A Bacterial Stress Response Regulates Respiratory Protein Complexes To Control Envelope Stress Adaptation

Guest, Randi L.; Wang, Junshu; Wong, Julia L.; Raivio, Tracy

doi:10.1128/jb.00153-17

Cited by 59 publications

(75 citation statements)

References 78 publications

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“…If it is true that the targets of downregulation are proteins that cause the stress in the first place, deletion of these genes might relieve the stress; that is what Raivio and coworkers find. Thus, in a cpxR mutant, when the cell cannot properly mount a Cpx response, cells are killed by treatment with sublethal doses of the antibiotic amikacin or high pH, but deletion of either the nuo or the cyo gene relieves this lethality (5). Strikingly, deletion of these gene clusters also significantly lowers the induction of a Cpx reporter normally induced as cells enter stationary phase.…”

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confidence: 99%

Stress Reduction, Bacterial Style

Gottesman

2017

J Bacteriol

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Bacteria have robust responses to a variety of stresses. In particular, bacteria like Escherichia coli have multiple cell envelope stress responses, and generally we evaluate what these responses are doing by the repair systems they induce. However, probably at least as important in interpreting what is being sensed as stress are the genes that these stress systems downregulate, directly or indirectly. This is discussed here for the Cpx and sigma E systems of E. coli.

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confidence: 99%

Stress Reduction, Bacterial Style

Gottesman

2017

J Bacteriol

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“…Several lipoproteins, misfolded pilin subunits of uropathogenic E. coli , and inner membrane respiratory complexes are known inducers of the Cpx pathway [33, 35, 47, 48]. Although the details of Cpx activation by these envelope components remains largely elusive, there are two suggested mechanisms.…”

Section: Discussionmentioning

confidence: 99%

Metabolism of long-chain fatty acids affects disulfide bond formation inEscherichia coliand activates envelope stress response pathways as a combat strategy

Jaswal

Shrivastava

Roy

et al. 2020

Preprint

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The envelope of gram-negative bacteria serves as the first line of defense against environmental insults. Therefore, its integrity is continuously monitored and maintained by several envelope stress response (ESR) systems. Due to its oxidizing environment, the envelope represents an important site for disulfide bond formation. In Escherichia coli, the periplasmic oxidoreductase, DsbA introduces disulfide bonds in substrate proteins and transfers electrons to the inner membrane oxidoreductase, DsbB. Under aerobic conditions, the reduced form of DsbB is re-oxidized by ubiquinone, an electron carrier in the electron transport chain (ETC). Given the critical role of ubiquinone in transferring electrons derived from the oxidation of reduced cofactors, we were intrigued whether metabolic conditions that generate a large number of reduced cofactors render ubiquinone unavailable for disulfide bond formation. To test this, here we investigated the influence of metabolism of long-chain fatty acid (LCFA), an energy-rich carbon source, on the redox state of the envelope. We show that LCFA degradation increases electron flow in the ETC. Further, we find that whereas cells metabolizing LCFAs exhibit several characteristics of insufficient disulfide bond formation, these hallmarks are averted in cells exogenously provided with ubiquinone. Importantly, the ESR pathways, Cpx and σE, are activated by envelope signals generated during LCFA metabolism, and these systems maintain proper disulfide bond formation. We find that σE downregulation hampers disulfide bond formation only in the absence of Cpx, and amongst the two ESR systems, only Cpx senses redox-dependent signal and is induced to a greater extent by LCFAs. Therefore, we argue that Cpx is the primary ESR that senses and maintains envelope redox homeostasis. Taken together, our results demonstrate an intricate relationship between cellular metabolism and disulfide bond formation dictated by ETC and ESR, and provide the basis for examining whether similar mechanisms control envelope redox status in other gram-negative bacteria.Author summaryDisulfide bonds contribute to the folding and stability of many extracytoplasmic proteins in all domains of life. In gram-negative bacteria, including Escherichia coli, disulfide bond formation occurs in the oxidizing environment of the periplasmic space enclosed within the outer and inner membrane layers of the envelope. Because disulfide-bonded proteins are involved in diverse biological processes, bacteria must monitor the envelope redox status and elicit an appropriate response when perturbations occur; however, these mechanisms are not well elucidated. Here, we demonstrated that the metabolism of an energy-rich carbon source, long-chain fatty acid (LCFA) hampers disulfide bond formation in E. coli. An envelope stress response (ESR) system, Cpx, senses this redox imbalance and maintains proper disulfide bond formation. The σE pathway, another ESR system, plays an ancillary role in maintaining redox homeostasis. LCFA metabolism, disulfide bond formation, and ESR systems have independently been implicated in the pathogenesis of several gram-negative bacteria. The present study sets the basis to explore whether LCFA metabolism impacts the virulence of these bacteria by influencing the redox status of their envelope and activation of ESR pathways.

