Abstract
An analysis of the scientific literature published in the last 10 years reveals a constant growth of laccase applicative research in several industrial fields followed by the publication of a great number of patents. The Green Chemistry journal devoted the cover of its September 2014 issue to a laccase as greener alternative for chemical oxidation. This indicates that laccase “never-ending story” has found a new promising trend within the constant search for efficient (bio)catalysts able to meet the 12 green chemistry principles. A survey of ancient and cutting-edge uses of laccase in different industrial sectors is offered in this review with the aim both to underline their potential and to provide inspiration for new ones. Applications in textile and food fields have been deeply described, as well as examples concerning polymer synthesis and laccase-catalysed grafting. Recent applications in pharmaceutical and cosmetic industry have also been reviewed.
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Introduction
First uses of laccases in industry date back to 1990s [1, 2]. Since then, a careful study of reactions catalysed in vivo by fungal laccases has led to the discovery of an ever-increasing number of biotechnological applications reaching a peak in the last 10 years.
Laccase-catalyzed oxidation gives rise to radical species that can evolve towards both synthetic and degradative processes. Radical fate can follow three different pathways depending on many factors (Fig. 1). Oxidative coupling (1) is the main mechanism leading to homo- or cross-coupling of molecules resulting into dimers and/or also polymeric species. Such synthetic route translates in vitro into biotechnological applications in dye and polymer synthesis and grafting for surface functionalization. On the other hand, depending on their stability and redox reversibility, radicals may undergo rearrangement per se, yielding dead end products (2), or, in the third option (3), act as mediators for further oxidation of non-phenolic compound causing bond cleavage. The latter two kinds of laccase actions can be reproduced in vitro into biotechnological applications such as bleaching technology, and bioremediation.
This review focuses on some emerging trends of laccase uses covering textile, food, pharmaceutical and cosmetic fields. Examples concerning polymer synthesis and laccase-catalyzed grafting have also been reviewed.
Textile industry
Among the explored industrial fields, laccases have found wide applications in several sectors of textile industry, where these enzymes have been integrated in already existing processes such as fiber bleaching and dyeing and are also emerging as important “green tools” to modify and/or improve textile properties. Bioremediation of textile wastewaters also occupies a wide slice of laccase applications, although it has not been reviewed in this paragraph.
Fiber biobleaching
Removing of natural pigments, other non-cellulosic matter and impurities from cellulosic material before fiber dyeing and finishing, a process termed bleaching, is a mandatory step in textile processing. Laccases have emerged as a fiber-preserving alternative to the most commonly used bleaching agent, hydrogen peroxide [5, 6]. When combined with hydrogen peroxide produced by glucose oxidase, laccase treatment of linen fabric resulted into effective whiteness increase and modification of amount and type of lignin surface functional groups [7]. A synergistic effect on oxidation/removal of the natural coloring matter of cotton has been observed coupling laccase with ultrasound treatment, the latter allowing an improved diffusion of the enzyme throughout the textile structure [8]. Enhanced bleaching efficiency by a combination of laccase and ultrasound treatment has been also verified on linen fabrics. In this study, the time/dye uptake isotherms were also enhanced after combined bleaching treatment [9]. More recently, a pilot reactor for laccase–hydrogen peroxide cotton bleaching assisted by ultrasound was scaled up and efficiently applied to fabrics treatment [10]. In addition, Tian and coworkers [11] developed what they called the “green” short-flow process to treat cotton fabric in an energy-saving way. The process, combining hydrogen peroxide with laccase-mediated system (LMS) pretreatment allowed a lower dosage of H2O2, reduced bleaching temperature and shortened bleaching time.
By oxidizing the indigo dye on denim garments into uncolored compounds, laccase treatment has allowed obtaining the desired wash light effect on blue denim jeans without using harsh oxidative agents such as sodium hypochlorite. The use of laccases for denim processing dates back to 1996, when the first commercial laccase preparation DeniliteI™ was launched on the market by Novozyme. Since then, customized formulation of laccases has been developed to target specific garment wet process conditions, as deeply reviewed by Rodriguez-Couto [12]. Solis-Olba applied an LMS based on ABTS to denim decoloration, verifying that denim fibers were not damaged during the treatment and also the environmental impact of the process was reduced since denim decoloration residual water can be easily biodegraded [13]. Montazer and Maryan [14] verified that the combination of laccases with cellulases in denim processing helped to improve the lightness and decrease staining on both back of garment and on white pocket. An example of effective application of laccase treatment for stone washing effects of denim fabric without using a mediator has also been reported [15].
Functional modification of textile fibers
Laccases have also been used to attach functional molecules on textile fibers. Modification of protein fibers, such as wool and cotton, allows improving their properties. Water repellence is often associated to self-cleaning properties, antioxidant and antimicrobial features, which are desired qualities in finishing design.
Grafting of wool with the bi-functional phenolic compound nordihydroguaiaretic acid (NDGA) through a laccase-catalyzed reaction in an aqueous ethanol mixture improves wool properties [16]. NDGA grafting on wool provides antioxidant activity and is efficient in protecting wool against the undesirable photoyellowing caused by UV radiation, probably due to the formation of inter/intramolecular bridges and cross-links among wool proteins. Shrink resistance, crease recovery angle and tensile strength of the modified samples also increase compared to the untreated ones.
Antibacterial properties toward Bacillus subtilis and Escherichia coli were imparted to flax fibers and fabrics through laccase-assisted modification with ferulic acid or hydroquinone [17]. Antibacterial properties were also imparted to wool fibers by a laccase (Trametes sp.)-mediated grafting of lauryl gallate [18]. Recently, Silva and coworkers [19] exploited the ascomycete Myceliophthora thermophila laccase to oxidize flavonoids naturally existing in flax fibers, covalently binding the o-quinones formed to the amino groups of chitosan or/and to catechin. Antibacterial activity of linen samples grafted with both chitosan and catechin was tested against Staphylococcus aureus and E. coli. The latter showed susceptibility only to chitosan-treated samples, whereas S. aureus was equally sensitive to chitosan and catechin actions.
