The Acid Blue 74, Aniline Blue, Reactive Blue 19, and AzureB dyes were obtained from Sigma-Aldrich, whereas Reactive Black5 and Reactive Blue 38 were supplied by Dye Star (Frankfurt,Germany). Decolorization of the different dyes was monitoredat their absorption maxima as described below.

Enzymes.
P. cinnabarinus laccase was produced by Beldem (Andenne, Belgium)from the monokaryotic hyperproducing strain ss3 obtained fromstrain I-937 (23). Commercial laccase from Trametes villosa("Polyporus pinsitus") was supplied by Novozymes (Denmark).Both laccase preparations were used for dye decolorization withoutfurther purification. Laccase activities were determined bymonitoring 5 mM ABTS oxidation to its cation radical ( ${varepsilon}$ ₄₃₆, 29,300mM^–1 cm^–1) in 100 mM acetate buffer, pH 5. One activityunit was defined as the amount of enzyme that releases 1 µmolof product per min.

The optimum pH for substrate (100 µM) oxidation by laccaseswas estimated by the use of 100 mM sodium citrate (pH 3, 4,5, and 6) and 100 mM sodium citrate-phosphate-borate (pH 2)buffers at 24°C. Laccase activities on phenols (50 µM)were estimated spectrophotometrically by using 100 mU of enzyme/mlin 50 mM sodium citrate buffer, pH 5. Oxidation rates were estimatedby decreases in substrate absorbance in the cases of acetovanillone( ${varepsilon}$ ₃₀₄, 7,100 M^–1 cm^–1), acetosyringone ( ${varepsilon}$ ₃₂₀, 6,000M^–1 cm^–1), p-coumaric acid ( ${varepsilon}$ ₃₁₂, 11,100 M^–1cm^–1), ethyl vanillin ( ${varepsilon}$ ₃₁₂, 6,466 M^–1 cm^–1),vanillin ( ${varepsilon}$ ₃₀₈, 9,200 M^–1 cm^–1), and syringaldehyde( ${varepsilon}$ ₃₂₀, 8,500 M^–1 cm^–1) or by increases in productabsorbance in the cases of 2,4,6-trimethoxyphenol ( ${varepsilon}$ ₃₁₀, 5,502M^–1 cm^–1), 2,6-dimethylphenol ( ${varepsilon}$ ₃₀₀, 4,717 M^–1cm^–1), vanillyl alcohol ( ${varepsilon}$ ₃₂₀, 2,933 M^–1 cm^–1),and methyl vanillate ( ${varepsilon}$ ₃₂₂, 3,217 M^–1 cm^–1). Themolar absorbances of the substrates were estimated under reactionconditions. The molar absorbances of the reaction products wereobtained after complete substrate oxidation with laccase.

Purified P. cinnabarinus laccase was used for estimations ofkinetic constants on phenols. Mean values and 95% confidencelimits of K_m and V_max values were obtained. Laccase purificationincluded (i) the removal of glycerol, present in the preparationsupplied by Beldem, by centrifugation at 13,000 rpm (SorvalSS-34 rotor) for 9 h at 4°C; (ii) dialysis and concentrationby ultrafiltration (Amicon 3-kDa-cutoff columns) with 25 mMsodium acetate buffer, pH 5; (iii) Q-Resource chromatographyin the same buffer with a linear NaCl gradient (0 to 0.5 M in6 min) at a flow rate of 6 ml/min; and (iv) a final dialysisstep against 100 mM sodium citrate buffer, pH 5, and conservationat –80°C.

Mediator screening.
Screening for natural mediators was based on the decolorizationof Reactive Black 5 (monitored at 598 nm) by P. cinnabarinuslaccase in the presence of each compound. The compounds mentionedin Fig. 1 were investigated as new mediators. For this purpose,100 mU of P. cinnabarinus laccase/ml, 50 µM Reactive Black5, and two concentrations of each potential mediator (50 and500 µM) were incubated in the buffer described above atpH 5 for 2 and 6 h at 24°C in 1-ml plastic cuvettes.

