Mutagenesis of the “Leucine Gate” to explore the basis of Catalytic Versatility in soluble Methane Monooxygenase
Mutagenesis of the “Leucine Gate” to explore the basis of Catalytic Versatility in soluble Methane Monooxygenase
Soluble methane monooxygenase (sMMO) from methane-oxidizing bacteria is a multicomponent nonheme oxygenase that naturally oxidizes methane to methanol and can also cooxidize a wide range of adventitious substrates, including mono- and diaromatic hydrocarbons. Leucine 110, at the mouth of the active site in the α subunit of the hydroxylase component of sMMO, has been suggested to act as a gate to control the access of substrates to the active site. Previous crystallography of the wild-type sMMO has indicated at least two conformations of the enzyme that have the “leucine gate” open to different extents, and mutagenesis of homologous enzymes has indicated a role for this residue in the control of substrate range and regioselectivity with aromatic substrates. By further refinement of the system for homologous expression of sMMO that we developed previously, we have been able to prepare a range of site-directed mutations at position 110 in the α subunit of sMMO. All the mutants (with Gly, Cys, Arg, and Tyr, respectively, at this position) showed relaxations of regioselectivity compared to the wild type with monoaromatic substrates and biphenyl, including the appearance of new products arising from hydroxylation at the 2- and 3- positions on the benzene ring. Mutants with the larger Arg and Trp residues at position 110 also showed shifts in regioselectivity during naphthalene hydroxylation from the 2- to the 1- position. No evidence that mutagenesis of Leu 110 could allow very large substrates to enter the active site was found, however, since the mutants (like the wild type) were inactive toward the triaromatic hydrocarbons anthracene and phenanthrene. Thus, our results indicate that the “leucine gate” in sMMO is more important in controlling the precision of regioselectivity than the sizes of substrates that can enter the active site.
6460-6467
Borodina, Elena
30113d1c-c7ad-430c-806f-8a1955afc6ed
Nichol, Tim
bc4cff7a-21eb-4f19-ad4f-256f936185a3
Dumont, Marc
afd9f08f-bdbb-4cee-b792-1a7f000ee511
Smith, Thomas J.
7b6d8745-c0fe-4205-8665-e1450322ad12
Murrell, J. Colin
244a92ff-dbe1-41cf-9e65-baacbc4a90cf
15 October 2007
Borodina, Elena
30113d1c-c7ad-430c-806f-8a1955afc6ed
Nichol, Tim
bc4cff7a-21eb-4f19-ad4f-256f936185a3
Dumont, Marc
afd9f08f-bdbb-4cee-b792-1a7f000ee511
Smith, Thomas J.
7b6d8745-c0fe-4205-8665-e1450322ad12
Murrell, J. Colin
244a92ff-dbe1-41cf-9e65-baacbc4a90cf
Borodina, Elena, Nichol, Tim, Dumont, Marc, Smith, Thomas J. and Murrell, J. Colin
(2007)
Mutagenesis of the “Leucine Gate” to explore the basis of Catalytic Versatility in soluble Methane Monooxygenase.
Applied and Environmental Microbiology, 73 (20), .
(doi:10.1128/AEM.00823-07).
Abstract
Soluble methane monooxygenase (sMMO) from methane-oxidizing bacteria is a multicomponent nonheme oxygenase that naturally oxidizes methane to methanol and can also cooxidize a wide range of adventitious substrates, including mono- and diaromatic hydrocarbons. Leucine 110, at the mouth of the active site in the α subunit of the hydroxylase component of sMMO, has been suggested to act as a gate to control the access of substrates to the active site. Previous crystallography of the wild-type sMMO has indicated at least two conformations of the enzyme that have the “leucine gate” open to different extents, and mutagenesis of homologous enzymes has indicated a role for this residue in the control of substrate range and regioselectivity with aromatic substrates. By further refinement of the system for homologous expression of sMMO that we developed previously, we have been able to prepare a range of site-directed mutations at position 110 in the α subunit of sMMO. All the mutants (with Gly, Cys, Arg, and Tyr, respectively, at this position) showed relaxations of regioselectivity compared to the wild type with monoaromatic substrates and biphenyl, including the appearance of new products arising from hydroxylation at the 2- and 3- positions on the benzene ring. Mutants with the larger Arg and Trp residues at position 110 also showed shifts in regioselectivity during naphthalene hydroxylation from the 2- to the 1- position. No evidence that mutagenesis of Leu 110 could allow very large substrates to enter the active site was found, however, since the mutants (like the wild type) were inactive toward the triaromatic hydrocarbons anthracene and phenanthrene. Thus, our results indicate that the “leucine gate” in sMMO is more important in controlling the precision of regioselectivity than the sizes of substrates that can enter the active site.
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Accepted/In Press date: 7 August 2007
e-pub ahead of print date: 17 August 2007
Published date: 15 October 2007
Identifiers
Local EPrints ID: 480086
URI: http://eprints.soton.ac.uk/id/eprint/480086
ISSN: 0099-2240
PURE UUID: 530cfee4-f2fc-4f21-9d69-e423912f6a3f
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Date deposited: 01 Aug 2023 16:46
Last modified: 18 Mar 2024 03:33
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Author:
Elena Borodina
Author:
Tim Nichol
Author:
Thomas J. Smith
Author:
J. Colin Murrell
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