Fiber wettability has also been modified by laccase-assisted grafting of ad hoc selected molecules. Kim and coworkers [20] have reported the synthesis of laccase-catalyzed protein–flavonoid conjugates and following anchoring of conjugates onto cationized fibers. By the anchoring of α-casein–catechin conjugates onto flax fibers, the surface became hydrophilic, with a lower contact angle (48°). Wool water-repellent property was modified through an enzymatic coating of wool with lauryl gallate [18].
The exploitation of LMS for the anti-shrinking treatment of wool has been patented [21] and also investigated by Lantto and coauthors [22]. Although molecular reasons causing this effect have not been examined in depth, it seems probable that laccase action would promote intermolecular cross-links of wool fibers, thereby decreasing elasticity and thus reducing the tendency to shrinkage. More recently, Zhang and coworkers [23] have exploited a high-redox potential laccase from Aspergillus to prepare conductive cotton by laccase-catalyzed in situ polymerization of conductive polyaniline (PANI). Electrical properties of cotton, such as antistatic property and electromagnetic shielding effect, were significantly enhanced, highlighting the potential for using common textile materials in flexible electronic devices.
Textile dyeing
The use of laccases to synthesize colorants in situ has come out as a “green” way for textile dyeing at mild process conditions. Laccase-mediated coupling and grafting reactions have also been used for coloring various textiles [17, 24–29]. In the first attempt of cellulose textiles dyeing by Hadzhiyska and coworkers [25], cotton cellulose was dyed in situ by a polymeric dye generated by oxidative coupling of colorless 2,5-diaminobenzenesulfonic acid (DABSA) and 1-hydroxyphenol (catechol) with laccase-treated fibers, obtaining up to 70 % of dye fixation. However, it has been reported that all fabrics showed high wash fastness but low light and friction resistance. Schröder and coworkers [17] used a response surface methodology (RSM) approach to determine the best conditions for laccase-induced coating of flax fibers and fabrics by a Trametes hirsuta laccase. Different phenols have been analyzed for their potential as monomers for enzyme-catalyzed polymerization: all the methoxyphenols showed different coloration with weak fastness properties. Kim and coworkers [26, 28] have reported the utilization of the natural flavonoids present in the cotton as anchors to attach other phenolic compounds to the fiber surface. A T. hirsuta laccase was used to catalyze the oxidation of flavonoids in solution producing quinines, further polymerized and grafted onto surface of the cotton, providing a yellow to brown coloration, depending on the external flavonoids used and on the reaction conditions. The natural flavonoids present in the cotton were found to play an important role on the grafting reaction, improving dyeing and color fastness. The washing and friction fastness test of flavonoids colorized cotton showed good results confirming the feasibility of this new and promising coloration technique. An important improvement in the wet rubbing fastness of the dyed sample has been observed by Blanco and coworkers [29]. In their work, there is a covalent fixation of the in situ generated polymeric pigment. Aromatic amine moieties of DABSA introduced onto tosylated cotton were coupled and copolymerized with a catechol into colored product covalently fixed on the fabric upon oxidation with laccase. The controlled amination of cellulose in a first step, and the subsequent coloration allowed for up to 95 % pigment fixation on the fabric. Tzanov and coworkers [24] have also proved the ability of laccases for wool dyeing. They used a dye bath prepared with a dye precursor (DABSA), dye modifiers (catechol and resorcinol) and laccase, in the absence of any dyeing auxiliaries, carrying out the reaction at pH and temperature values safe to the wool material. Furthermore, they have shown that by prolonging the contact time between wool, enzyme, precursor and modifier, deeper colors were obtained in contrast to the conventional process, where deeper colors are attained by increasing the amount of dye.
In situ laccase-assisted overdyeing using catechol and catechin as dye precursors has been reported by Guimares [30]. Laccase-generated polymers gave rise to new coloration states from dark brown to green-yellow and replaced dyes in the overdyeing process. Through this process, overdyeing of denim was successfully achieved with acceptable levels in terms of durability. Also leather was colored by laccase action using dihydroxynaphthalenes as substrates [27]. The colored products are lightfast and bound to the natural collagen by a covalent tanning manner.
New routes for dye synthesis
Textile dyes occupy an important fraction of chemical industry market. Although consumption of dyes by the textile industry already accounts for two-thirds of the total dyestuff market, recent world dyes and organic pigments industry have estimated a further 3.5 % annual growth for the period 2013–2018 [31]. Due to their toxicity and the harsh operative conditions required for their synthesis, this growth of demand has been accompanied by stringent legislation regarding removal of dyes from industrial effluents and has encouraged the development of eco-friendly processes for their disposal as well as for their synthesis. In this scenario, laccases have shown to play a pivotal and double role: being efficient biocatalysts for biodegradation of synthetic dyes and attractive enzymes for coupling reactions leading to the production of new colored products. Laccase-mediated remediation of textile wastewaters has not been reviewed in this paragraph.
Laccases are known to synthesize many natural compounds in nature, through oxidative coupling reactions. This ability can be translated in vitro into powerful synthetic routes towards new colored natural products. Small colorless aromatic compounds such as phenols, aminophenols, diamines are oxidized by laccase to aryloxy radicals, which may undergo further non-enzymatic reactions leading to formation of colored products [32]. Experimental evidence has shown that laccase is able to catalyze the formation of colored products (from yellow/brown to red and blue) by oxidation of benzene derivatives containing at least two substituents (comprising amino, hydroxyl, and methoxy groups) [32, 33]. Thus, derivatization of various phenolic and non-phenolic substrates may represent a strategy to expand the range of these potential precursors. Presence of mediators has been shown to promote color formation, such as in the case of trimerization of indole with formation of a yellow compound in the presence of 2,2,6,6-tetramethylpiperidin-1-yloxy (TEMPO) [34]. Also, inorganic polyoxometalates have been found to act as better mediators than the organic one, 1-hydroxybenzotriazole (HBT) in the laccase-catalyzed synthesis of polycatechols, assuring better flax coloration, color fixation and resistance [35]. A variety of secondary amines characterized by biologically activities and intense colors were obtained during C–N coupling of 3-methylcatechol with different primary linear, branched-chained and cyclic amines, mediated by both native and recombinant laccases [36]. Phenoxazinones are also another class of compounds with excellent coloring properties, non-toxic and obtainable through laccase-catalyzed oxidation of many aminophenolic compounds [37–39]. Azo-dyes, by far the most important class of commercial dyes, have been synthesized by oxidative coupling reaction between different substrates [40, 41]. In an interesting example, Enaud and coworkers [42, 43] synthesized a novel azo-dye containing two sulfonated anthraquinonic chromophores by a laccase immobilized on an inexpensive carrier. The acid dye obtained is neither cytotoxic nor mutagenic demonstrating good dying properties in polyamide fibers.
