A novel fold for acyltransferase-3 (AT3) proteins provides a framework for transmembrane acyl-group transfer
A novel fold for acyltransferase-3 (AT3) proteins provides a framework for transmembrane acyl-group transfer
Acylation of diverse carbohydrates occurs across all domains of life and can be catalysed by proteins with a membrane bound acyltransferase-3 (AT3) domain (PF01757). In bacteria, these proteins are essential in processes including symbiosis, resistance to viruses and antimicrobials, and biosynthesis of antibiotics, yet their structure and mechanism are largely unknown. In this study, evolutionary co-variance analysis was used to build a computational model of the structure of a bacterial O-antigen modifying acetyltransferase, OafB. The resulting structure exhibited a novel fold for the AT3 domain, which molecular dynamics simulations demonstrated is stable in the membrane. The AT3 domain contains 10 transmembrane helices arranged to form a large cytoplasmic cavity lined by residues known to be essential for function. Further molecular dynamics simulations support a model where the acyl-coA donor spans the membrane through accessing a pore created by movement of an important loop capping the inner cavity, enabling OafB to present the acetyl group close to the likely catalytic resides on the extracytoplasmic surface. Limited but important interactions with the fused SGNH domain in OafB are identified, and modelling suggests this domain is mobile and can both accept acyl-groups from the AT3 and then reach beyond the membrane to reach acceptor substrates. Together this new general model of AT3 function provides a framework for the development of inhibitors that could abrogate critical functions of bacterial pathogens.
Newman, Kahlan E.
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Tindall, Sarah N.
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Mader, Sophie L.
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Khalid, Syma
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Thomas, Gavin H.
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Van Der Woude, Marjan W.
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11 January 2023
Newman, Kahlan E.
7fccd66d-2aa1-4dd6-b477-2ad528389f83
Tindall, Sarah N.
1ef3e26b-6c59-4499-9eed-2ddc4e9c1c35
Mader, Sophie L.
ccec2852-edba-41e9-aa86-99fdb858df97
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
Thomas, Gavin H.
dcf1bb2d-39dc-4c20-b006-f96d55a3bd29
Van Der Woude, Marjan W.
d70aa23c-8908-4ce4-9ff7-84086bd218b9
Newman, Kahlan E., Tindall, Sarah N., Mader, Sophie L., Khalid, Syma, Thomas, Gavin H. and Van Der Woude, Marjan W.
(2023)
A novel fold for acyltransferase-3 (AT3) proteins provides a framework for transmembrane acyl-group transfer.
eLife, 12, [e81547].
(doi:10.7554/eLife.81547).
Abstract
Acylation of diverse carbohydrates occurs across all domains of life and can be catalysed by proteins with a membrane bound acyltransferase-3 (AT3) domain (PF01757). In bacteria, these proteins are essential in processes including symbiosis, resistance to viruses and antimicrobials, and biosynthesis of antibiotics, yet their structure and mechanism are largely unknown. In this study, evolutionary co-variance analysis was used to build a computational model of the structure of a bacterial O-antigen modifying acetyltransferase, OafB. The resulting structure exhibited a novel fold for the AT3 domain, which molecular dynamics simulations demonstrated is stable in the membrane. The AT3 domain contains 10 transmembrane helices arranged to form a large cytoplasmic cavity lined by residues known to be essential for function. Further molecular dynamics simulations support a model where the acyl-coA donor spans the membrane through accessing a pore created by movement of an important loop capping the inner cavity, enabling OafB to present the acetyl group close to the likely catalytic resides on the extracytoplasmic surface. Limited but important interactions with the fused SGNH domain in OafB are identified, and modelling suggests this domain is mobile and can both accept acyl-groups from the AT3 and then reach beyond the membrane to reach acceptor substrates. Together this new general model of AT3 function provides a framework for the development of inhibitors that could abrogate critical functions of bacterial pathogens.
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elife-81547-v1
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Accepted/In Press date: 4 December 2022
Published date: 11 January 2023
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Funding Information:
The authors acknowledge access to the following High Performance Computing resources: Iridis 5 at the University of Southampton and the JADE Tier 2 facility (EPSRC grant no. EP/T022205/1) to which access was granted via HECBioSim, the UK High-End Computing Consortium for Biomolecular Simulation (EPSRC grant no. EP/R029407/1). The authors also acknowledge the C Skylaris group at the University of Southampton for their help with ONETEP. KEN was supported by a Ph.D. Studentship from the Engineering and Physical Sciences Research Council (Project Number: 2446840); SNT was supported by a Ph.D. studentship from the Biotechnology and Biological Sciences Research Council White Rose Doctoral Training Program (BB/M011151/1), 'Mechanistic Biology and its Strategic Appli-cation'. SLM acknowledges the support of the Federation of European Biochemical Societies (FEBS) through a long-term fellowship. SK is supported by an EPSRC established Career Fellowship (EPSRC grant no. EP/V030779/1). We thank Alex Bateman for useful discussions and initial advice with using RaptorX.
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Local EPrints ID: 475917
URI: http://eprints.soton.ac.uk/id/eprint/475917
ISSN: 2050-084X
PURE UUID: ecd75e3e-48f8-47ea-804c-235092b19847
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Date deposited: 31 Mar 2023 16:30
Last modified: 17 Mar 2024 03:11
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Contributors
Author:
Kahlan E. Newman
Author:
Sarah N. Tindall
Author:
Sophie L. Mader
Author:
Syma Khalid
Author:
Gavin H. Thomas
Author:
Marjan W. Van Der Woude
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