Deciphering the essentiality and function of the anti‐σ<sup>M</sup> factors in <i>Bacillus subtilis</i>

Zhao, Heng; Roistacher, Daniel M.; Helmann, John D.

doi:10.1111/mmi.14216

Cited by 15 publications

(21 citation statements)

References 69 publications

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“…The concentrations and affinities of individual sigma factors influence their competition for the core RNAP [59,60]. While sigma factor competition is best studied in E. coli, it has been observed in other organisms, including P. aeruginosa [47,59,[61][62][63]. One such example in P.…”

Section: Discussionmentioning

confidence: 99%

The anti-sigma factor MucA is required for viability inPseudomonas aeruginosa

Schofield

Rodriguez

Kidman

et al. 2020

Preprint

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Pseudomonas aeruginosa causes chronic lung infections in people with cystic fibrosis (CF), and this bacterium undergoes selection in the CF lung environment over the course of these life-long infections. One genetic adaptation frequently observed in CF P. aeruginosa isolates is mutation of mucA. MucA inhibits the sigma factor AlgU. Clinical mucA mutations lead to misregulation of AlgU, resulting in a mucoid bacterial phenotype that is associated with poor CF disease outcomes. Here we show that paradoxically a portion of the mucA gene is essential for P. aeruginosa viability. We demonstrate that mucA is no longer essential in a strain lacking algU, and mucA alleles that encode for proteins that do not bind to AlgU are insufficient for bacterial viability. Furthermore, we found that mucA is no longer essential in mutant strains containing AlgU variants with reduced sigma factor activity, suggesting that reducing AlgU activity can suppress the requirement for mucA. Finally, we found that overexpression of algU from an inducible promoter prevents cell growth in the absence of MucA, and that this phenotype can be rescued by overproduction of RpoD, the housekeeping sigma factor. Together, these results suggest that in the absence of MucA, the inability to regulate AlgU activity leads to sigma factor competition, preventing the expression of essential housekeeping genes and resulting in the loss of bacterial viability.

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Section: Discussionmentioning

confidence: 99%

The anti-sigma factor MucA is required for viability inPseudomonas aeruginosa

Schofield

Rodriguez

Kidman

et al. 2020

Preprint

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“…Expression of BcrC is primarily controlled by the extracytoplasmic function sigma factor M (14,30). While the physiological input triggering activation of M still remains elusive (31,32), the broad range of inducing conditions, including cell wall antibiotics, salt, ethanol, and others, suggests that it is not a specific chemical compound but rather a cellular cue upon cell envelope damage that activates the M response (33). Interestingly, despite the seemingly unrelated input stimuli for the BceAB and the BcrC resistance modules-with BceAB being activated by a "drugsensing" mechanism (antibiotic flux) and BcrC by a "damage-sensing" mechanismprevious work revealed that there is a high level of interdependency between the modules (26).…”

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confidence: 99%

From Modules to Networks: a Systems-Level Analysis of the Bacitracin Stress Response in Bacillus subtilis

et al. 2020

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Bacterial resistance against antibiotics often involves multiple mechanisms that are interconnected to ensure robust protection. So far, the knowledge about underlying regulatory features of those resistance networks is sparse, since they can hardly be determined by experimentation alone. Here, we present the first computational approach to elucidate the interplay between multiple resistance modules against a single antibiotic and how regulatory network structure allows the cell to respond to and compensate for perturbations of resistance. Based on the response of Bacillus subtilis toward the cell wall synthesis-inhibiting antibiotic bacitracin, we developed a mathematical model that comprehensively describes the protective effect of two well-studied resistance modules (BceAB and BcrC) on the progression of the lipid II cycle. By integrating experimental measurements of expression levels, the model accurately predicts the efficacy of bacitracin against the B. subtilis wild type as well as mutant strains lacking one or both of the resistance modules. Our study reveals that bacitracin-induced changes in the properties of the lipid II cycle itself control the interplay between the two resistance modules. In particular, variations in the concentrations of UPP, the lipid II cycle intermediate that is targeted by bacitracin, connect the effect of the BceAB transporter and the homeostatic response via BcrC to an overall resistance response. We propose that monitoring changes in pathway properties caused by a stressor allows the cell to fine-tune deployment of multiple resistance systems and may serve as a cost-beneficial strategy to control the overall response toward this stressor. IMPORTANCE Antibiotic resistance poses a major threat to global health, and systematic studies to understand the underlying resistance mechanisms are urgently needed. Although significant progress has been made in deciphering the mechanistic basis of individual resistance determinants, many bacterial species rely on the induction of a whole battery of resistance modules, and the complex regulatory networks controlling these modules in response to antibiotic stress are often poorly understood. In this work we combined experiments and theoretical modeling to decipher the resistance network of Bacillus subtilis against bacitracin, which inhibits cell wall biosynthesis in Gram-positive bacteria. We found a high level of cross-regulation between the two major resistance modules in response to bacitracin stress and quantified their effects on bacterial resistance. To rationalize our experimental data, we expanded a previously established computational model for the lipid II cycle through incorporating the quantitative action of the resistance modules. This led us to a systems-level description of the bacitracin stress response network that captures the complex interplay between resistance modules and the essential lipid II cycle of cell wall biosynthesis and accurately predicts the minimal inhibitory bacitracin concentration in all the studied mutants. With this, our study highlights how bacterial resistance emerges from an interlaced network of redundant homeostasis and stress response modules.