Food industry
Food industry benefits from laccase application in different sectors and for multiple purposes: from modification of food sensory parameters and texture to improvement of products shelf-life and determination of certain compounds in beverages. As a fact, many laccase substrates, mostly phenols, thiol-containing proteins and unsaturated fatty acids are fundamental components of various foods and beverages, thus their modification may lead to new functionalities, quality improvement and cost reduction [44].
Baking industry
Application of laccases in baking process has been first reported by Labat et al. [45] describing laccase ability to cross-link arabinoxylans (AX) matrix in dough through dimerization of the esterified ferulic acid, causing increased strength, stability, and reduced stickiness of dough, and thus resulting into its improved machinability. In addition, an increased volume and improved crumb structure and softness of the backed products have been observed. Enhancement of maximum resistance and decreased extensibility has been obtained by laccase treatment of both flour and gluten doughs [46]. The hardening effect was higher in flour dough, where laccase action is prevalent on AX fraction, with respect to gluten dough, where laccases react with gluten protein matrix with less efficiency. Similar results have been obtained on gluten-free oat flour, where laccase treatment was shown to not affect oat globulins [47]. Prolonged incubation with laccase caused softening phenomena, probably due to radical-catalyzed break-down of the cross-linked AX network [46]. Firmness of fresh oat bread and tightness of wheat dough were found to be increased after laccase treatment, as a consequence of the reduction of water-extractable arabinoxylan (WEAX) content following AX cross-linking [48]. When combined with xylanases, laccase treatment further improved textures of both oat and oat–wheat breads [48]. Coupled laccase and protease supplementation, combined with endo-β glucanase side activity of the laccase preparation, also improved bread-making performances. In this case, the effect of hydrolytic activities prevailed over laccase promoted protein cross-linking, by reducing the formation of globular aggregates and positively affecting flour pasting properties [49].
Food sensory parameters
Consumer’s perception of the quality of a food product is strictly influenced by its exterior aspect and odor. Laccases have been applied to the improvement of food sensory parameters by acting on processes affecting physico-chemical deterioration of food products, or enhancing their flavor and taste properties.
Tsuchiya et al. [50] have patented the use of a recombinant laccase and cholorogenic acid to control the malodor of cysteine in different products, including foodstuff. They have shown that enzymatically treated cysteines have a reduced H2S-related smell with respect to untreated ones.
Laccase-catalyzed deoxygenation of vegetable oils has been shown to prevent oxidation of linoleic and linolenic acids responsible for generation of undesirable volatile compounds [51]. The authors have also demonstrated that addition of flavoring agents, such as anthocyanin, a spice, and other phenolic compounds available as food ingredients has a very positive influence on the deoxygenation rate by acting as laccase substrates too.
A method for enhancing color in tea-based foodstuff by the means of Pleurotus laccases has also been patented [52]. The oxidation step converted the colorless catechins in the leaves to a complex mixture of yellow and orange to dark brown substances, such as theaflavins and thearubigins. Also, cacao of superior taste and flavor has been obtained by treatment of cacao nib by Coriolus versicolor laccase [53]. Reduction of tannin content in cocoa pod husk after laccase treatment has been found to improve its nutritive value when used as ingredient for animal feeds [54].
Wine and beer stabilization
Wine stabilization is one of the main processes demanding laccases in food industry. Polyphenols in wine play a major role in determining aroma, color and taste of wine, which are strictly related to the particular phenolic composition. However, the same compounds are also the main actors involved in madeirization process causing turbidity, color intensification and aroma and flavor alteration. Laccase treatment aimed at reducing polyphenol content has been reported as an effective method to preserve wine quality, since the use of enzymes would selectively remove target-specific polyphenols without undesirably altering wine’s organoleptic characteristics. Laccases fit well with process requirement, due to their stability in acidic medium and reversible inhibition with sulfite [55]. Although the efficiency in polyphenol removal has been demonstrated, many authors underlined the need to add supplementary steps to wine production process, such as sulfur treatment, clarification and filtration to remove the oxidized products produced by laccase [56]. Other authors have also confirmed the potential of laccases in pre-fermentative treatment when coupled with conventional clarifiers such as proteins and polyvinylpyrrolidone (PVPP) [56]. Differential selectivity in phenol removal has been highlighted by Minussi et al. [57] in the treatment of red and white wines. Red wine treatment reduced phenolic compounds but mainly affected those responsible for the must antioxidant properties. On the other hand, treatment of white wines has shown higher reduction in total phenols than in the total antioxidant potential, resulting into reducing processing costs and increased storability of white wines.
Another negative aspect connected to wine storage is the characteristic cork off-flavor imparted to wine in contact with cork stoppers, which is related to phenols naturally present in cork and/or produced by microbial degradation. The use of laccase for the treatment of cork stoppers for wine bottles has been patented as an effective method to reduce the cork taint by phenols oxidation [58].
Similarly, the addition of laccase to fermented beer has been shown to improve its storage stability by scavenging the oxygen, which is responsible for the development of catty taint in bottled beer through reaction with fatty acids, amino acids and proteins [59]. Laccase treatment reduces the excess of naturally occurring proanthocyanidines and polyphenols that cause protein precipitation and therefore haze formation in beer [59].
