Projects per year
Abstract
Terpene synthases are potentially useful biocatalysts for the synthesis of valuable compounds, such as anticancer drugs and antibiotics. The design of altered activities requires better knowledge of their mechanisms, for example, an understanding of the complex conformational changes that are part of their catalytic cycle, how they are coordinated, and what drives them. Crystallographic studies of the sesquiterpene synthase artistolochene synthase have led to a proposed sequence of ligand binding and conformational change but have provided only indirect insight. Here, we have performed extensive molecular dynamics simulations of multiple enzyme ligand complexes (over 2 mu s in total). The simulations provide clear evidence of what drives the conformational changes required for reaction. They support a picture in which the substrate farnesyl diphosphate binds first, followed by three magnesium ions in sequence, and, after reaction, the release of aristolochene and two magnesium ions followed by the final magnesium ion and diphosphate. Binding of farnesyl diphosphate leads to an increased level of sampling of open conformations, allowing the first two magnesium ions to bind. The closed enzyme conformation is maintained with a diphosphate moiety and two magnesium ions bound. The open-to-closed transition reduces flexibility around the active site entrance, partly through a lid closing over it. The simulations with all three magnesium ions and farnesyl diphosphate bound provide, for the first time, a realistic model of the Michaelis complex involved in reaction, which is inaccessible to experimental structural studies. These insights could help with the design of altered activities in a range of terpene synthases.
Original language | English |
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Pages (from-to) | 8094-8105 |
Number of pages | 12 |
Journal | Biochemistry |
Volume | 52 |
Issue number | 45 |
DOIs | |
Publication status | Published - 12 Nov 2013 |
Keywords
- MOLECULAR-DYNAMICS SIMULATIONS
- FARNESYL PYROPHOSPHATE
- CRYSTAL-STRUCTURE
- EUDESMANE CATION
- TRICHODIENE SYNTHASE
- SESQUITERPENE SYNTHASE
- PENICILLIUM-ROQUEFORTI
- ENZYMATIC CYCLIZATION
- TERPENE BIOSYNTHESIS
- FORCE-FIELDS
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Dive into the research topics of 'Conformational Change and Ligand Binding in the Aristolochene Synthase Catalytic Cycle'. Together they form a unique fingerprint.Projects
- 2 Finished
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CCP-BioSim: Biomolecular simulation at the life sciences interface
Mulholland, A. J. (Principal Investigator)
1/10/11 → 1/10/15
Project: Research
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COMPUTATIONAL BIOCHEMISTRY: PREDICTIVE MODELLING FOR BIOLOGY AND MEDICINE
Mulholland, A. J. (Principal Investigator)
1/10/08 → 1/04/14
Project: Research
Equipment
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HPC (High Performance Computing) and HTC (High Throughput Computing) Facilities
Alam, S. R. (Manager), Chapman, S. A. (Manager), Eccleston, P. E. (Other), Atack, S. H. (Other) & Williams, D. A. G. (Manager)
Facility/equipment: Facility