| Identification | Back Directory | [Name]
LACCASE | [CAS]
80498-15-3 | [Synonyms]
LACC
Sp 504
LACCASE
LACCASE T
LACCASE CV
LACCASE AB
EC 1.10.3.2
Laccase 001
Laccase 002
Laccase 003
Novozyme 809
Denilase ii s
laccase enzyMe
Laccase, liquid
Urushiol oxidase
LACCASE, >1 U/MG*
p-Diphenol oxidase
LACCASE, >1.5 U/MG*
PrimaGreen EcoFade LT
LACCASE, 4+ UMG POWDER
Laccase Agaricus bisporus
Laccase Coriolus versicolor
laccase from rhus vernificera
LACCASE T FROM TRAMETES SPEC.
Laccase from Rhus vernicifera
laccase from agaricus bisporus
laccase from coriolus versicolor
laccase from trametes versicolor
Laccase from Tramales versicolor
BENZENEDIOL:OXYGEN OXIDOREDUCTASE
LACCASE, CORIOLUS VERSICOLOR, CLEA
Laccase [recombinant, >=4 units/mg]
Laccase from Pleurotus ostreatus (mushroom)
LACCASE FROM TRAMETES SPEC., 0.8+ UMG POWDER
LACCASE FROM TRAMALES VERSICOLOR, 20+ UMG POWDER
LACCASE FROM TRAMALES VERSICOLOR, >20 U/MG*
LACCASE, CORIOLUS VERSICOLOR, CROSS-LINKED ENZYME AGGREGATE
Laccase from Rhus vernicifera,Benzenediol:oxygen oxidoreductase
L-Alanyl-L-valyl-L-α-aspartyl-L-α-aspartyl-L-α-aspartyl-L-alanyl-L-α-glutamyl-L-glutaminyl-L-isoleucyl-L-proline | [EINECS(EC#)]
420-150-4 | [Molecular Formula]
NULL | [MDL Number]
MFCD00131475 | [MOL File]
80498-15-3.mol | [Molecular Weight]
151.206 |
| Questions And Answer | Back Directory | [Description]
Laccase is a kind of copper-containing oxidase existing in many kinds of plants, fungi and microbes. It mainly takes effect on phenol-like compounds including phenols, polyphenols and anilines, performing one-electron oxidation. It is capable of catalyzing the ring cleavage reaction of aromatic compounds. In industry, laccase can be paired with an electron mediator to facilitate electron transfer to a solid electrode wire. It can also be applied to textile dyeing/textile finishing, wine cork making, teeth whitening with many other industrial, environmental, diagnostic, and synthetic uses. In food industry, laccase can be used to remove the polyphenols as well as oxygen that remain in the beer to increase the storage life of beer. Laccase can also be used in fruit juices to delay the oxidation of polyphenols and stabilize the juice.
| [References]
https://en.wikipedia.org/wiki/Laccase
http://172.16.24.174/digital.csic.es/bitstream/10261/9595/1/postprint_laccase_patent_review.pdf
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| Hazard Information | Back Directory | [Uses]
Laccases are multicopper-oxidases (benzenediol:oxygen oxidoreductase, EC
1.10.3.2) that are able to oxidize phenolic substrates (e.g. 2,6-dimethoxy-phenol),
aromatic amines (e.g. 1-hydroxybenzotriazole), or polycyclic aromatic hydrocarbons
(e.g. anthracene) . The oxidation of the substrate occurs via a oneelectron
reduction and is accompanied by a reduction of molecular oxygen to
water.
Most laccases are of fungal origin, but they also occur in bacteria, insects,
and plants. Due to the broad substrate range of laccases, their possible
industrial usage is widespread. Nevertheless, only few applications have been
commercialized up to now, mostly in the textile industry. In the food and feed
sector, laccases have been evaluated for different applications, such as the stabilization
of beverages, the reduction of off-flavors, the improvement of wheat
dough, and the usage of laccases as biosensors in the food processing industry.
Off-flavors in wine may occur due to microbial conversion of phenolic compounds
present in the wine itself or in the cork stoppers. In a commercial product
from Novozymes called Suberase, laccase is used for polymerization of phenolic
compounds in the cork, which act as precursors for malodors, such as pentachlorophenol
or 2,4,6-trichloroanisol.
In apple juice, addition of laccase reduced the amount of the phenolic offflavors
2,6-dibromophenol, guaiacol, and a-terpineol. Several studies used
laccases to increase the stability of apple juices by polymerization of phenols and
their subsequent removal by ultrafiltration methods. A positive side effect is
the decrease of molecular oxygen in the juice due to its consumption by laccases.
Nevertheless, desired phenols might also be oxidized; thus, the sensory attributes
and nutritional value might be altered.
The polymerization reactions catalyzed by laccases can also be used to improve
the shade of food, such as the coloration of tea-based products. In the bakery industry, laccase might be used together with proteases or xylanases to improve
the dough quality. It was proposed that laccases oxidize ferulic acid attached to the
arabinoxylan present in cereal flour. The obtained phenolic radicals can undergo a
nonenzymatic reaction, resulting in cross-linked feruloylated arabinoxylans.
In oat flour-based bread, the usage of laccase increased the loaf-specific volume
and decreased the crumb hardness. Contradictory, in another study, laccase
alone decreased the specific volume and increased the crumb hardness. A
combined usage of laccase with xylanase improved again the oat flour bread
properties. | [General Description]
Laccase EC 1.10.3.2, a glycoprotein, is an extracellular multicopper enzyme and is considered as a metal. Laccase is widely distributed in fungi and also found among the higher plants, bacteria and insects. | [Flammability and Explosibility]
Notclassified | [Biochem/physiol Actions]
Laccase oxidizes aromatic and nonaromatic compounds. Various compounds are used for detecting laccase production. These include guaiacol, syringaldazine and polymeric dyes like remazol brilliant blue-R. Laccase is involved in lignin degradation and thereby has industrial as well as food applications. Laccase is commonly used for delignification, dye bleaching, paper processing, waste detoxification, textile dye transformation, plant fiber modification and ethanol production. | [Biotechnological Applications]
Lee et al. isolated and identified an extracellular laccase-producing strain of Y. lipolytica from soil. Extracellular laccase (YlLac) was purified by anionexchange and gel filtration chromatography. YlLac is a monomeric glycoprotein with 14 % carbohydrate content and a molecular weight of 67 kDa. It showed a higher catalytic efficiency toward 2,20-Azino-bis (3-ethylbenzthiazoline-6-sulfonic acid) (kcat/Km = 19.3 s-1 lM-1) and 2,6-dimethoxyphenol (kcat/Km = 13 s-1 lM-1) than any other reported laccases. This enzyme was able to oxidize phenolic compounds of pretreated rice straw. The use of YlLac for the removal of cellulase inhibitory compounds from biomass slurries is a promising approach for improving the efficiency of biorefineries (Lee et al. 2012). |
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