Fruit juice clarification
Analogously to what happens during wine storage, phenols naturally occurring in fruit juices undergo interaction with proteins resulting into formation of haze or sediments. In addition, juice browning also imputable to both enzymatic and chemical oxidation phenomena involving phenols turns out into a final product which is less appealing to the consumers. Several authors have proposed the use of laccases as stabilizing agents, due to their ability to oxidize most of phenols in juices. Contradictory results have been published. Sammartino et al. [60] demonstrated that enzymatically treated apple juice was less stable than the one stabilized by conventional methods. Also, laccase treatment increased susceptibility to browning during storage [61, 62]. On the other hand, effective phenol removal and improved juice stabilization have been reported [56]. When laccase treatment was followed by a filtration step, juice quality could be highly improved [63, 64]. Neifar et al. [65] coupled a laccase treatment of pomegranate juice optimized by RSM with ultrafiltration, obtaining a reduction of polyphenol content and antioxidant capacity, but a concomitant increase of clarity of about 30 % versus untreated juice. More recently, Gassara-Chatti [66] has utilized a formulation of ligninolytic enzymes from Phanerochaete chrysosporium encapsulated in polyacrylamide hydrogel for clarification of mixed juice of berry and pomegranate, resulting in a significant polyphenolic reduction and clarity amelioration with respect to treatment with free enzymes.
Value-added food products
Laccases have been applied to enzymatic gelation of sugar beet pectin (SBP), a food ingredient capable of generating gels after oxidative cross-linking of ferulic acid [67]. Such kinds of gels are of particular interest in food industry due to their thermo-irreversibility, allowing a foodstuff to be heated without losing its gel structure. When added to three different food products, black currant juice, milk, and chopped heat-treated meat emulsion, gelation occurred in all the cases, although in the first two some unwanted side effects occurred [67]. Laccase-induced gelation of SBPs has been found to be highly related to molecular weight, acetylation and methylation degree of different pectin preparations [68]. Moreover, gelling rate and mechanical properties of laccase-induced gels have been proved to be greatly dependent on the amount of laccase activity used: higher enzymatic activity promoted the formation of softer gel due to the short reaction time available for the right arrangement of molecules. On the contrary, lower activity levels assured the formation of correct and permanent cross-links and led to a more rigid gel [68].
Another interesting application demanding laccases concerns the improvement of the stability of globular protein-coated lipid droplets to environmental stresses. As a fact, such kinds of emulsifiers are widely utilized in food industries, although their application is restricted to a limited range of matrixes because of their sensitivity to changes in pH, ionic strength and temperature. Laccases have been found to increase emulsion stability of oil droplets coated by multilayered biopolymer interfaces by promoting cross-linking among β-lactoglobulins in the primary interfacial layer as well as among beet pectin molecules constituting the secondary adsorbed layer. Also protein–polysaccharide cross-links between layers could be responsible for the observed increased emulsion stability to salt in a wider pH range [69]. Laccases also catalyzed the cross-linking of interfacial layers in multilayered oil-in water emulsions obtained by electrostatic deposition of pectin onto a fish gelatin interfacial membrane [70]. Cross-linking occurred exclusively in the layers and not between droplets, since no aggregates were formed. Resulting emulsions were characterized by enhanced stability in a broad pH range (3.5–10). In another example, oil-in water emulsions coated by laccase-mediated cross-linked sugar beet pectin were characterized by smaller and well-dispersed droplets improving their long-term stability [71].
Ma et al. [72] used laccase for the cross-linking of whey protein isolates (WPI) to improve their emulsification properties. Chemically modified and enzymatically treated WPI has been shown to enhance storage stability of WPI-stabilized emulsions. More recently, a mixed solution of WPI, SBP and laccase was microemulsified as nanodroplets in an organic phase [73]. Caffeine was encapsulated into the nanodroplets as a model compound to test their applicability as vehicles for drugs and/or nutraceuticals. Although stable conjugated particles of spherical shape and nanoscalar size were obtained, the authors recommended this method for encapsulation of non-oxidative nutraceuticals and biomaterials since antioxidants such as caffeine may counteract with the oxidizing action of laccase during cross-linking of biopolymers.
Laccase-mediated cross-linking of food proteins has also been used to develop added-value products in the food industry [71, 74], as well as to influence protein digestibility and reduce their allergenicity [75, 76]. β-Lactoglobulin (BLG), accounting for approximately 10–15 % of total milk proteins, is an important nutrient of dairy products and, at the same time, one of the major milk allergens causing serious health risk in cow’s milk-allergic patients [77]. A Trametes versicolor laccase has been used to cross-link BLG phenolic groups in the presence of a sour cherry extract as a natural source of phenolic mediators [76]. Enzymatic processing by cross-linking may be used to tailor BLG properties, by improving its safety and facilitating its digestibility, while conserving beneficial health effects, such as the radical-scavenging activity of peptides released during enzymatic digestion.
Compound detection in beverages
Different biosensors based on laccases have been developed to measure polyphenols in food products, such as wine, beer and tea. Effective potential of a biosensor based on immobilized laccase has been first verified by Ghindilis et al. [78] for detection of tannin in tea of different brands. Since then, a lot of reports concerning the development of laccase-based biosensors have been published in the scientific literature. Laccases from different Trametes species were immobilized on carbon nanotube screen-printed electrodes for determination of polyphenols index in wines [79]. Reported data have shown that biosensor performance is dependent on the laccase source used. Ibarra-Escutia et al. [80] optimized an amperometric biosensor based on a T. versicolor laccase for monitoring phenol compounds in tea infusion. This biosensor displays an excellent stability in the operative conditions and exhibits good performances in terms of response time and sensibility, allowing accurate sample analysis without any pretreatment step. Also, a disposable biosensor was developed for phenol detection in tea infusions [81]. Finally, a bioelectronic tongue based on lipid nanostructured layers containing tyrosinases and laccases has been recently developed by Medina-Plaza and coauthors [82]. The enzymes have been incorporated into a biomimetic environment provided by a Langmuir–Blodgett film of arachidic acid. Lutetium bisphthalocyanine (LuPc2) has also been introduced in the films to act as electron mediator. This multisensory system discriminates phenols according to the number of phenolic groups attached to the structure as well as grapes of different varieties according to their phenolic content. A combination of factors contributes to the high performances of this biosensor: the high functionality of the enzyme obtained using a biomimetic immobilization, the signal enhancement caused by the LuPc2 mediator, the improvement in the selectivity induced by the enzymes and the complementarity of the enzymatic activities.