Mediator concentration and pH.
The effects of the mediator concentration and reaction timewere studied by the use of 25 µM Reactive Black 5 in thepresence of 0.1, 1, 10, 25, 50, 100, 250, and 500 µM concentrationsof mediator for different times (from 10 min to 6 h) with 100mU of P. cinnabarinus laccase/ml in the buffer described aboveat 24°C in 1-ml cuvettes.

The effect of pH on dye decolorization was studied by treating25 µM Reactive Black 5 with 100 mU of P. cinnabarinuslaccase/ml in the presence of a 100 µM concentration ofmediator (syringaldehyde or acetosyringone) in the buffer describedabove (pH 3, 4, 5, and 6) at 24°C in 1-ml cuvettes with160-rpm agitation.

Decolorization of different dye types.
Assays of decolorization of 25 µM Azure B, Reactive Blue19, Acid Blue 74, Reactive Blue 38, and Aniline Blue were performedwith 100 mU of a laccase preparation from P. cinnabarinus orT. villosa and 25, 50, and 100 µM concentrations of mediatorin the buffer described above (pH 5) for 6 h with agitation(160 rpm) in 1-ml cuvettes at 24°C. Decreases in the absorbancemaxima characteristic of Azure B (647 nm), Reactive Blue 19(592 nm), Acid Blue 74 (608 nm), Reactive Blue 38 (620 nm),and Aniline Blue (592 nm) were measured at different incubationtimes. Ten natural compounds selected from the previous screening,HAA, and the seven synthetic compounds listed above were usedas mediators in these experiments. Absorption spectra between275 and 800 nm were recorded during dye decolorization withselected mediators by use of a diode-array spectrophotometer.

RESULTS

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Results

Mediator screening and dye decolorization conditions.
Among the 44 compounds screened as laccase mediators (phenolicalcohols, aldehydes, ketones, acids, esters, and some amines),22 promoted the decolorization of Reactive Black 5 by P. cinnabarinuslaccase with the same concentrations of mediator and dye (Fig.1). The 10 phenols shown in Fig. 2a to j produced decolorizationrates of 10 to 80% and were selected for additional studieswith different types of dyes. The laccase activities on thesecompounds at the concentrations used for mediators are shownin Table 1. Among them, acetosyringone and syringaldehyde providedthe highest decolorization rates. The kinetic constants of P.cinnabarinus laccase (purified to a final yield of 39%) werecalculated for syringaldehyde (K_m, 116 ± 3 µM;V_max, 244 ± 0 U/mg), acetosyringone (K_m, 1,404 ±407 µM; V_max, 122 ± 38 U/mg), vanillin (K_m, 143± 15 µM; V_max, 2 ± 0 U/mg), acetovanillone(K_m, 102 ± 18 µM; V_max, 2 ± 0 U/mg), andp-coumaric acid (K_m, 301 ± 63 µM; V_max, 201 ±33 U/mg). The optimum pH for acetosyringone and syringaldehydeoxidation by laccase was about pH 3 (Fig. 3). In contrast, themost (and fastest) decolorization of Reactive Black 5 with thesetwo mediators was obtained at pH 5. Therefore, pH 5 was usedfor subsequent decolorization assays.

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FIG. 2. Chemical structures of the 10 phenolic compounds (a to j) selected in the mediator screening (Fig. 1) and of 7 synthetic mediators and HAA (k to r). (a) Acetosyringone; (b) syringaldehyde; (c) 2,6-dimethylphenol; (d) 2,4,6-trimethoxyphenol; (e) ethyl vanillin; (f) acetovanillone; (g) vanillin; (h) vanillyl alcohol; (i) methyl vanillate; (j) p-coumaric acid; (k) ABTS; (l) HBT; (m) VIO; (n) TEMPO; (o) HNNS; (p) NNDS; (q) PZ; (r) HAA.