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“…However, full YhdL activity requires a second transmembrane protein, YhdK. Although a lack of σ M is well tolerated under unstressed conditions, the lack of the anti-σ M factors leads to a runaway activation of the autoregulated sigM operon, and overexpression of the σ M regulon [10]. A null mutation of yhdK leads to an ~100-fold elevation of σ M activity, morphological abnormalities, and slow growth [10].…”

Section: Introductionmentioning

confidence: 99%

“…Although a lack of σ M is well tolerated under unstressed conditions, the lack of the anti-σ M factors leads to a runaway activation of the autoregulated sigM operon, and overexpression of the σ M regulon [10]. A null mutation of yhdK leads to an ~100-fold elevation of σ M activity, morphological abnormalities, and slow growth [10]. A null mutation in yhdL is lethal, but suppressors arise readily that have inactivated sigM and grow normally in unstressed conditions [4, 10].…”

Section: Introductionmentioning

confidence: 99%

Mutations of the Bacillus subtilis YidC1 (SpoIIIJ) insertase alleviate stress associated with σM-dependent membrane protein overproduction

2019

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In Bacillus subtilis, the extracytoplasmic function σ factor σM regulates cell wall synthesis and is critical for intrinsic resistance to cell wall targeting antibiotics. The anti-σ factors YhdL and YhdK form a complex that restricts the basal activity of σM, and the absence of YhdL leads to runaway expression of the σM regulon and cell death. Here, we report that this lethality can be suppressed by gain-of-function mutations in yidC1 (spoIIIJ), which encodes the major YidC membrane protein insertase in B. subtilis. B. subtilis PY79 YidC1 (SpoIIIJ) contains a single amino acid substitution in a functionally important hydrophilic groove (Q140K), and this allele suppresses the lethality of high σM. Analysis of a library of YidC1 variants reveals that increased charge (+2 or +3) in the hydrophilic groove can compensate for high expression of the σM regulon. Derepression of the σM regulon induces secretion stress, oxidative stress and DNA damage responses, all of which can be alleviated by the YidC1Q140K substitution. We further show that the fitness defect caused by high σM activity is exacerbated in the absence of the SecDF protein translocase or σM-dependent induction of the Spx oxidative stress regulon. Conversely, cell growth is improved by mutation of specific σM-dependent promoters controlling operons encoding integral membrane proteins. Collectively, these results reveal how the σM regulon has evolved to up-regulate membrane-localized complexes involved in cell wall synthesis, and to simultaneously counter the resulting stresses imposed by regulon induction.

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Deciphering the essentiality and function of the anti‐σ^M factors in Bacillus subtilis

Cited by 15 publications

References 69 publications

The anti-sigma factor MucA is required for viability inPseudomonas aeruginosa

The anti-sigma factor MucA is required for viability inPseudomonas aeruginosa

From Modules to Networks: a Systems-Level Analysis of the Bacitracin Stress Response in Bacillus subtilis

Mutations of the Bacillus subtilis YidC1 (SpoIIIJ) insertase alleviate stress associated with σM-dependent membrane protein overproduction

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Deciphering the essentiality and function of the anti‐σM factors in Bacillus subtilis

Cited by 15 publications

References 69 publications

The anti-sigma factor MucA is required for viability inPseudomonas aeruginosa

The anti-sigma factor MucA is required for viability inPseudomonas aeruginosa

From Modules to Networks: a Systems-Level Analysis of the Bacitracin Stress Response in Bacillus subtilis

Mutations of the Bacillus subtilis YidC1 (SpoIIIJ) insertase alleviate stress associated with σM-dependent membrane protein overproduction

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Deciphering the essentiality and function of the anti‐σ^M factors in Bacillus subtilis