Laccase-mediated polymer synthesis
In the frame of industrial application, laccase ability to synthesize polymers is of outstanding importance. Indeed, polymeric materials are essential for everyday life, being present in many and different fields, such as food, textile, electronics, communications, transportations, pharmacy, and medicine [83]. Even if current polymer production schemes are highly optimized, the huge quantity of annually produced polymers demands a greener technology, particularly in the perspective of toxic formaldehyde reduction. Hence, it is not surprising that also enzymes are being engaged for polymer synthesis [83], being laccases and peroxidases dominating this field [84]. In a polymerization reaction, laccase achieves its natural work with the initial formation of radicals from a typical substrate (aromatic with hydroxyl group or groups). Then, radicals can undergo polymerization reactions towards homopolymeric materials [85]. It is also possible to create new heteromolecular hybrid molecules coupling a laccase substrate and a non-laccase substrate (variable reaction partner) [85] (Fig. 1). Radical polymerization lacks any control on the structure and morphology of the final product, thus if a defined molecule is pursued, it is necessary to find opportune reaction conditions, as reviewed by Hollmann and Arends [84]. Short reaction time, defined molar concentrations [86], presence of templates [87], substrate engineering [88, 89], and use of co-solvent [90, 91] are some of the more frequently applied strategies to obtain defined polymers.
Despite the proved capability, short-term implementation of enzyme-mediated polymer synthesis on industrial scale is still hampered by economic issues. However, the high efforts put in this field let foresee a fast revolution in polymer chemistry in the next decade.
Polymer synthesis by laccases has already been reviewed by different authors [83–85, 92, 93]; the aim of this paragraph is to underline those applications we believe more promising or more ready for a real industrial exploitation.
Flavonoids
Flavonoids are benzo-γ-pyrone derivatives consisting of phenolic and pyrane rings [94] endowed with biological and pharmacological effects, including antioxidant, anti-mutagenic, anti-carcinogenic, anti-viral and anti-inflammatory properties [95]. High molecular weight polyphenols have been reported to exhibit enhanced biological properties with longer circulation time in vivo [96]. As a fact, in the last decade it has been demonstrated that oxidative coupling of flavonoids generates polymers with increased antioxidant activity. Kurisawa and coworkers [97] have employed a Myceliophthora laccase to catalyze the oxidative polymerization of catechin—a flavonoid found in green tea and wine—in a mixture of a polar organic solvent and buffer. Polymer yield and composition were improved testing different solvent composition. When compared with monomeric catechin, the synthesized polymer exhibited significantly improved superoxide scavenging activity and xanthine oxidase (XO) inhibitory activity. Jadahav and Singhal [98] used a laccase conjugated to Arabic gum to perform catechin polymerization. Free laccase produced water-insoluble cross-linked oligomer, whereas conjugated laccase produced water-soluble linear oligomer endowed with high antioxidant activity and reducing power. An improved antioxidant activity if compared with the corresponding monomer has also been observed in the polymerization of quercetin and kaempferol with a laccase from Ustilago maydis [99]. More recently, the oxidative grafting of flavonoids to modify/impart polymer properties is gaining increased attention, as described in other sections.
Artificial urushi
“Urushi” is a Japanese traditional coating material showing excellent toughness, brilliance and solvent resistance for a long period in comparison with synthetic coatings. It is a natural resinous sap obtained by the Rhus vernicifera tree through the cross-linking of urushiol monomers [100]. The urushiol structure is a catechol derivative, with unsaturated hydrocarbon chain consisting of monoenes, dienes, and trienes at the 3-, or 4-position of catechol. In nature, the film forming of urushiols proceeds via laccase catalysis under air. It can be regarded as the only example of a practical natural paint that utilizes in vitro enzymatic catalysis for hardening [100]. New urushiol analogs were developed to overcome the difficulty to chemically synthesize natural urushiols [101, 102]. “Artificial urushi” may be defined as the cross-linked film prepared by in vitro laccase-catalyzed oxidation of new urushiol analogs, in which the unsaturated group is connected with the phenolic group through an ester linkage. The artificial urushi prepared by laccase shows hardness and brilliance comparable to those of natural urushi [100–102].
Conducting polymers
Conducting polymers, such as polyaniline (PANI), polythiophene (PEDOT), and polypyrrole (PP), have attracted a great attention in the last years.