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TABLE 1. Activity of P. cinnabarinus laccase on the 10 phenols selected, relative to ABTS (50 µM concentration)

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FIG. 3. Effect of pH on mediator (100 µM) oxidation (continuous lines) and initial (5 min) Reactive Black (25 µM) decolorization (dashed lines) by P. cinnabarinus laccase monitored at 598 nm. Mediators: ${blacksquare}$ , acetosyringone; ${blacktriangleup}$ , syringaldehyde.

The influences of the natural mediator concentrations on thedecolorization of Reactive Black 5 (2-h treatment) are shownin Fig. 4. Laccase in the presence of acetosyringone and syringaldehydeproduced the strongest decolorization rate (>80%) at a mediator/dyeratio of only 2:1. In contrast, the p-coumaric acid decolorizationrate was directly proportional to the mediator concentration.Reactions with the synthetic mediators HBT and VIO (data notshown) required much higher mediator concentrations than thosefor acetosyringone and syringaldehyde (up to 250 µM) toattain similar decolorization rates.

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FIG. 4. Effect of mediator concentration on dye decolorization (%) by P. cinnabarinus laccase (2-h treatment of 25 µM Reactive Black 5 monitored at 598 nm). Mediators: ${blacksquare}$ , acetosyringone; ${blacktriangleup}$ , syringaldehyde; +, 2,4,6-trimethoxyphenol; •, vanillin; ${diamondsuit}$ , p-coumaric acid.

Decolorization of different types of dyes.
The 10 natural mediators described above were evaluated forthe oxidation of six dyes with different chemical structures(Fig. 5). Three mediator concentrations and both P. cinnabarinusand T. villosa laccases were used for 6-h treatments, althoughthe most significant differences were observed during the first2 h. The results were compared with those obtained with HAAand seven synthetic mediators, i.e., the two mentioned aboveand ABTS, PZ, HNNS, NNDS, and TEMPO (Fig. 2k to r).

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FIG. 5. Chemical structures of the different dyes assayed. (A) Reactive Black 5 (diazo type); (B) Azure B (heterocyclic); (C) Reactive Blue 19 (anthraquinoid); (D) Aniline Blue (triarylmethane type); (E) Acid Blue 74 (indigoid); (F) Reactive Blue 38 (phthalocyanine type).

(i) Reactive Black 5.
The diazo dye Reactive Black 5 (Fig. 5A) had been previouslyused for the screening and optimization of treatment conditions.Its decolorization by laccase and natural mediators (50 µM)as a function of time is shown in Fig. 6A. Acetosyringone andsyringaldehyde not only produced the largest amounts of decolorizationbut also were extremely rapid at decolorizing the dye (>80%decolorization in 5 min). In contrast, the most effective syntheticmediators, NNDS and HNNS, required 4 h to attain 70 to 80% decolorization,and HBT and VIO only reached 50 to 60% after 6 h (Fig. 6B).Among the natural mediators, 2,4,6-trimethoxyphenol and vanillinalso required several hours to attain 70 and 50% decolorization,respectively.

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FIG. 6. Reactive Black 5 (A and B) and Azure B (C and D) (25 µM) decolorization by P. cinnabarinus laccase, monitored at 598 and 647 nm, respectively, in the presence of natural (left) and synthetic (right) mediators (50 µM in panels A and B; 100 µM in panels C and D). Natural mediators: ${blacksquare}$ , acetosyringone; ${blacktriangleup}$ , syringaldehyde; ${circ}$ , 2,6-dimethylphenol; +, 2,4,6-trimethoxyphenol; ${triangleup}$ , ethyl vanillin; ${square}$ , acetovanillone; •, vanillin; ${diamond}$ , vanillyl alcohol; x, methyl vanillate; ${diamondsuit}$ , p-coumaric acid; , HAA. Synthetic mediators: ${diamondsuit}$ , HNNS; •, NNDS; {zam004055305gra6} , PZ; ${blacksquare}$ , HBT; ${blacktriangleup}$ , VIO; ${diamond}$ , ABTS; ${circ}$ , TEMPO. Dashed lines, no mediator.

