Abstract
Heme-containing integral membrane proteins are at the heart of many bioenergetic complexes and electron transport chains. The importance of these electron relay hubs across biology has inspired the design of de novo proteins that recreate their core features within robust, versatile and tractable protein folds. To this end, we report here the computational design and in-cell production of a minimal diheme membrane cytochrome which successfully integrates into the cellular membrane of live bacteria. This synthetic construct emulates a four-helix bundle found in modern respiratory complexes but has no sequence homology to any polypeptide sequence found in nature. The two b-type hemes, which appear to be recruited from the endogenous heme pool, have distinct split redox potentials with values close to those of natural membrane-spanning cytochromes. The purified protein can engage in rapid biomimetic electron transport with small molecules, with other redox proteins, and with biologically-relevant diffusive electron carriers. We thus report an artificial membrane metalloprotein with the potential to serve as a functional module in electron transfer pathways in both synthetic protocells and living systems.
Original language | English |
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Article number | e2300137120 |
Journal | Proceedings of the National Academy of Sciences of the United States of America |
Volume | 120 |
Issue number | 16 |
Early online date | 10 Apr 2023 |
DOIs | |
Publication status | Published - 18 Apr 2023 |
Bibliographical note
Funding Information:We thank Prof. Christoph von Ballmoos for the kind gift of plasmid pETcyoII, used for the heterologous expression of E. coli bo3 ubiquinol oxidase. This work was funded in whole or in part by a SynBioCDT doctoral training award to B.J.H., BrisSynBio, a Biotechnology and Biological Sciences Research Council/Engineering and Physical Sciences Research Council (BBSRC/EPSRC) Synthetic Biology Research Centre (BB/L01386X/1), and BBSRC grant BB/W003449/1 to J.L.R.A. This work used the computational facilities of the Advanced Computing Research Centre at the University of Bristol (http://www.bristol.ac.uk/acrc).
Funding Information:
ACKNOWLEDGMENTS. We thank Prof. Christoph von Ballmoos for the kind gift of plasmid pETcyoII, used for the heterologous expression of E. coli bo3 ubiquinol oxidase. This work was funded in whole or in part by a SynBioCDT doctoral training award to B.J.H., BrisSynBio, a Biotechnology and Biological Sciences Research Council/ Engineering and Physical Sciences Research Council (BBSRC/EPSRC) Synthetic Biology Research Centre (BB/L01386X/1), and BBSRC grant BB/W003449/1 to J.L.R.A. This work used the computational facilities of the Advanced Computing Research Centre at the University of Bristol (http:// www.bristol.ac.uk/acrc).
Publisher Copyright:
Copyright © 2023 the Author(s). Published by PNAS. This open access article is distributed under Creative Commons Attribution License 4.0 (CC BY).
Structured keywords
- BrisSynBio
- Bristol BioDesign Institute
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Dive into the research topics of 'Cellular production of a de novo membrane cytochrome'. Together they form a unique fingerprint.Student theses
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Computation Design of Bioenergetic Membrane Proteins
Author: Hardy, B. J., 21 Mar 2023Supervisor: Curnow, P. (Supervisor) & Anderson, R. (Supervisor)
Student thesis: Doctoral Thesis › Doctor of Philosophy (PhD)
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HPC (High Performance Computing) and HTC (High Throughput Computing) Facilities
Sadaf R Alam (Manager), Steven A Chapman (Manager), Polly E Eccleston (Other), Simon H Atack (Other) & D A G Williams (Manager)
Facility/equipment: Facility