PANI is regarded as one of the most important conducting polymers. Due to its good electrical and optical properties, as well as its high environmental stability, it can be used as active component of organic lightweight batteries, microelectronics, optical display, for anticorrosive protection, in bioanalysis, etc. [83]. PANI is commonly synthesized by chemical or electrochemical oxidation of aniline monomer under very harsh conditions and yielding a product with a poor solubility in common solvents [83]. Among all the forms of PANI only the emeraldine salt is conductive, and it is usually obtained from the emeraldine base via protonation of its imine sites in acidic conditions (doping) [103]. Problems concerning reaction conditions and PANI solubility can be overcome thanks to biotechnology, e.g., PANI can be enzymatically synthesized by oxidoreductases (glucose oxidase, peroxidase, laccase) in the presence of templates. Many studies deal with the use of peroxidases, but more recently also laccases are increasingly being used, thanks to their ability to work using only air (dioxygen) as cofactor [83]. When PANI polymerization is conducted in the absence of templates, extensive branching is observed and this is not desirable for conducting materials. Besides sulfonated polystyrene (SPS), the first used template in laccase-mediated PANI synthesis [104], many other templates have been used, such as other negatively charged polymers [105, 106], negatively charged micelles [23, 107–110], and negatively charged vesicles [111]. Shumakovich and coworkers [106] have performed a comparison of chemical and enzymatic methods of aniline polymerization. The high-redox potential T. hirsuta laccase was used in the synthesis of polyaniline in the presence of poly(2-acrylamido-2-methyl-1-propanesulfonic acid) (PAMPS) as template. PANI nanoparticles obtained by the two methods are morphologically distinctive. In addition, the mechanism of enzymatic aniline polymerization differs from that of the chemical synthesis. The latter proceeds with a significant induction period, which is not observed in the laccase-catalyzed reaction. With the aim to repeatedly use the enzyme, Vasileva and colleagues [105] used an immobilized laccase on CM cellulose to perform PANI synthesis in the presence of PAMS as template. The conductance of the interpolymer complex synthesized using the immobilized laccase is close to the value of PANI synthesized using the free enzyme, and comparable with the value of the chemically obtained PANI. During recent years, great interest has been given to the synthesis of chiral conducting polymers because they are very promising for practical application in different fields, e.g., for creating surface-modified electrodes, electrochemical asymmetric synthesis, chiral chromatography, and chiral membrane separating technology [112]. A fungal laccase from T. hirsuta was used for the synthesis of chiral polyaniline in the presence of optically active compounds, either in a homogeneous way (in the bulk solution) and heterogeneous one (on the surface of glass slides, in situ synthesis). The optical activity of the enzymatically synthesized polymer in the doped and de-doped forms was confirmed using Circular Dichroism spectroscopy. When the low redox potential laccase from R. vernicifera was used for PANI polymerization, the presence of mediator was required to increase the rate of the reaction [110]. Conducting polyaniline synthesized by the LMS method is produced with a higher yield and displays five times higher conductivity than that obtained in the absence of mediator.
3,4-ethylenedioxythiophene (EDOT) has attracted significant attention in recent years since EDOT polymers (PEDOT) have demonstrated potential applications in organic field effect transistors, organic light emitting diodes and photovoltaic cells [113]. Due to high redox potential of the monomer, EDOT cannot be oxidized in the presence of only laccases, thus it is necessary to use a redox mediator. A T. hirsuta laccase was used in the presence of potassium octocyanomolybdate(4+) as high potential redox mediator to catalyze the reaction of EDOT oxidation and to perform synthesis of PEDOT using PAMPS as template. UV–vis and FTIR spectra confirmed the formation of water dispersible conducting polymer [113].
Polypyrrole (PP) is a biocompatible conducting polymer endowed with a high conductivity, stability in the conducting state, and interesting redox and electromechanical features [114]. An LMS based on a T. versicolor laccase and ABTS was used for the synthesis of PP [115]. The presence of ABTS increased the rate of the reaction and allowed to produce oligomers with higher molecular weight with respect to those obtained without mediator. The conductivity of these polymers, both with and without ABTS, is similar to that of PP prepared electrochemically or chemically.
New materials
The recent synthesis of a novel photoluminescent material [116] is herein cited as a symptomatic case of viable future chances given by laccase-mediated polymer synthesis. A T. versicolor laccase was used for the oxidative polymerization of 4-fluoroguaiacol in the presence of 30 vol % organic co-solvent [108]. The novel synthesized material displays fluorescence with emissions in blue, green and red, thus it may be used as a component in optoelectronic devices. Obtained results have also led to demonstrate that the coupling of the repeated units proceeds by defluorination to attain oxy-phenol propagation with coupling by the C4 phenyl carbon.
Polymer grafting
Polymers with new and/or improved properties can be obtained not only by new synthetic routes, but also modifying existing polymers with selected molecules, using the so-called grafting technology [31, 93, 117]. Coupling of low-molecular weight molecules to polymers can be achieved through functional groups located at the polymer terminal, in the main chain or in the side chain [83]. This enzymatic modification of existing materials, yielding products with modified properties, has an immense potential in different industrial sectors, such as food, textile, pulp and paper, wood, and also cosmetic to a lesser extent. In this paragraph, selected cases of polymer modification of lignocellulosic materials will be reviewed, since examples of grafting in other fields are described in the corresponding sections (“Functional modification of textile fibers”, “Textile dyeing”, “Baking industry”, “Value-added food products”, “Pharmaceutical and cosmetic industries”).
Lignocellulosic materials
Laccase-mediated polymer modification covers different aspects in the pulp and paper industry. The potential of laccase-assisted biografting of phenolic acids for improving strength properties of kraft paper made from high kappa pulps is discussed in several papers [112–124]. The main focus of Chandra studies has been the grafting of phenolic acids to high-lignin content softwood kraft fibers mediated by a Trametes villosa laccase [118–122]. Results indicated that improvements of hydrogen bonding between fibers and creation of phenoxy radical cross-links within the sheets increased paper strength [122]. Recently, Witayakran and Ragauskas [123] have investigated the possibility of grafting various amino acids onto high-lignin content pulps obtaining an increasing of carboxyl group content and paper properties. The ability to use laccases to selectively graft amino acids to lignin-rich pulp fibers provides a new and unique fiber modification technology which will have many future opportunities. In most cases, treatment of flax and sisal pulp with laccases (from Pycnoporus cinnabarinus and T. villosa), with or without a mediator, in the presence of different phenolic compounds, improved strength-related properties (particularly wet tensile strength) in the resulting paper [125–128].
Recently, there has been an increase in innovative research aimed at developing functional packaging material with antimicrobial properties [129, 130]. Several bioactive phenolic compounds (acids, essential oil components and dopamine) were grafted onto the surface of unbleached kraft liner fibers using a laccase from T. pubescens [129]. Obtained results have shown that the handsheet papers obtained by laccase antibacterial surface process (LASP) display a greater efficacy against gram-positive and gram-negative bacteria, if compared with paper treated only with monomeric phenol derivatives. Antimicrobial activity was proved to be function of grafted structure, time of the treatment and concentration of phenol derivatives. Among the tested essential oil compounds, isoeugenol is the most effective: isoeugenol/LASP, besides killing S. aureus, displays a bacteriostatic effect on the more resistant spore forming gram-positive Bacillus subtilis. A P. cinnabarinus laccase was used to initiate the grafting of three different antimicrobial phenol structures (syringaldehyde, acetosyringone and p-coumaric acid) onto unbleached flax fibers with a high cellulose content [130]. Grafted pulps presented high antimicrobial activity against three bacteria analyzed (S. aureus, Pseudomonas aeruginosa and Klebsiella pneumoniae).