(ii) Azure B.
The decolorization of Azure B, a heterocyclic dye (Fig. 5B)which, like Reactive Black 5, is not oxidized by laccase alone,is shown in Fig. 6C and D. In the presence of mediators, AzureB was decolorized to a lesser extent than Reactive Black 5.Effective mediating capabilities were observed for acetosyringoneand p-coumaric acid, with both attaining 40% decolorizationat a 100 µM mediator concentration, but decolorizationoccurred significantly more rapidly (15 min) with acetosyringone.Less than 10% color removal was obtained with syringaldehyde,whereas HAA produced about 25% decolorization. When the mediatorconcentration was raised above 100 µM, an enhancementof decolorization (about 60% in 2 h) was observed with p-coumaricacid (data not shown), but no effect was produced on acetosyringoneor syringaldehyde decolorization (as also found for ReactiveBlack 5 decolorization). HNNS and NNDS were the most effectivesynthetic mediators, although they produced slower Azure B decolorizationthan the most effective natural mediators.

(iii) Reactive Blue 19.
The anthraquinoid dye Reactive Blue 19 (Fig. 5C) was 90% decolorizedby laccase alone in 6 h, and the effect of the different mediatorswas more easily observed after short reaction times (Fig. 7A and B).Acetosyringone and syringaldehyde strongly accelerateddecolorization during the first minutes of reaction (e.g., anearly 20-fold increase by 25 µM syringaldehyde after5 min). p-Coumaric acid also improved decolorization duringthe first 15 min. Among the synthetic mediators, HNNS and NNDSenabled >80% decolorization in 30 min, whereas HBT and VIOdid not significantly improved Reactive Blue 19 decolorizationafter the same amount of time.

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FIG. 7. Reactive Blue 19 (A and B) and Aniline Blue (C and D) (25 µM) decolorization by P. cinnabarinus laccase in the presence of natural (left) and synthetic (right) mediators (25 µM in panels A and B; 100 µM in panels C and D) monitored at 592 nm. Natural mediators: ${blacksquare}$ , acetosyringone; ${blacktriangleup}$ , syringaldehyde; ${circ}$ , 2,6-dimethylphenol; +, 2,4,6-trimethoxyphenol; ${triangleup}$ , ethyl vanillin; ${square}$ , acetovanillone; •, vanillin; ${diamond}$ , vanillyl alcohol; x, methyl vanillate; ${diamondsuit}$ , p-coumaric acid; –, HAA. Synthetic mediators: ${diamondsuit}$ , HNNS; •, NNDS; {zam004055305gra7} , PZ; ${blacksquare}$ , HBT; ${blacktriangleup}$ , VIO; ${diamond}$ , ABTS; ${circ}$ , TEMPO. Dashed lines, no mediator.

(iv) Aniline Blue.
The triarylmethane-type dye Aniline Blue (Fig. 5D) was decolorizedup to 35% by laccase alone in 6 h, with the rate being stronglyincreased by natural mediators (Fig. 7C and D). Up to 80% decolorizationwas obtained with acetosyringone and syringaldehyde within 5min. In fact, most of the natural mediators tested stronglyenhanced Aniline Blue decolorization by laccase (up to 70% decolorizationwas attained with vanillin, acetovanillone, ethyl vanillin,and methyl vanillate), except for p-coumaric and vanillyl alcohol.Synthetic mediators also gave adequate decolorization rates,except for ABTS, which did not mediate the reaction. PZ, NNDS,and HNNS were the most efficient synthetic mediators.