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“…The second 275 possibility is that activation of the Cpx response, or another regulatory system, by deleting tolC 276 reduces expression of NDH-I or NDH-II. In support of this hypothesis, CpxR has been shown to 277 directly repress the transcription of the operon encoding NDH-I(Guest et al, 2017). At this 278 point, we are unable to distinguish between these two possibilities.…”

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“…Under 171 aerobic conditions, electrons released from β-NADH by NDH-I or NDH-II are first transferred to 172 ubiquinone and then to a terminal oxidase, such as cytochrome bo 3 . Given that activity of the 173 NADH oxidation arm of the aerobic respiratory chain is impaired in the tolC mutant (figure 3), 174 and that NDH-I and cytochrome bo 3 contribute to Cpx pathway activity in enteropathogenic E. 175 coli(Guest et al, 2017), we next asked whether NDH-I, NDH-II, or cytochrome bo 3 are required 176 for activation of the Cpx response in the tolC mutant. To test this hypothesis, we mutated each 177 of these electron transport chain components in E. coli containing or lacking tolC and measured 178Cpx pathway activity using the cpxP-lacZ transcriptional reporter.…”

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Impaired Efflux of the Siderophore Enterobactin Induces Envelope Stress inEscherichia coli

Guest

Court

Waldon

et al. 2019

Preprint

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21The Cpx response is one of several envelope stress responses that monitor and 22 maintain the integrity of the gram-negative bacterial envelope. While several conditions that are 23 known or predicted to generate misfolded inner membrane proteins activate the Cpx response, 24 the molecular nature of the Cpx inducing cue is not yet known. Studies have demonstrated that 25 mutation of multidrug efflux pumps activates the Cpx response in many gram-negative bacteria. 26In Vibrio cholerae, pathway activation is due to accumulation of the catechol siderophore 27 vibriobactin. However, the mechanism by which the Cpx response is activated by mutation of 28 efflux pumps in Escherichia coli remains unknown. Here we show that inhibition of efflux by 29 deletion of tolC, the outer membrane channel of several multidrug efflux pumps, activates the 30 Cpx response in E. coli as a result of impaired efflux of the siderophore enterobactin. 31Enterobactin accumulation in the tolC mutant reduces activity of the NADH oxidation arm of the 32 aerobic respiratory chain. However, NADH dehydrogenase I, NADH dehydrogenase II, and 33 cytochrome bo 3 do not contribute to Cpx pathway activation in the E. coli tolC mutant. We show 34 that the Cpx response down-regulates transcription of the enterobactin biosynthesis operon. 35These results suggest that the Cpx response promotes adaptation to envelope stress in enteric 36 bacteria that are exposed to iron-limited environments, which are rich in envelope-damaging 37 compounds and conditions. 38 Wiriyathanawudhiwong et al., 2009). Furthermore, accumulation of several metabolites 58 increases expression of the TolC-dependent AcrAB multidrug efflux system as a compensatory 59 mechanism to increase metabolite secretion (Helling et al., 2002;Ruiz and Levy, 2014). 60Blocking metabolite secretion by mutating tolC or TolC-dependent efflux systems increases 61 sensitivity to cysteine, the siderophore enterobactin, and intermediates of heme biosynthesis, 62suggesting that metabolite accumulation is toxic (Tatsumi and Wachi, 2008; Vega and Young, 63 2014;Wiriyathanawudhiwong et al., 2009). In support of this hypothesis, numerous cellular 109 Iron limitation induces the Cpx response in the tolC mutant 110To confirm that inhibition of efflux activates the Cpx response in E. coli, we measured 111 Cpx pathway activity in a tolC mutant using a cpxP-lacZ transcriptional reporter. No change in 112 cpxP-lacZ reporter activity was observed when E. coli were grown in LB ( figure 1A). This was 113 surprising given that under similar growth conditions, expression of the periplasmic chaperone 114Spy has been shown to increase in a tolC mutant via the Cpx response (Acosta et al., 2014; 115 Rosner and Martin, 2013). Nonetheless, when E. coli were grown in M9 minimal medium we 116 observed a nearly eleven-fold increase in cpxP-lacZ activity in the tolC mutant ( figure 1A). This 117 increase was abolished in E. coli lacking cpxA ( figure 1B), suggesting that inhibition of efflux 118 generates envelope stress that ...

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A Bacterial Stress Response Regulates Respiratory Protein Complexes To Control Envelope Stress Adaptation

Cited by 59 publications

References 78 publications

Stress Reduction, Bacterial Style

Stress Reduction, Bacterial Style

Metabolism of long-chain fatty acids affects disulfide bond formation inEscherichia coliand activates envelope stress response pathways as a combat strategy

Impaired Efflux of the Siderophore Enterobactin Induces Envelope Stress inEscherichia coli

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