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Bacterial sensors define intracellular free energies for correct enzyme metalation

Bacterial sensors define intracellular free energies for correct enzyme metalation
Bacterial sensors define intracellular free energies for correct enzyme metalation
There is a challenge for metalloenzymes to acquire their correct metals because some inorganic elements form more stable complexes with proteins than do others. These preferences can be overcome provided some metals are more available than others. However, while the total amount of cellular metal can be readily measured, the available levels of each metal have been more difficult to define. Metal-sensing transcriptional regulators are tuned to the intracellular availabilities of their cognate ions. Here we have determined the standard free energy for metal complex formation to which each sensor, in a set of bacterial metal sensors, is attuned: the less competitive the metal, the less favorable the free energy and hence the greater availability to which the cognate allosteric mechanism is tuned. Comparing these free energies with values derived from the metal affinities of a metalloprotein reveals the mechanism of correct metalation exemplified here by a cobalt chelatase for vitamin B12.
1552-4450
241-249
Osman, Deenah
7771ca9d-9150-4046-a4e7-10ce3950342a
Martini, Maria Alessandra
d380578e-1af9-4b50-a70c-f7227e8738dc
Foster, Andrew W.
e12c139f-cb45-4bed-ae80-821e9b540f3d
Chen, Junjun
7a962b14-7819-48c0-8dc7-2ed35879bf68
Scott, Andrew J.P.
b1f6a7ca-61af-47cd-973f-93b4f1564aed
Morton, R J
f5343e1f-72f2-45e7-88c8-e55517992ac9
Steed, Jonathan W.
97a5b8f6-b374-454d-a0b4-0bcaf37aa962
Lurie-Luke, Elena
bc47da35-78d2-4945-9dd0-b3d5a9c78231
Huggins, Thomas G.
5ee37706-5425-4304-881d-94c65d1a1e88
Lawrence, Andrew D.
ce503b40-0155-486f-bb1d-26830b61b5f1
Deery, Evelyne
16c10c8d-1383-4ce6-95dd-dfcfa0168875
Warren, Martin
8e3460cb-4b1d-4868-81e8-a2672676095f
Chivers, Peter
538132d7-de0b-45c1-b7f5-d74c7517694d
Robinson, Nigel
f8f5611e-b9e0-4fa2-90eb-a78d674c4bbe
et al.
Osman, Deenah
7771ca9d-9150-4046-a4e7-10ce3950342a
Martini, Maria Alessandra
d380578e-1af9-4b50-a70c-f7227e8738dc
Foster, Andrew W.
e12c139f-cb45-4bed-ae80-821e9b540f3d
Chen, Junjun
7a962b14-7819-48c0-8dc7-2ed35879bf68
Scott, Andrew J.P.
b1f6a7ca-61af-47cd-973f-93b4f1564aed
Morton, R J
f5343e1f-72f2-45e7-88c8-e55517992ac9
Steed, Jonathan W.
97a5b8f6-b374-454d-a0b4-0bcaf37aa962
Lurie-Luke, Elena
bc47da35-78d2-4945-9dd0-b3d5a9c78231
Huggins, Thomas G.
5ee37706-5425-4304-881d-94c65d1a1e88
Lawrence, Andrew D.
ce503b40-0155-486f-bb1d-26830b61b5f1
Deery, Evelyne
16c10c8d-1383-4ce6-95dd-dfcfa0168875
Warren, Martin
8e3460cb-4b1d-4868-81e8-a2672676095f
Chivers, Peter
538132d7-de0b-45c1-b7f5-d74c7517694d
Robinson, Nigel
f8f5611e-b9e0-4fa2-90eb-a78d674c4bbe

Osman, Deenah, Martini, Maria Alessandra and Foster, Andrew W. , et al. (2019) Bacterial sensors define intracellular free energies for correct enzyme metalation. Nature Chemical Biology, 15, 241-249. (doi:10.1038/s41589-018-0211-4).

Record type: Article

Abstract

There is a challenge for metalloenzymes to acquire their correct metals because some inorganic elements form more stable complexes with proteins than do others. These preferences can be overcome provided some metals are more available than others. However, while the total amount of cellular metal can be readily measured, the available levels of each metal have been more difficult to define. Metal-sensing transcriptional regulators are tuned to the intracellular availabilities of their cognate ions. Here we have determined the standard free energy for metal complex formation to which each sensor, in a set of bacterial metal sensors, is attuned: the less competitive the metal, the less favorable the free energy and hence the greater availability to which the cognate allosteric mechanism is tuned. Comparing these free energies with values derived from the metal affinities of a metalloprotein reveals the mechanism of correct metalation exemplified here by a cobalt chelatase for vitamin B12.

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Accepted/In Press date: 4 December 2018
e-pub ahead of print date: 28 January 2019
Learn more about School of Biological Sciences research

Identifiers

Local EPrints ID: 488471
URI: http://eprints.soton.ac.uk/id/eprint/488471
DOI: doi:10.1038/s41589-018-0211-4
ISSN: 1552-4450
PURE UUID: a1f6dbcb-89e6-4ed2-810c-b5a90e015f35
ORCID for Andrew D. Lawrence: ORCID iD orcid.org/0000-0002-5853-5409

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Date deposited: 22 Mar 2024 17:57
Last modified: 23 Mar 2024 03:10

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Contributors

Author: Deenah Osman
Author: Maria Alessandra Martini
Author: Andrew W. Foster
Author: Junjun Chen
Author: Andrew J.P. Scott
Author: R J Morton
Author: Jonathan W. Steed
Author: Elena Lurie-Luke
Author: Thomas G. Huggins
Author: Andrew D. Lawrence ORCID iD
Author: Evelyne Deery
Author: Martin Warren
Author: Peter Chivers
Author: Nigel Robinson
Corporate Author: et al.

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