(v) Acid Blue 74.
The indigoid dye Acid Blue 74 (Fig. 5E) was decolorized 50%by laccase alone in 6 h, but the presence of any of the naturalmediators increased this rate to 100% at the lowest concentrationin less than 1 h (except for 2,6-dimethylphenol and vanillylalcohol, which required 2 to 4 h). The decolorization ratesafter 30 min are shown in Fig. 8. Complete decolorization wasachieved during the first 5 min with acetosyringone and syringaldehyde.In general, synthetic mediators were less efficient. Among them,PZ was the most rapid and efficient, followed by HNNS and NNDS,enabling 100% decolorization after 1 h. In contrast, ABTS didnot enhance decolorization.

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FIG. 8. Decolorization of Acid Blue 74 (25 µM) after 5-min reactions with laccase and mediators (25 µM) monitored at 608 nm. Bars represent the percentages of decolorization obtained by P. cinnabarinus laccase in the presence of synthetic (white bars) and natural (black bars) mediators and in the absence of mediators (hatched bar).

(vi) Reactive Blue 38.
The phthalocyanine-type dye Reactive Blue 38 (Fig. 5F) was notoxidized by laccase alone or in the presence of any of the naturalor synthetic mediators assayed.

From the above results, acetosyringone appeared to be one ofthe most efficient natural mediators of laccase decolorizationof the five dyes assayed. The decolorization rates attainedwith the two laccases assayed at different acetosyringone/dyemolar ratios and treatment times are summarized in Table 2.The UV-visible spectra of Reactive Black 5 and Acid Blue 74and the changes produced during fast decolorization (scans every5 s) with P. cinnabarinus laccase and acetosyringone are shownin Fig. 9A and B, in contrast to the slow decolorization (scansevery 10 min) in the presence of vanillin (Fig. 9C and D).

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TABLE 2. Decolorization of five dyes after different treatment times with laccases from P. cinnabarinus and T. villosa using different acetosyringone/dye molar ratios^a

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FIG. 9. Changes in absorption spectra (275 to 800 nm) of two dyes (25 µM) during decolorization with P. cinnabarinus laccase (100 mU/ml) in the presence of acetosyringone (25 µM) or vanillin (25 µM) (reactions were carried out at 24°C and pH 5). (A) Reactive Black 5 decolorization with acetosyringone (spectra were recorded every 5 s for a total time of 5 min). (B) Acid Blue 74 decolorization with acetosyringone (spectra were recorded every 5 s for a total time of 1 min). (C) Reactive Black 5 decolorization with vanillin (spectra were recorded every 10 min for a total time of 12 h). (D) Acid Blue 74 decolorization with vanillin (spectra were recorded every 10 min for a total time of 90 min).

DISCUSSION

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Discussion

Natural mediator screening.
Reactive Black 5 is not oxidized by laccases from P. cinnabarinusand T. villosa, despite both being high-redox-potential laccases(32, 43). This is probably due to the high redox potential ofthis dye, which is not oxidized by chemical oxidizers such asMn³⁺ (22), but steric hindrances may also reduce the accessibilityof the -OH and -NH₂ groups to laccases. Only methyl or methoxyortho-substituted diazo dyes have been shown to be oxidizedby laccases (11). However, the decolorization of Reactive Black5 by a laccase is possible in the presence of redox mediators(12). This reaction was used as a test to evaluate the mediatingcapabilities of naturally occurring phenols, amines, and othercompounds under study. The 10 mediators selected among 44 differentcompounds included phenols derived from syringyl (S), guaiacyl(G), and p-hydroxyphenyl (H) lignin units, characterized bythe presence of two, one, or no methoxy substituents, respectively(in ortho positions with respect to the phenolic hydroxyl) (24),such as syringaldehyde, acetosyringone, vanillin, acetovanillone,methyl vanillate, and p-coumaric acid. Recently, some phenols,including syringaldehyde and acetosyringone, have been describedas laccase mediators for indigo decolorization (9) as well asfor the transformation of a fungicide (27) and hydrocarbon degradation(25). However, the present study provides the first comprehensivescreening for natural mediators, which were then compared withsynthetic artificial mediators for the ability to decolorizedifferent types of dyes. Moreover, the capabilities of naturalphenols to act as laccase mediators were demonstrated by theuse of mediator/substrate molar ratios of 1 to 4, which aremuch lower than those used in the studies mentioned above (ratiosof 19 to 40) (25, 27). Both the possibility of obtaining mediatorsfrom natural sources (lignin) and the low mediator/substrateratios used strongly increased the feasibility of the laccase-mediatorsystem for industrial or environmental applications. In fact,syringaldehyde and acetosyringone are among the main productsfrom both biological and enzymatic degradation and chemical(alkaline) depolymerization of S-rich lignins (14, 29), suchas lignins of eucalypt and some nonwoody plants (15, 21).

