Abstract
Protein engineering has emerged as an important tool to overcome the limitations of natural enzymes as biocatalysts. Recent advances have mainly focused on applying directed evolution to enzymes, especially important for organic synthesis, such as monooxygenases, ketoreductases, lipases or aldolases in order to improve their activity, enantioselectivity, and stability. The combination of directed evolution and rational protein design using computational tools is becoming increasingly important in order to explore enzyme sequence-space and to create improved or novel enzymes. These developments should allow to further expand the application of microbial enzymes in industry.
Copyright 2010 Elsevier Ltd. All rights reserved.
Publication types
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Research Support, Non-U.S. Gov't
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Review
MeSH terms
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Archaeal Proteins / chemistry
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Archaeal Proteins / genetics
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Archaeal Proteins / metabolism*
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Bacterial Proteins / chemistry
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Bacterial Proteins / genetics
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Bacterial Proteins / metabolism*
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Computational Biology / methods
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Directed Molecular Evolution
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Enzyme Stability
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Enzymes / chemistry
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Enzymes / genetics
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Enzymes / metabolism*
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Fungal Proteins / chemistry
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Fungal Proteins / genetics
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Fungal Proteins / metabolism*
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Mutant Proteins / chemistry
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Mutant Proteins / genetics
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Mutant Proteins / metabolism
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Protein Engineering / methods*
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Recombinant Proteins / chemistry
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Recombinant Proteins / genetics
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Recombinant Proteins / metabolism
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Substrate Specificity
Substances
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Archaeal Proteins
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Bacterial Proteins
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Enzymes
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Fungal Proteins
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Mutant Proteins
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Recombinant Proteins