LICRED: A Versatile Drop-In Vector for Rapid Generation of Redox-Self-Sufficient Cytochrome P450s
Cytochromes P450 (P450s) are a family of haem-containing oxidases with considerable potential as tools for industrial biocatalysis. Organismal genomes are revealing thousands of gene sequences that encode P450s of as yet unknown function, the exploitation of which will require high-throughput tools...
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Published in | Chembiochem : a European journal of chemical biology Vol. 11; no. 7; pp. 987 - 994 |
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Main Authors | , , , , , , , , |
Format | Journal Article |
Language | English |
Published |
Weinheim
Wiley-VCH Verlag
03.05.2010
WILEY-VCH Verlag WILEY‐VCH Verlag |
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Abstract | Cytochromes P450 (P450s) are a family of haem-containing oxidases with considerable potential as tools for industrial biocatalysis. Organismal genomes are revealing thousands of gene sequences that encode P450s of as yet unknown function, the exploitation of which will require high-throughput tools for their isolation and characterisation. In this report, a ligationindependent cloning vector "LICRED" is described that enables the high-throughput generation of libraries of redox-self-sufficient P450s by fusing a range of P450 haem domains to the reductase of P450RhF (RhF-Red) in a robust and generically applicable way. Cloning and expression of fusions of RhF-Red with the haem domains of P450cam and P450-XplA resulted in soluble, active, redox-self-sufficient, chimeric enzymes. In vitro studies also revealed that electron transfer from NADPH to haem was primarily intramolecular. The general applicability of the LICRED platform was then demonstrated through the creation of a library of RhF-Red fusion constructs by using the diverse complement of P450 haem domains identified in the genome of Nocardia farcinica. The resultant fusion-protein library was then screened against a panel of substrates; this revealed chimeric enzymes competent for the hydroxylation of testosterone and methyltestosterone, and the dealkylation of 7-ethoxycoumarin. |
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AbstractList | Cytochromes P450 (P450s) are a family of haem‐containing oxidases with considerable potential as tools for industrial biocatalysis. Organismal genomes are revealing thousands of gene sequences that encode P450s of as yet unknown function, the exploitation of which will require high‐throughput tools for their isolation and characterisation. In this report, a ligationindependent cloning vector “LICRED” is described that enables the high‐throughput generation of libraries of redox‐self‐sufficient P450s by fusing a range of P450 haem domains to the reductase of P450RhF (RhF‐Red) in a robust and generically applicable way. Cloning and expression of fusions of RhF‐Red with the haem domains of P450cam and P450‐XplA resulted in soluble, active, redox‐self‐sufficient, chimeric enzymes. In vitro studies also revealed that electron transfer from NADPH to haem was primarily intramolecular. The general applicability of the LICRED platform was then demonstrated through the creation of a library of RhF‐Red fusion constructs by using the diverse complement of P450 haem domains identified in the genome of Nocardia farcinica. The resultant fusion‐protein library was then screened against a panel of substrates; this revealed chimeric enzymes competent for the hydroxylation of testosterone and methyltestosterone, and the dealkylation of 7‐ethoxycoumarin.
A new platform, LICRED, enables the high‐throughput generation of chimeric cytochromes P450 by fusing a library of haem domains to a generic reductase by ligation‐independent cloning. This strategy can be used to characterise orphan P450s for which the function has not been determined and also to generate libraries of redox‐self‐sufficient biocatalysts. Cytochromes P450 (P450s) are a family of haem‐containing oxidases with considerable potential as tools for industrial biocatalysis. Organismal genomes are revealing thousands of gene sequences that encode P450s of as yet unknown function, the exploitation of which will require high‐throughput tools for their isolation and characterisation. In this report, a ligationindependent cloning vector “LICRED” is described that enables the high‐throughput generation of libraries of redox‐self‐sufficient P450s by fusing a range of P450 haem domains to the reductase of P450RhF (RhF‐Red) in a robust and generically applicable way. Cloning and expression of fusions of RhF‐Red with the haem domains of P450cam and P450‐XplA resulted in soluble, active, redox‐self‐sufficient, chimeric enzymes. In vitro studies also revealed that electron transfer from NADPH to haem was primarily intramolecular. The general applicability of the LICRED platform was then demonstrated through the creation of a library of RhF‐Red fusion constructs by using the diverse complement of P450 haem domains identified in the genome of Nocardia farcinica . The resultant fusion‐protein library was then screened against a panel of substrates; this revealed chimeric enzymes competent for the hydroxylation of testosterone and methyltestosterone, and the dealkylation of 7‐ethoxycoumarin. Cytochromes P450 (P450s) are a family of haem-containing oxidases with considerable potential as tools for industrial biocatalysis. Organismal genomes are revealing thousands of gene sequences that encode P450s of as yet unknown function, the exploitation of which will require high-throughput tools for their isolation and characterisation. In this report, a ligationindependent cloning vector "LICRED" is described that enables the high-throughput generation of libraries of redox-self-sufficient P450s by fusing a range of P450 haem domains to the reductase of P450RhF (RhF-Red) in a robust and generically applicable way. Cloning and expression of fusions of RhF-Red with the haem domains of P450cam and P450-XplA resulted in soluble, active, redox-self-sufficient, chimeric enzymes. In vitro studies also revealed that electron transfer from NADPH to haem was primarily intramolecular. The general applicability of the LICRED platform was then demonstrated through the creation of a library of RhF-Red fusion constructs by using the diverse complement of P450 haem domains identified in the genome of Nocardia farcinica. The resultant fusion-protein library was then screened against a panel of substrates; this revealed chimeric enzymes competent for the hydroxylation of testosterone and methyltestosterone, and the dealkylation of 7-ethoxycoumarin. |
Author | Hilgarth, Eva-Maria Hyde, Ralph Delenne, Marie Flitsch, Sabine Robin, Aelig Turner, Nicholas Sabbadin, Federico Grogan, Gideon Bruce, Neil C |
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Snippet | Cytochromes P450 (P450s) are a family of haem-containing oxidases with considerable potential as tools for industrial biocatalysis. Organismal genomes are... Cytochromes P450 (P450s) are a family of haem‐containing oxidases with considerable potential as tools for industrial biocatalysis. Organismal genomes are... |
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SubjectTerms | biocatalysis Cytochrome P-450 Enzyme System - genetics Cytochrome P-450 Enzyme System - metabolism cytochromes Electron Transport enzyme catalysis Enzymes Genetic Vectors Heme - chemistry heme proteins high throughput Kinetics NADP - chemistry Oxidation-Reduction Protein Structure, Tertiary Recombinant Fusion Proteins - genetics Recombinant Fusion Proteins - metabolism |
Title | LICRED: A Versatile Drop-In Vector for Rapid Generation of Redox-Self-Sufficient Cytochrome P450s |
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