Enzymatic decolorization of dyes.
P. cinnabarinus laccase (33, 44) has been investigated for usein paper pulp bleaching (8, 43), but we showed in the presentstudy that it is also efficient for dye decolorization. No significantdifferences from T. villosa (50) laccase were observed in thepresence of the same mediators. This shows that once an enzymeposses a redox potential that is high enough to oxidize themediator (those of both laccases used here exceed 0.7 V) (32,43), the efficiency of the laccase-mediator system mainly dependson the mediator used. Except for the phthalocyanine-type dyeReactive Blue 38, all other dyes assayed could be decolorizedby the use of laccases and mediators. Efficient decolorizationwas confirmed by UV-visible spectroscopy showing a general decreasein dye absorption (in the 275- to 800-nm region) during laccase-mediatortreatments. The decolorization of Reactive Blue 38 by ligninolyticperoxidases was reported previously (22). The anthraquinoid(Reactive Blue 19), indigoid (Acid Blue 74), and triarylmethane-type(Aniline Blue) dyes assayed could be directly decolorized bythe P. cinnabarinus and T. villosa laccases. However, the presenceof phenolic mediators strongly accelerated the reaction andincreased the decolorization rates attained. The most recalcitrantdyes were the heterocyclic dye (Azure B), which is used to detectlignin peroxidase activity because it is not oxidized by laccaseor manganese peroxidase alone, but it was partially decolorizedin the presence of the mediators (1). The diazo dye ReactiveBlack 5 was oxidized by laccase only in the presence of mediators,but high decolorization rates were attained. Most of the phenolicmediators tested here were much more effective than HAA, a metaboliteof P. cinnabarinus that was described as a natural laccase mediator(16), although more recent studies have shown that it does notplay a role in lignin biodegradation as initially suggested(31). On the other hand, the most efficient natural mediatorsidentified, i.e., syringaldehyde and acetosyringone, were alwaysmore rapid at decolorizing dyes (only 5 to 30 min were required)than the synthetic mediators, including the best-known mediatorsHBT and VIO as well as HNNS and NNDS (which provided the bestresults among synthetic mediators).

Natural mediator oxidation by laccase.
The limiting step in the oxidation of phenols by laccase isthe first electron transfer from the substrate to T1 copper,a reaction that is mainly governed by differences in redox potentialbetween the phenol and the enzyme (47). The electron donor effectof methoxy substituents at the benzenic ring enhances laccaseactivity due to a decreased redox potential. In this way, acetosyringoneand syringaldehyde (two S-type compounds) were rapidly oxidizedby laccase (50- to 100-fold higher V_max values than the G-typephenols acetovanillone and vanillin) and were also found tobe the most rapid and efficient enzyme mediators. However, neithersyringol nor syringic acid, two other S-type phenols, were aseffective as the corresponding ketone and aldehyde. This wasdue to other factors influencing the oxidation rate by laccase,especially the pK_a, since phenol oxidation to a phenoxy radicalis favored by the presence of the phenolate form (13). In thisway, syringaldehyde and acetosyringone possess lower pK_a values(7.34 and 7.88, respectively) than syringic acid (9.49 for thephenolate) and syringol (9.98) which promote faster oxidation(40).

