Conserved features in TamA enable interaction with TamB to drive the activity of the translocation and assembly module

Joel Selkrig; Matthew J. Belousoff; Stephen J. Headey; Eva Heinz; Takuya Shiota; Hsin Hui Shen; Simone A. Beckham; Rebecca S. Bamert; Minh Duy Phan; Mark A. Schembri; Matthew C.J. Wilce; Martin J. Scanlon; Richard A. Strugnell; Trevor Lithgow

doi:10.1038/srep12905

Conserved features in TamA enable interaction with TamB to drive the activity of the translocation and assembly module

Joel Selkrig, Matthew J. Belousoff, Stephen J. Headey, Eva Heinz, Takuya Shiota, Hsin Hui Shen, Simone A. Beckham, Rebecca S. Bamert, Minh Duy Phan, Mark A. Schembri, Matthew C.J. Wilce, Martin J. Scanlon, Richard A. Strugnell, Trevor Lithgow^*

^*Corresponding author for this work

Strathclyde Institute Of Pharmacy And Biomedical Sciences

Research output: Contribution to journal › Article › peer-review

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Abstract

The biogenesis of membranes from constituent proteins and lipids is a fundamental aspect of cell biology. In the case of proteins assembled into bacterial outer membranes, an overarching question concerns how the energy required for protein insertion and folding is accessed at this remote location of the cell. The translocation and assembly module (TAM) is a nanomachine that functions in outer membrane biogenesis and virulence in diverse bacterial pathogens. Here we demonstrate the interactions through which TamA and TamB subunits dock to bridge the periplasm, and unite the outer membrane aspects to the inner membrane of the bacterial cell. We show that specific functional features in TamA have been conserved through evolution, including residues surrounding the lateral gate and an extensive surface of the POTRA domains. Analysis by nuclear magnetic resonance spectroscopy and small angle X-ray scattering document the characteristic structural features of these POTRA domains and demonstrate rigidity in solution. Quartz crystal microbalance measurements pinpoint which POTRA domain specifically docks the TamB subunit of the nanomachine. We speculate that the POTRA domain of TamA functions as a lever arm in order to drive the activity of the TAM, assembling proteins into bacterial outer membranes.

Original language	English
Article number	12905
Number of pages	12
Journal	Scientific Reports
Volume	5
DOIs	https://doi.org/10.1038/srep12905
Publication status	Published - 5 Aug 2015

Funding

We thank Chaille Webb for comments on the manuscript and Denisse Leyton for reagents. This research was undertaken on the SAXS/WAXS beamline at the Australian Synchrotron and the QCM-D facility at CSIRO. This work was supported through an NHMRC Program Grant (606788, to TL and RAS) and an NHMRC Project grant (APP1042651 to MAS), and an ARC Super Science Grant (to TL and RAS). TL is an ARC Laureate Fellow, MAS is an ARC Future Fellow, HHS is an ARC Super Science Fellow, MJB is an NHMRC Biomedical Fellow, JS is a Long-Term EMBO (non-stipendiary) and EIPOD fellow and MCJW is an NHMRC Senior Research Fellow.

Keywords

cell biology
proteins
lipids

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10.1038/srep12905Licence: CC BY 4.0

Selkrig-etal-SR-2015-Conserved-features-in-TamA-enable-interaction-with-TamB-to-drive-the-activityFinal published version, 3.55 MBLicence: CC BY 4.0

Cite this

Selkrig, J., Belousoff, M. J., Headey, S. J., Heinz, E., Shiota, T., Shen, H. H., Beckham, S. A., Bamert, R. S., Phan, M. D., Schembri, M. A., Wilce, M. C. J., Scanlon, M. J., Strugnell, R. A., & Lithgow, T. (2015). Conserved features in TamA enable interaction with TamB to drive the activity of the translocation and assembly module. Scientific Reports, 5, Article 12905. https://doi.org/10.1038/srep12905

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abstract = "The biogenesis of membranes from constituent proteins and lipids is a fundamental aspect of cell biology. In the case of proteins assembled into bacterial outer membranes, an overarching question concerns how the energy required for protein insertion and folding is accessed at this remote location of the cell. The translocation and assembly module (TAM) is a nanomachine that functions in outer membrane biogenesis and virulence in diverse bacterial pathogens. Here we demonstrate the interactions through which TamA and TamB subunits dock to bridge the periplasm, and unite the outer membrane aspects to the inner membrane of the bacterial cell. We show that specific functional features in TamA have been conserved through evolution, including residues surrounding the lateral gate and an extensive surface of the POTRA domains. Analysis by nuclear magnetic resonance spectroscopy and small angle X-ray scattering document the characteristic structural features of these POTRA domains and demonstrate rigidity in solution. Quartz crystal microbalance measurements pinpoint which POTRA domain specifically docks the TamB subunit of the nanomachine. We speculate that the POTRA domain of TamA functions as a lever arm in order to drive the activity of the TAM, assembling proteins into bacterial outer membranes.",

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AU - Belousoff, Matthew J.

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AU - Shiota, Takuya

AU - Shen, Hsin Hui

AU - Beckham, Simone A.

AU - Bamert, Rebecca S.

AU - Phan, Minh Duy

AU - Schembri, Mark A.

AU - Wilce, Matthew C.J.

AU - Scanlon, Martin J.

AU - Strugnell, Richard A.

AU - Lithgow, Trevor

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N2 - The biogenesis of membranes from constituent proteins and lipids is a fundamental aspect of cell biology. In the case of proteins assembled into bacterial outer membranes, an overarching question concerns how the energy required for protein insertion and folding is accessed at this remote location of the cell. The translocation and assembly module (TAM) is a nanomachine that functions in outer membrane biogenesis and virulence in diverse bacterial pathogens. Here we demonstrate the interactions through which TamA and TamB subunits dock to bridge the periplasm, and unite the outer membrane aspects to the inner membrane of the bacterial cell. We show that specific functional features in TamA have been conserved through evolution, including residues surrounding the lateral gate and an extensive surface of the POTRA domains. Analysis by nuclear magnetic resonance spectroscopy and small angle X-ray scattering document the characteristic structural features of these POTRA domains and demonstrate rigidity in solution. Quartz crystal microbalance measurements pinpoint which POTRA domain specifically docks the TamB subunit of the nanomachine. We speculate that the POTRA domain of TamA functions as a lever arm in order to drive the activity of the TAM, assembling proteins into bacterial outer membranes.

AB - The biogenesis of membranes from constituent proteins and lipids is a fundamental aspect of cell biology. In the case of proteins assembled into bacterial outer membranes, an overarching question concerns how the energy required for protein insertion and folding is accessed at this remote location of the cell. The translocation and assembly module (TAM) is a nanomachine that functions in outer membrane biogenesis and virulence in diverse bacterial pathogens. Here we demonstrate the interactions through which TamA and TamB subunits dock to bridge the periplasm, and unite the outer membrane aspects to the inner membrane of the bacterial cell. We show that specific functional features in TamA have been conserved through evolution, including residues surrounding the lateral gate and an extensive surface of the POTRA domains. Analysis by nuclear magnetic resonance spectroscopy and small angle X-ray scattering document the characteristic structural features of these POTRA domains and demonstrate rigidity in solution. Quartz crystal microbalance measurements pinpoint which POTRA domain specifically docks the TamB subunit of the nanomachine. We speculate that the POTRA domain of TamA functions as a lever arm in order to drive the activity of the TAM, assembling proteins into bacterial outer membranes.

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Conserved features in TamA enable interaction with TamB to drive the activity of the translocation and assembly module

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