Physicochemical characterization, structural analysis and homology modeling of bacterial and fungal laccases using in silico methods

Laccases from various sources like higher plants, fungi as well as bacteria are known to have wide range of applications in various industries such as paper, textile and beverage. This enzyme is extensively studied because of its vital role in bioremediation, biosensors and diagnostics. Phylogenetic...

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Published in:Network modeling and analysis in health informatics and bioinformatics (Wien) 2015-12, Vol.4 (1), p.17, Article 17
Main Authors: Tamboli, Asif S., Rane, Niraj R., Patil, Swapnil M., Biradar, Shivtej P., Pawar, Pankaj K., Govindwar, Sanjay P.
Format: Article
Language:English
Subjects:
Applications of Graph Theory and Complex Networks
Automation
Bacteria
Bioinformatics
Bioremediation
Biosensors
Casein
Casein kinase II
Catalysis
Computational Biology/Bioinformatics
Computer Science
Dermatitis
Enzymes
Fungi
Health Informatics
Homology
Kinases
Laccase
Myristoylation
Original Article
Oxidation
Phosphorylation
Phylogenetics
Phylogeny
Protein kinase C
Protein structure
Proteins
Pseudomonas putida
Secondary structure
Structural analysis
Trees
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Summary:Laccases from various sources like higher plants, fungi as well as bacteria are known to have wide range of applications in various industries such as paper, textile and beverage. This enzyme is extensively studied because of its vital role in bioremediation, biosensors and diagnostics. Phylogenetic analysis of retrieved sequences of laccases from selected bacteria and fungi inferred variation in sequences and these laccases were grouped independently. All laccases of selected organisms are acidic showing computed pI 
ISSN:2192-6662
2192-6670
DOI:10.1007/s13721-015-0089-y