Wood (Picea abies) veneers and pulp were treated with tannins, as natural antibacterial phenols, in the presence or absence of commercial M. thermophila laccase with the aim to impart antibacterial properties to the substrates [131]. The treatment in the presence of laccase significantly improved the antibacterial resistance of veneers and paper made from tannin-treated pulp against S. aureus, while a more modest protective effect was observed against E. coli. Authors have also provided mechanistic evidence of the binding of catechin and gallic acid onto putative lignin monomers. Catechin was bonded to the phenolic molecules mainly through 5–5 linkages, while bonding to monomers with sinapyl units was mainly through 4–O–5 linkages. Bridging molecules such as 4-hydroxy-3-methoxybenzylurea, compatible with melamine resin, were attached to fiber lignin by means of laccase with the aim of boosting the disinfecting properties of phenol resin utilized for the impregnated kraft paper of certain environments where high hygienic requirements exist, such as hospitals and kitchens [132].
In an effort to use green chemistry technology to increase wood surface hydrophobicity, laccase-mediated grafting of pulps has been successfully tested. Fluorophenols and alkylamines were coupled, mediated by a T. hirsuta laccase, to complex lignin models to increase hydrophobicity of wood veneers [133–135]. The proposed mechanism has shown that the fluorophenols were bonded to sinapyl units via 4–O–5 linkages, while coupling to guaiacyl units occurred through 5–5 linkages. The alkyl amines were bonded onto simple phenolics and lignin models through the –NH2 thereby establishing a –C–O–N and a –C–N bond. The advantage of laccase-mediated covalent binding of molecules onto wood surface is that the grafted molecules are not readily displaced and released into the environment.
Several approaches of in situ laccase-created radicals in wood chips have been investigated as a way of producing binderless (artificial adhesive-free) wood such as Medium Density Fiberboards (MDFs) and Particle Boards (PBs), commonly used for interior building and furnishing [136].
Many attempts have been made at increasing bonding between the fibers or other constituent particles by their chemical modification. The activation of lignin for bonding can be carried out by oxidative enzymes [137–139]. Particularly, the auto-adhesion of beechwood (Fagus sylvatica) fibers was enhanced by a pretreatment of the fibers with a T. villosa laccase (Novozymes A/S) [139]. The mechanism of enzymatic catalyzed bonding is linked to the generation of stable radicals in lignin by oxidation. Fiberboards made from laccase-treated fibers have a high wet strength compared to boards made from untreated fibers. Furthermore, the surfaces of laccase-treated fibers have shown a markedly increased hydrophobicity, as well as a change in the chemical composition, indicating that lignin extractives precipitated on the fiber surfaces. Another approach to substitute synthetic resins in wood composite production is a two-component system in which laccase-treated technical lignin, such as kraft lignin or lignosulfonate, functions as the adhesive. This method has been applied to the production of PB [140–142], even if the use of water-soluble lignosulfonates generates products displaying poor dimensional stability [141]. A variant process has also been described where a laccase-oxidized lignin-based adhesive, with 1 % methylene diphenyl diisocyanate, resulted in PBs with doubled tensile strength and reduced swelling in water [143].
Other examples
Membrane fouling is a serious problem in membrane filtration due to adsorption of components from the feed [144]. Among other factors, also the (surface) material of the membrane affects adsorption. Poly(ether sulfone) (PES) is a popular hydrophobic material for membranes. A (more) hydrophilic membrane surface may reduce (or even prevent) adsorption [145]. A laccase-mediated grafting of PES with 4-hydroxybenzoic acid and gallic acid in controlled reaction conditions has proved to have clear potential for reduction of fouling by proteins, polysaccharides, and polyphenols, probably related to the more hydrophilic surface [146].
Pharmaceutical and cosmetic industries
Laccases can catalyze the synthesis of various therapeutics, such as antibiotics, antimicrobials and anti-cancer drugs. The usefulness of laccases for the amination of new antibiotics has been demonstrated. Many potential aromatic substituents of penicillins and cephalosporins are natural laccase substrates. Mikolasch and coworkers synthesized different novel β-lactam antibiotics (e.g., cephalosporins, penicillins and carbacephems) through laccase-catalyzed amination of amino β-lactams and 2,5-dihydroxyphenylacetic acid, 2,5-dihydroxybenzoic acid or catechols [147–150]. Novel cyclosporin analogs can be obtained through a laccase-mediated oxidation [151].
Recently, the laccase-catalyzed synthesis of anhydrovinblastine, mitomycin and structurally similar anti-cancer compounds has been reported. Anhydrovinblastine, useful in the leukemia treatment, was synthesized in a coupling process of catharine and vindoline [152, 153]. It has been demonstrated that laccases from M. thermophila and P. cinnabarinus synthesize 5-alkylamino- and 2,5-bis (alkylamino)-(1-4)-benzoquinones, structurally similar to mitomycin, a chemotherapeutic agent used to treat different cancers [154]. Synthesis of other anti-cancer molecules, such as aminonaphthoquinones and p-benzoquinone, has been, respectively, obtained in a monoamination and diamination laccase-catalyzed reaction [155, 156]. Moreover, laccases from different organisms exhibit cytotoxic or antiproliferative effects against the tumor cells, mainly MCF7 and Hep G2 [157–161].
Laccases from Tricholoma giganteum, Lepiota ventrisospora, Lentinus edodes, Pleurotus cornucopiae, Coprinus comatus, Lentinus tigrinus, Hericium coralloides, Agaricus placomyces, and Abortiporus biennis have been reported as inhibitors against HIV-1 reverse transcriptase activity [162–169]. Another laccase has been reported to possess the capability of fighting aceruloplasminemia, restoring the iron homeostasis [170].
