Directed Evolution of Toluene
            <i>ortho</i>
            -Monooxygenase for Enhanced 1-Naphthol Synthesis and Chlorinated Ethene Degradation

Canada, Keith A.; Iwashita, Sachiyo; Shim, Hyungbo; Wood, Thomas K.

doi:10.1128/jb.184.2.344-349.2002

Cited by 160 publications

(168 citation statements)

References 41 publications

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“…The I100Q and I100C mutants indicate that the residue in this position need not be hydrophobic for TMOs to be efficient catalysts and suggest that a small side chain is not beneficial, perhaps due to limited gating ability and greater exposure to solvent. A Val to Ala mutation of the analogous gate residue in T2MO from Burkholderia capacia G4, a member of the three-component PH family, resulted in enhanced ability to degrade naphthalene and threering fused aromatics including phenanthrene, fluorene, and anthracene (48). In the light of the present structures, these findings strongly suggest that members of the PH subclass have a similar substrate channel.…”

Section: Resultsmentioning

confidence: 51%

Crystal Structure of the Toluene/o-Xylene Monooxygenase Hydroxylase from Pseudomonas stutzeri OX1

Sazinsky

Bard²,

Donato

et al. 2004

Journal of Biological Chemistry

190

177

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The four-component toluene/o-xylene monooxygenase (ToMO) from Pseudomonas stutzeri OX1 is capable of oxidizing arenes, alkenes, and haloalkanes at a carboxylate-bridged diiron center similar to that of soluble methane monooxygenase (sMMO). The remarkable variety of substrates accommodated by ToMO invites applications ranging from bioremediation to the regioand enantiospecific oxidation of hydrocarbons on an industrial scale. We report here the crystal structures of the ToMO hydroxylase (ToMOH), azido ToMOH, and ToMOH containing the product analogue 4-bromophenol to 2.3 Å or greater resolution. The catalytic diiron(III) core resembles that of the sMMO hydroxylase, but aspects of the ␣ 2 ␤ 2 ␥ 2 tertiary structure are notably different. Of particular interest is a 6 -10 Å-wide channel of ϳ35 Å in length extending from the active site to the protein surface. The presence of three bromophenol molecules in this space confirms this route as a pathway for substrate entrance and product egress. An analysis of the ToMOH active site cavity offers insights into the different substrate specificities of multicomponent monooxygenases and explains the behavior of mutant forms of homologous enzymes described in the literature.Bacterial multicomponent monooxygenases (BMMs) 1 comprise a family of carboxylate-bridged non-heme diiron enzymes capable of oxidizing a broad range of hydrocarbons including C 1 -C 8 alkanes, alkenes, and aromatics (1, 2). Four characterized subclasses of multicomponent monooxygenases have been defined (2, 3). These are soluble methane monooxygenases (sMMOs), four-component alkene/arene monooxygenases or toluene monooxygenases (TMOs), three-component phenol hydroxylases (PHs), and ␣␤ alkene monoxygenases (AMOs), of which all are believed to have evolved from a common ancestor. Bacteria containing multicomponent monooxygenases are capable of using specific hydrocarbon substrates as their primary source of carbon and energy (1, 2, 4). The remarkable range of substrate specificity exhibited by these enzymes endows these bacteria with the ability to bioremediate environmentally harmful substances such as trichloroethylene and petroleum spills (5, 6) and to regulate the global carbon cycle (4). BMMs can also perform regio-and stereospecific hydroxylations, making them useful for producing pure feedstocks for industrial synthesis (7). These enzyme systems, although highly homologous, have evolved different substrate specificities. Only soluble methane monooxygenase can activate the inert C-H bond of methane, which is one of the most difficult reactions to perform in nature (1), whereas the catalytic abilities of TMOs are limited to aromatics, alkenes, and some haloalkanes (2, 5).Substrate hydroxylation in BMMs occurs at a dioxygen-activated, carboxylate-bridged diiron center in the ␣-subunit of a ϳ220 -250 kDa hydroxylase component that is an (␣␤␥) 2 heterodimer or, in the case of one known AMO, an ␣␤ monomer (1-3, 8, 9). Sequence identity comparisons and spectroscopic studies suggest that the diiron centers of...

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Section: Resultsmentioning

confidence: 51%

Crystal Structure of the Toluene/o-Xylene Monooxygenase Hydroxylase from Pseudomonas stutzeri OX1

Sazinsky

Bard²,

Donato

et al. 2004

Journal of Biological Chemistry

190

177

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“…First, the x-ray structure of the methane monooxygenase hydroxylase (MmoH) indicates that a short access path from solvent to the diiron center may pass through a ''Leu gate'' (27). Second, directedevolution studies of toluene 2-monooxygenase revealed that a V106A mutation in this ''gate'' region led to an increased reactivity with a larger substrate, naphthalene (28). Third, the position of G103L used in these studies is predicted to lie along this entry portal, in close proximity to the (Fe) 2 center.…”

Section: Discussionmentioning

confidence: 99%

Insight into the mechanism of aromatic hydroxylation by toluene 4-monooxygenase by use of specifically deuterated toluene and p- xylene

Mitchell

Rogge

Gierahn

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

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The present studies address the mechanism of aromatic hydroxylation used by the natural and G103L isoforms of the diiron enzyme toluene 4-monooxygenase. These isoforms have comparable catalytic parameters but distinct regiospecificities for toluene hydroxylation. Hydroxylation of ring-deuterated pxylene by the natural isoform revealed a substantial inverse isotope effect of 0.735, indicating a change in hybridization from sp 2 to sp 3 for hydroxylation at a carbon atom bearing the deuteron. During the hydroxylation of 4-2 H1-and 3,5-2 H2-toluene, similar magnitudes of intramolecular isotope effects and patterns of deuterium retention were observed from both isoforms studied, indicating that the active-site mutation affected substrate orientation but did not influence the mechanism of hydroxylation. The results with deuterated toluenes show inverse intramolecular isotope effects for hydroxylation at the position of deuteration, normal secondary isotope effects for hydroxylation adjacent to the position of deuteration, near-quantitative deuterium retention in m-cresol obtained from 4-2 H1-toluene, and partial loss of deuterium from all phenolic products obtained from 3,5-2 H2-toluene. This combination of results suggests that an active site-directed opening of position-specific transient epoxide intermediates may contribute to the chemical mechanism and the high degree of regiospecificity observed for aromatic hydroxylation in this evolutionarily specialized diiron enzyme.

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“…Proteins with several activities (multipurpose enzymes) may have a wide range of biotechnological applications related (but not limited) to industrial organic synthesis and metabolic engineering [12][13][14][15][16][17]. However, natural protein promiscuity (as described in the two preceding paragraphs) may perhaps be of limited use in the development of these multipurpose catalysts.…”

Section: Accepted M Manuscriptmentioning

confidence: 99%

Using multi-objective computational design to extend protein promiscuity

Suárez

Tortosa

Garcia-Mira

et al. 2010

Biophysical Chemistry

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Directed Evolution of Toluene ortho -Monooxygenase for Enhanced 1-Naphthol Synthesis and Chlorinated Ethene Degradation

Cited by 160 publications

References 41 publications

Crystal Structure of the Toluene/o-Xylene Monooxygenase Hydroxylase from Pseudomonas stutzeri OX1

Crystal Structure of the Toluene/o-Xylene Monooxygenase Hydroxylase from Pseudomonas stutzeri OX1

Insight into the mechanism of aromatic hydroxylation by toluene 4-monooxygenase by use of specifically deuterated toluene and p- xylene

Using multi-objective computational design to extend protein promiscuity

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