Proteolytic queues at ClpXP increase antibiotic tolerance

Deter, Heather S.; Abualrahi, Alawiah H.; Jadhav, Prajakta; Schweer, Elise K; Ogle, Curtis T.; Butzin, Nicholas C.

doi:10.1101/680504

Cited by 9 publications

(37 citation statements)

References 66 publications

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“…The higher persistence levels during ciprofloxacin treatment could be due to double-stranded DNA breaks caused by ciprofloxacin activating the SOS response (44) (the SOS response is directly related to persistence). We also observed that despite controlling methodology to the greatest extent possible, persister levels varied considerably (far more than observed in our previous work with E. coli) (7) between experiments for both streptomycin and ciprofloxacin treatments (Table S1). We hypothesize that this variability might be due to the stochastic fluctuations (noise) in gene expression levels, which results in protein level variations significantly even among genetically identical cells in a similar environment (45).…”

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confidence: 54%

“…Among them, proteases and associated chaperons are notable persister-related genes because overexpression and knockouts of these genes alter persistence levels (14,35). Furthermore, our lab recently demonstrated that interfering with protein degradation by forming a proteolytic queue at ClpXP will increase tolerance levels dramatically and in a tunable fashion (larger queues caused higher tolerance) (7). Research over the last several years has resulted in a lot of discussion concerning genes essential for persistence (8,13,26,29).…”

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confidence: 99%

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Antibiotic tolerance, persistence, and resistance of the evolved minimal cell,Mycoplasma mycoidesJCVI-Syn3B

Hossain

Deter²,

Peters

et al. 2020

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Antibiotic persisters are a small subpopulation of bacteria that tolerate antibiotics due to a physiologically dormant state. As a result, this phenomenon (persistence) is considered a major contributor to the evolution of antibiotic-resistant and relapsing infections. However, the precise molecular mechanisms of persistence are still unclear. To examine the key mechanisms of persistence, we used the synthetically developed minimal cell Mycoplasma mycoides JCVI-Syn3B; the genome contains <500 genes, which are mostly essential. We found that Syn3B evolves expeditiously and rapidly evolves antibiotic resistance to kasugamycin. The minimum cell also tolerates and persists against multiple antibiotics despite lacking many systems related to bacterial persistence (e.g. toxin-antitoxin systems). These results show that this minimal system is a suitable system to unravel the central regulatory mechanisms of persistence.

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confidence: 54%

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confidence: 99%

Antibiotic tolerance, persistence, and resistance of the evolved minimal cell,Mycoplasma mycoidesJCVI-Syn3B

Hossain

Deter²,

Peters

et al. 2020

Preprint

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“…Two advantages of this method are it allows for concentration of cells while minimizing time for RNA degradation, and we recover any whole cells present after antibiotic treatment regardless of viability (this includes cells that are considered "viable but not culturable" (VBNC), see Methods). This work builds off our previously reported results with antibiotic tolerance, and uses a similar setup with the same strains of E. coli 29 . The sequencing data was analyzed using DESeq and based on this analysis, we consider significant changes in gene expression to be greater than two-fold with an adjusted p-value <0.1.…”

Section: Resultsmentioning

confidence: 89%

“…Our findings show that many of the regulatory proteins activated during antibiotic stress are regulated by protein degradation. Protein aggregation was recently demonstrated in persister cells 25 , and our previous work shows that interfering with degradation at the protease ClpXP increases antibiotic tolerance in E. coli 29 . To confirm that the transcriptional changes are due to altered proteolysis, we then sequenced populations with slowed protein degradation using our previously established system 29 .…”

Section: Introductionmentioning

confidence: 87%

“…In addition to the regulation of MarA and SoxS through degradation, proteolytic processes play a vital role in antibiotic tolerance, as many previous works have suggested 29,[62][63] . These effects on the TRN during ampicillin treatment suggest that the activity of many transcription factors is controlled at the proteolytic level and that disruption of degradation during environmental stress leads to an increase in the activity of these TFs.…”

Section: Altered Proteolytic Activity Affects Transcriptional Regulatmentioning

confidence: 99%

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Antibiotic tolerance is associated with a broad and complex transcriptional response inE. coli

Deter

Hossain

Butzin

2020

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In a given bacterial population, antibiotic treatment will kill a large portion of the population, while a small, tolerant subpopulation will survive. Tolerant cells disrupt the efficacy of antibiotic treatment and increase the likelihood that a population gains antibiotic resistance. When a population becomes resistant, antibiotic treatment fails, which is a major health concern. Since antibiotic tolerance often leads to resistance, we have taken a systems biology approach to examine how transcriptional networks respond to antibiotic stress so that cells can survive and recover after antibiotic treatment. We have compared gene expression with and without ampicillin in E. coli. While many previous studies have identified aspects of the antibiotic stress response at either the protein or transcriptional level, our work leverages existing knowledge of transcriptional regulation to link the dynamics of the two allowing for a more holistic approach. Here, we are the first to develop a whole-cell, transcriptional regulatory network (TRN) of antibiotic tolerant subpopulations and examine how cells respond at the transcriptional level to bactericidal concentrations of an antibiotic. Using TRN analysis, we show how certain sigma and transcription factors are affecting transcriptional regulation under antibiotic stress, and that changes in gene expression specific to ampicillin treatment can be directly linked to cell survival and recovery. The resulting network demonstrates that cells are mounting an active and coordinated response to the antibiotic that spans multiple systems and pathways. The redundancy and interconnectivity of the networks suggest that accounting for whole-cell dynamics may be crucial when modeling and studying antibiotic tolerance in the future.

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Antibiotic tolerance, persistence, and resistance of the evolved minimal cell, Mycoplasma mycoides JCVI-Syn3B

et al. 2021

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Summary Antibiotic resistance is a growing problem, but bacteria can evade antibiotic treatment via tolerance and persistence. Antibiotic persisters are a small subpopulation of bacteria that tolerate antibiotics due to a physiologically dormant state. Hence, persistence is considered a major contributor to the evolution of antibiotic-resistant and relapsing infections. Here, we used the synthetically developed minimal cell Mycoplasma mycoides JCVI-Syn3B to examine essential mechanisms of antibiotic survival. The minimal cell contains only 473 genes, and most genes are essential. Its reduced complexity helps to reveal hidden phenomenon and fundamental biological principles can be explored because of less redundancy and feedback between systems compared to natural cells. We found that Syn3B evolves antibiotic resistance to different types of antibiotics expeditiously. The minimal cell also tolerates and persists against multiple antibiotics. It contains a few already identified persister-related genes, although lacking many systems previously linked to persistence (e.g. toxin-antitoxin systems, ribosome hibernation genes).

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Proteolytic queues at ClpXP increase antibiotic tolerance

Cited by 9 publications

References 66 publications

Antibiotic tolerance, persistence, and resistance of the evolved minimal cell,Mycoplasma mycoidesJCVI-Syn3B

Antibiotic tolerance, persistence, and resistance of the evolved minimal cell,Mycoplasma mycoidesJCVI-Syn3B

Antibiotic tolerance is associated with a broad and complex transcriptional response inE. coli

Antibiotic tolerance, persistence, and resistance of the evolved minimal cell, Mycoplasma mycoides JCVI-Syn3B

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