A Proteomic Signature of Dormancy in the Actinobacterium Micrococcus luteus

Mali, Sujina; Mitchell, Morgan W.; Havis, Spencer; Bodunrin, Abiodun; Rangel, Jonathan; Olson, Gabriella; Widger, William R.; Bark, Steven J.

doi:10.1128/jb.00206-17

Cited by 24 publications

(41 citation statements)

References 89 publications

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“…The VBNC state describes a subpopulation of bacteria that have transiently lost their ability to grow on routine laboratory media on which they were previously able to grow. These cells exhibit significantly lower, although present, metabolic activity than their actively growing counterparts, and they continue to maintain membrane integrity and produce proteins (10,11). In Fig.…”

Section: The Vbnc Statementioning

confidence: 99%

“…As suggested above, it is important to recognize that neither VBNC cells nor persisters are metabolically inept. Although there is a large decline in metabolic activity in these cells, they continue to energize their membranes and produce a more specialized set of proteins (10,79). There are several mechanisms by which persister cells are thought to form, and there is growing evidence that these same mechanisms are involved in directing the VBNC state.…”

Section: Overlapping Molecular Mechanismsmentioning

confidence: 99%

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Relationship between the Viable but Nonculturable State and Antibiotic Persister Cells

2018

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Bacteria have evolved numerous means of survival in adverse environments with dormancy, as represented by "persistence" and the "viable but nonculturable" (VBNC) state, now recognized to be common modes for such survival. VBNC cells have been defined as cells which, induced by some stress, become nonculturable on media that would normally support their growth but which can be demonstrated by various methods to be alive and capable of returning to a metabolically active and culturable state. Persister cells have been described as a population of cells which, while not being antibiotic resistant, are antibiotic tolerant. This drug-tolerant phenotype is thought to be a result of stress-induced and stochastic physiological changes as opposed to mutational events leading to true resistance. In this review, we describe these two dormancy strategies, characterize the molecular underpinnings of each state, and highlight the similarities and differences between them. We believe these survival modes represent a continuum between actively growing and dead cells, with VBNC cells being in a deeper state of dormancy than persister cells.

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Section: The Vbnc Statementioning

confidence: 99%

Section: Overlapping Molecular Mechanismsmentioning

confidence: 99%

Relationship between the Viable but Nonculturable State and Antibiotic Persister Cells

2018

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“…However, they can grow and divide again when culture conditions are more favorable for their metabolic recovery as a consequence the bacteria can thereafter express their pathogenicity again ( Emerson et al, 2017 ). Thus VBNC bacteria represent a significant risk in many domains such as medical field ( Passerat et al, 2009 ; Dinu and Bach, 2011 ; Zandri et al, 2012 ; Mali et al, 2017 ; Lee and Bae, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

Contribution of Fluorescence Techniques in Determining the Efficiency of the Non-thermal Plasma Treatment

et al. 2018

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We have recently developed a non-thermal plasma (NTP) equipment intended to sterilize fragile medical devices and maintain the sterile state of items downstream the treatment. With traditional counts on agar plate a six log reduction of Staphylococcus aureus viability was obtained within 120 min of O2, Ar, or N2 NTP treatments. However to determine the best NTP process, we studied the different physiological states of S. aureus by flow cytometry (FC) and confocal laser scanning microscopy (CLSM) focusing on the esterasic activity and membrane integrity of the bacteria. Two fluorochromes, 5-(and-6)-carboxy-2′,7′-dichlorofluorescein diacetate and propidium iodide were used in order to distinguish three sub-populations: metabolically active, permeabilized, and damaged bacteria that can be in the viable but nonculturable state. FC and CLSM highlight that O2 and Ar NTP treatments were the most attractive processes. Indeed, a 5 min of Ar NTP generated a high destruction of the structure of bacteria and a 120 min of O2 NTP treatment led to the higher decrease of the total damaged bacteria population. SEM observations showed that in presence of clusters, bacteria of upper layers are easily altered compared to bacteria in the deeper layers. In conclusion, the plate counting method is not sufficient by itself to determine the best NTP treatment. FC and CLSM represent attractive indicator techniques to select the most efficient gas NTP treatment generating the lowest proportion of viable bacteria and the most debris.

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“…As expected, there was an increase in the expression of many genes regulated by sigma factors related to stationary phase and heat shock, which have previously been associated with antibiotic tolerance and cellular stress response pathways [25][26] . Namely, RpoH (σ 32 ; associated with heat shock 41 ), RpoS (σ 38 ; associated with stationary phase and stress 42 ), and RpoE (σ 24 ; also associated with heat shock 43 ) had more active regulons in the treated compared to the untreated population. Our analysis shows that RpoH transcribes many genes related to one of the COG groups noted earlier, 'posttranslational modification, protein turnover and chaperones'.…”

Section: Clusters Of Orthologous Groups (Cogs) During Ampicillin Treamentioning

confidence: 99%

“…Many studies suggest that persisters are metabolically repressed, particularly with respect to translation, while others propose that active metabolism plays a vital role in persistence [16][17][18][19][20] . A few studies have leveraged RNA-sequencing (RNA-seq) [20][21][22] and proteomic data [23][24][25] , and they have identified several individual genes and systems related to antibiotic tolerance. Sigma factors and transcription factors, regulatory proteins that affect gene expression, are two classes of protein in which many individual genes have been related to antibiotic stress 15,[25][26][27][28] .…”

Section: Introductionmentioning

confidence: 99%

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

Deter

Hossain

Butzin

2020

Preprint

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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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A Proteomic Signature of Dormancy in the Actinobacterium Micrococcus luteus

Cited by 24 publications

References 89 publications

Relationship between the Viable but Nonculturable State and Antibiotic Persister Cells

Relationship between the Viable but Nonculturable State and Antibiotic Persister Cells

Contribution of Fluorescence Techniques in Determining the Efficiency of the Non-thermal Plasma Treatment

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

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