Dye oxidation by phenol radicals.
The specificity of mediators towards different functional groupsmust also be taken into account in laccase-mediator reactions.For example, laccase-ABTS is not reactive towards benzylic ethersor alkylbenzenes, but it is effective on benzyl alcohols (2,10), and oxidized HBT and VIO also seem to be more competenttowards some specific groups (2, 45). In the present study,we obtained different decolorization rates depending on thetype of dye and mediator used. Thus, p-coumaric acid efficientlymediated Azure B decolorization but was unable to decolorizeAniline Blue. In contrast, syringaldehyde was not very effectiveon Azure B but was highly efficient on the other dyes. Finally,acetosyringone seemed to be highly competent to mediate theoxidation of all dyes tested. Recently, two different mechanismsfor the oxidation of nonphenolic compounds by laccase-mediatorsystems have been proposed: (i) an electron transfer route formediators such as ABTS and (ii) a radical hydrogen atom transferroute for mediators of the -NOH- type (2). It is very likelythat the phenoxy radicals formed during the oxidation of naturalmediators by laccase act similarly to the -NO·- radicalsfrom -NOH- compounds, i.e., they extract a hydrogen atom fromthe substrate (13). Therefore, the dissociation energy of thecorresponding bond should govern their reaction with the laccasemediators.

The feasibility of the laccase-mediator systems depends on theredox reversibility of the reaction of the radical with thesubstrate as well as on the balance between the stability andreactivity of the mediator radical which, in addition, shouldnot inhibit the enzyme activity. The two former conditions havebeen confirmed with acetosyringone, since voltametric and electronparamagnetic resonance studies have shown the true reversibilityof the substrate reaction (19) and the long half-life of itsphenoxy radical (35). In contrast, the -NO·- radicalfrom HBT inactivates laccase, and due to its high reactivity,decays rapidly to benzotriazole and other inactive compounds(30). As mentioned above, syringaldehyde and acetosyringoneare more easily oxidized by laccase than are vanillin and acetovanillonedue to their lower redox potentials (their pK_a values are verysimilar). These two S-type phenols also form more stable radicalsdue to the presence of two methoxyl groups on the aromatic ringthat prevent the formation of biphenyl-type structures by radicalcondensation, as produced after the laccase oxidation of G-typephenols. The higher stability of acetosyringone (and also syringaldehyde)phenoxy radicals in slightly acidic aqueous media (6) explainswhy dye decolorization in the presence of this mediator wasbetter at pH 5, despite the optimal oxidation by the enzymeat pH 3.

Conclusion.
After natural mediator screening and an evaluation of the chosenmediators' performances on different types of dyes (using lowmediator concentrations), we concluded that several lignin-derivedphenols (such as syringaldehyde and acetosyringone) representecofriendly alternatives to synthetic (including -NOH- type)mediators for laccase degradation of different types of dyesand other recalcitrant compounds in terms of both efficiencyand velocity of oxidation.

ACKNOWLEDGMENTS

This work was supported by a CSIC-ENCE contract, the SpanishBiotechnology Programme (BIO 2002-1166), and EU project QLK3-99-590.S.C. was supported by an R&C contract of the Spanish MEC,and D.I. was supported by an I3P fellowship of the Spanish CSIC.

We thank Novozymes (Bagsvaerd, Denmark) and Beldem (Andenne,Belgium) for preparations of laccases from T. villosa and P.cinnabarinus, respectively.

FOOTNOTES

* Corresponding author. Mailing address: Centro de Investigaciones Biológicas, CSIC, Ramiro de Maeztu 9, E-28040 Madrid, Spain. Phone: 34 918373112. Fax: 34 915360432. E-mail: susanacam{at}cib.csic.es.

REFERENCES

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