2003
DOI: 10.1042/bst0310558
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Engineering substrate recognition in catalysis by cytochrome P450cam

Abstract: We have a continuing interest in applying the current knowledge of cytochrome P450cam substrate recognition to engineer the enzyme for the biotransformation of unnatural substrates with the long-term aim of applications in the synthesis of fine chemicals and bioremediation of environmental contaminants. Comparisons of the structure of target substrates with that of camphor, the natural substrate, led to the design of active-site mutants with greatly enhanced activity for the oxidation of chlorinated benzenes a… Show more

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Cited by 33 publications
(24 citation statements)
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“…Regardless of the area of application, however, the feasibility of utilizing P450s to confer herbicide resistance or decontaminate polluted areas will greatly depend on our abilities to provide P450 enzymes with high catalytic activity towards the desired substrate(s). Several approaches have been successful in enhancing P450 activity including rational protein design (Bell et al 2003;Carmichael and Wong 2001), directed enzyme evolution (Abecassis et al 2000;Abecassis et al 2003) and the optimization of the redox environment in plants by simultaneously overexpressing a NADPH:P450 reductase (Siminszky et al 2003); therefore, P450s specifically tailored for high efficiency herbicide metabolism may soon become available.…”
Section: Practical Applicationsmentioning
confidence: 99%
“…Regardless of the area of application, however, the feasibility of utilizing P450s to confer herbicide resistance or decontaminate polluted areas will greatly depend on our abilities to provide P450 enzymes with high catalytic activity towards the desired substrate(s). Several approaches have been successful in enhancing P450 activity including rational protein design (Bell et al 2003;Carmichael and Wong 2001), directed enzyme evolution (Abecassis et al 2000;Abecassis et al 2003) and the optimization of the redox environment in plants by simultaneously overexpressing a NADPH:P450 reductase (Siminszky et al 2003); therefore, P450s specifically tailored for high efficiency herbicide metabolism may soon become available.…”
Section: Practical Applicationsmentioning
confidence: 99%
“…1A). Alternatively, NysL can be engineered via either site-specific mutagenesis (4) or directed evolution (3) in order to change its specificity towards 10-deoxynystatin. This approach might provide novel nystatin analogues hydroxylated at alternative macrolactone ring positions in hope of obtaining antifungal compounds with improved pharmacologic properties.…”
Section: Discussionmentioning
confidence: 99%
“…Most studies of these enzymes focus on altering the specificity and regioselectivity of the catalyzed hydroxylation reactions. Analysis of the active site of CYP101A1 and comparisons of the structure of target substrates with that of camphor led to the design of active-site mutants with greatly enhanced activity for the oxidation of (+)-α-pinene [30]. Based on the enzyme/ substrate contacts revealed by the structure of the triple mutant F87W/Y96F/V247L with (+)-α-pinene bound within the active site, additional mutations were carried out and resulted in an improved selectivity for the formation of the natural fragrances and flavors (+)-cis-verbenol and (+)-verbenone [31].…”
Section: Engineering By Rational Protein Designmentioning
confidence: 99%