The soxRS response of Escherichia coli can be induced in the absence of oxidative stress and oxygen by modulation of NADPH content
The soxRS response of Escherichia coli can be induced in the absence of oxidative stress and oxygen by modulation of NADPH content
The soxRS regulon protects Escherichia coli cells against superoxide and nitric oxide. Oxidation of the SoxR sensor, a [2Fe-2S]-containing transcriptional regulator, triggers the response, but the nature of the cellular signal sensed by SoxR is still a matter of debate. In vivo, the sensor is maintained in a reduced, inactive state by the activities of SoxR reductases, which employ NADPH as an electron donor. The hypothesis that NADPH levels affect deployment of the soxRS response was tested by transforming E. coli cells with genes encoding enzymes and proteins that lead to either build-up or depletion of the cellular NADPH pool. Introduction of NADP(+)-reducing enzymes, such as wheat non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase or E. coli malic enzyme, led to NADPH accumulation, inhibition of the soxRS regulon and enhanced sensitivity to the superoxide propagator methyl viologen (MV). Conversely, expression of pea ferredoxin (Fd), a redox shuttle that can oxidize NADPH via ferredoxin-NADP(H) reductase, resulted in execution of the soxRS response in the absence of oxidative stress, and in higher tolerance to MV. Processes that caused NADPH decline, including oxidative stress and Fd activity, correlated with an increase in total (NADP(+)+NADPH) stocks. SoxS expression can be induced by Fd expression or by MV in anaerobiosis, under conditions in which NADPH is oxidized but no superoxide can be formed. The results indicate that activation of the soxRS regulon in E. coli cells exposed to superoxide-propagating compounds can be triggered by depletion of the NADPH stock rather than accumulation of superoxide itself. They also suggest that bacteria need to finely regulate homeostasis of the NADP(H) pool to enable proper deployment of this defensive response.
Krapp, Adriana R
f7851e9f-d748-4e95-a0b8-2553fee2bff9
Humbert, Maria
82134d25-24b8-4fdd-bd1c-461683b5322e
Carrillo, Nestor
87994e87-089f-45c2-b4d0-418dafc2510b
April 2011
Krapp, Adriana R
f7851e9f-d748-4e95-a0b8-2553fee2bff9
Humbert, Maria
82134d25-24b8-4fdd-bd1c-461683b5322e
Carrillo, Nestor
87994e87-089f-45c2-b4d0-418dafc2510b
Krapp, Adriana R, Humbert, Maria and Carrillo, Nestor
(2011)
The soxRS response of Escherichia coli can be induced in the absence of oxidative stress and oxygen by modulation of NADPH content.
Microbiology, 157 (4).
(doi:10.1099/mic.0.039461-0).
Abstract
The soxRS regulon protects Escherichia coli cells against superoxide and nitric oxide. Oxidation of the SoxR sensor, a [2Fe-2S]-containing transcriptional regulator, triggers the response, but the nature of the cellular signal sensed by SoxR is still a matter of debate. In vivo, the sensor is maintained in a reduced, inactive state by the activities of SoxR reductases, which employ NADPH as an electron donor. The hypothesis that NADPH levels affect deployment of the soxRS response was tested by transforming E. coli cells with genes encoding enzymes and proteins that lead to either build-up or depletion of the cellular NADPH pool. Introduction of NADP(+)-reducing enzymes, such as wheat non-phosphorylating glyceraldehyde-3-phosphate dehydrogenase or E. coli malic enzyme, led to NADPH accumulation, inhibition of the soxRS regulon and enhanced sensitivity to the superoxide propagator methyl viologen (MV). Conversely, expression of pea ferredoxin (Fd), a redox shuttle that can oxidize NADPH via ferredoxin-NADP(H) reductase, resulted in execution of the soxRS response in the absence of oxidative stress, and in higher tolerance to MV. Processes that caused NADPH decline, including oxidative stress and Fd activity, correlated with an increase in total (NADP(+)+NADPH) stocks. SoxS expression can be induced by Fd expression or by MV in anaerobiosis, under conditions in which NADPH is oxidized but no superoxide can be formed. The results indicate that activation of the soxRS regulon in E. coli cells exposed to superoxide-propagating compounds can be triggered by depletion of the NADPH stock rather than accumulation of superoxide itself. They also suggest that bacteria need to finely regulate homeostasis of the NADP(H) pool to enable proper deployment of this defensive response.
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Accepted/In Press date: 21 December 2010
e-pub ahead of print date: 22 December 2010
Published date: April 2011
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Local EPrints ID: 447560
URI: http://eprints.soton.ac.uk/id/eprint/447560
ISSN: 1350-0872
PURE UUID: 400816f1-8ea1-41d4-9e6a-20863c2905e0
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Date deposited: 16 Mar 2021 17:31
Last modified: 17 Mar 2024 03:35
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Author:
Adriana R Krapp
Author:
Maria Humbert
Author:
Nestor Carrillo
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