Additionally, laccase application has been reported in the generation of iodine [171–174], a well-known antifungal compound, generally used as disinfectant. Laccases are also able to catalyze the formation of other antimicrobial compounds, such as the cinnabarinic acid [175], or to have antibacterial and antifungal activity themselves. Recently, Grover and coworkers have developed a laccase-nanotube-based paint, showing a bactericidal and sporicidal activity [176].
Furthermore, an increasing interest has been focused on laccase application in the cosmetics as a biocatalyst in the hair dye synthesis and in the formulation of personal hygiene products, including deodorant, toothpaste, mouthwash, detergent and soap. Laccase-based hair dying is an emerging field of research. Traditional chemical-based hair coloring products are often irritant, difficult to handle and not safe. Hydrogen peroxide (H2O2) and phenylenediamines are the most used chemicals in hair dying. They are allergenic and carcinogenic [177, 178] and can, respectively, cause severe hair damage [179, 180]. Laccase can act as an oxidizing agent, substituting H2O2. For this reason, laccase-based hair dyes are less irritant [181, 182]. Recent works have shown that laccase-catalyzed polymerization of natural phenols is applicable to the development of new cosmetic pigments [181]. A laccase from T. versicolor and natural plant-derived phenolic compounds have been used to produce a colorful array of eco-friendly dyes [183]. Jeon and coworkers [184] have studied laccase-catalyzed in situ polymerization of natural phenols to form products for hair dyeing. Three kinds of two-monomer combinations for gray hair dyeing were developed, namely, gallic acid/syringic acid, catechin/catechol and ferulic acid/syringic acid, generating brown, black and red colorations, respectively. Laccase polymerization of natural phenols can provide stable colored polymers, since color changes in all dyed hairs tested were negligible, even after repeated shampooing with detergent excess. The alkaline laccase secreted by Flammulina velutipes has been tested for hair coloring [185]. Lately, Chen and coworkers have proposed the laccase from the actinomycete Thermobifida fusca as an excellent thermo-alkali-stable laccase for hair coloring [186]. Fang et al. have demonstrated that the bacterial laccase Lac15D displays a constant activity toward dye precursors and their combinations under alkaline conditions, suggesting its application in hair coloring [187].
In the cosmetic field, laccases are also used for skin lightening [188, 189]. Laccases may not only find utility in the oxidative reaction, production of pigments and melanins, but also in the reduction of melanin-derived blemishes [190]. In addition, laccases can oxidize various thiols and other sulfur-containing compounds, responsible of malodor or even kill the microbes that generate offensive molecules [191]. For this ability, these enzymes have been introduced in deodorant for personal hygiene [192], oral care products [193] and soaps [194].
The importance of these oxidoreductases as efficient catalysts in cosmetic field is underlined by the increasing number of patents registered in the last years [195–209].
Conclusion
Figure 2 summarizes and classifies the scientific literature published in the last 10 years about implementation of laccases in several industrial fields. The trend is positive for most of the analyzed sectors, with applications in waste water treatment occupying the widest slice of published articles. Articles concerning modification of natural polymers such as lignin and cellulose with related applications in wood and paper industries also represent an important portion of the applicative research on laccases. Other emerging sectors are represented by laccase exploitation in biosensing and fuel cells industry, cosmetics, biopolymer synthesis and in food and textile fields. Also the use of laccases as green catalysts for the synthesis of high-added value organics is emerging as a new, although still poorly exploited, sector of applicative research.
The active research on potential laccase industrial applications has stimulated the publication of a great number of patents in several sectors. Figure 3 reports the relative percentage of patents distribution in different sectors, referred to the decade 2003–2013. The widest slice of patents concerns methods of fermentation and optimization of laccase production, followed by inventions about enzyme modification aimed at its conjugation and/or immobilization for different uses (enzymes category in Fig. 3a). Analyzing the distribution of patent owners (Fig. 3b), Novozyme (Novo Nordisk, Denmark) owns the most of the totality of patents (5 %), followed by L’Oreal with 3 %. The biggest slice of the pie graph (78 %) is occupied by companies or Research centers possessing less than 1 % of total number of published patents.
Despite this plethora of applications, laccase potential was not fully exploited, due to several issues mainly connected with the economy and the efficiency of the enzyme in the operating conditions. Recent efforts to abundantly produce these enzymes, to improve enzyme activity and/or stability through immobilization and protein engineering, are boosting laccase exploitation at industrial level. Since the first commercial product based on laccase enzyme, launched in 1996 by Novozyme (Novo Nordisk, Denmark), widespread companies have been engaged in producing this enzyme in several formulation and for different purposes, mainly for the textile and food industries [2]. Less enzymatic formulations are available for pulp and paper industries, probably for a kind of reserve towards the integration of enzymes in an “ancient” and consolidated process flow, such as paper production. Most of the new companies are located in the Asian continent, where, despite global crises, industry is expanding, probably also due to the less bureaucratic constraints for industrial production and lower salaries of employees in these regions [2]. On the other hand, the increasing demand of specific and eco-friendly alternative biocatalysts has nowadays induced, also in Europe, the creation of new small companies offering customized formulations of laccases to target specific process conditions.
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Acknowledgments
This work was supported by grants from the European project “Optimized oxidoreductases for medium and large scale industrial biotransformations, INDOX” (KBBE-2013-7-613549) and from the Italian MIUR (Ministero dell’Università e della Ricerca Scientifica Progetti di Rilevante Interesse Nazionale) PRIN 2009STNWX3. Cinzia Pezzella is recipient of a fellowship funded by POR Campania FSE 2007/2013 “Campania Research in Experimental Medicine, Project CREME” (CUP B25B09000050007).
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Pezzella, C., Guarino, L. & Piscitelli, A. How to enjoy laccases. Cell. Mol. Life Sci. 72, 923–940 (2015). https://doi.org/10.1007/s00018-014-1823-9
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DOI: https://doi.org/10.1007/s00018-014-1823-9