The Colicin E1 TolC Box: Identification of a Domain Required for Colicin E1 Cytotoxicity and TolC Binding

Jakes, Karen S.

doi:10.1128/jb.00412-16

Cited by 14 publications

(30 citation statements)

References 48 publications

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“…3 A ). This observation is notable in light of the fact that, in previous studies, similar peptides were shown to bind TolC (18, 20) and to occlude the channel, as reflected in diminished conductance (18, 19). These studies, however, did not investigate the effects of colicin E1 fragments on the efflux function of the pump.…”

Section: Resultssupporting

confidence: 51%

“…In particular, peptides including residues 100-120 of colicin E1 (termed the ‘TolC box’), with additional amino acids at the C-terminus of the ‘box’, have been shown to co-elute with TolC (18) and to disrupt channel conductance (19). A subsequent study confirmed the identity of the minimal T-domain segment that binds TolC, showing that E. coli exposure to peptides comprising residues 100–120 is sufficient to prevent subsequent binding of full-length colicin E1 (as reflected in the fact that the bacteria were protected from the colicin’s cytotoxic effects (20)). Notably, none of these studies investigated the effects of exposure to colicin E1 fragments on TolC’s efflux activity.…”

Section: Introductionmentioning

confidence: 85%

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Colicin E1 opens its hinge to plug TolC

Budiardjo

Stevens

Calkins

et al. 2019

Preprint

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17The double membrane architecture of Gram-negative bacteria forms a barrier 18 that is effectively impermeable to extracellular threats. Accordingly, researchers have 19shown increasing interest in developing antibiotics that target the accessible, surface-20 exposed proteins embedded in the outer membrane. TolC forms the outer membrane 21 channel of an antibiotic efflux pump in Escherichia coli. Drawing from prior observations 22 that colicin E1, a toxin produced by and lethal to E. coli, can bind to the TolC channel, 23we investigate the capacity of colicin E1 fragments to 'plug' TolC and inhibit its efflux 24 function. First, using single-molecule fluorescence, we show that colicin E1 fragments 25 that do not include the cytotoxic domain localize at the cell surface. Next, using real-time 26 efflux measurements and minimum inhibitory concentration assays, we show that 27 exposure of wild-type E. coli to fragments of colicin E1 indeed disrupts TolC efflux and 28 heightens bacterial susceptibility to four common classes of antibiotics. This work 29 demonstrates that extracellular plugging of outer membrane transporters can serve as a 30 novel method to increase antibiotic susceptibility. In addition to the utility of these protein 31 fragments as starting points for the development of novel antibiotic potentiators, the 32 variety of outer membrane protein colicin binding partners provides an array of options 33 that would allow our method to be used to inhibit other outer membrane protein 34 functions. 35 36Significance 37 We find that fragments of a protein natively involved in intraspecies bacterial 38 warfare can be exploited to plug the E. coli outer membrane antibiotic efflux machinery. 39This plugging disables a primary form of antibiotic resistance. Given the diversity of 40 bacterial species of similar bacterial warfare protein targets, we anticipate that this 41 3 method of plugging is generalizable to disabling the antibiotic efflux of other 42 proteobacteria. Moreover, given the diversity of the targets of bacterial warfare proteins, 43 this method could be used for disabling the function of a wide variety of other bacterial 44 outer membrane proteins. 45 46

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Section: Resultssupporting

confidence: 51%

Section: Introductionmentioning

confidence: 85%

Colicin E1 opens its hinge to plug TolC

Budiardjo

Stevens

Calkins

et al. 2019

Preprint

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show abstract

“…Another curious finding is the structural homology of AcrA to colicin E3 (Fig. 7a-c, RMSD = 0.85 Å), which interacts with BtuB (vitamin B12 receptor), a β-barrel OM protein similar to TolC 52,53 . We have used the colicin homology to suggest possible modes of AcrA binding to TolC (Fig.…”

Section: Discussionmentioning

confidence: 99%

Dead cells release a ‘necrosignal’ that activates antibiotic survival pathways in bacterial swarms

2020

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Swarming is a form of collective bacterial motion enabled by flagella on the surface of semisolid media. Swarming populations exhibit non-genetic or adaptive resistance to antibiotics, despite sustaining considerable cell death. Here, we show that antibiotic-induced death of a sub-population benefits the swarm by enhancing adaptive resistance in the surviving cells. Killed cells release a resistance-enhancing factor that we identify as AcrA, a periplasmic component of RND efflux pumps. The released AcrA interacts on the surface of live cells with an outer membrane component of the efflux pump, TolC, stimulating drug efflux and inducing expression of other efflux pumps. This phenomenon, which we call 'necrosignaling', exists in other Gram-negative and Gram-positive bacteria and displays species-specificity. Given that adaptive resistance is a known incubator for evolving genetic resistance, our findings might be clinically relevant to the rise of multidrug resistance.

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“…Over 20 colicins have been studied and the functional diversity of colicins offers unique cell-killing mechanisms ( 1 ). For example, colicins Ia ( 5 ) and E1 ( 6 ) form pores on the inner membrane, colicin M inhibits cell-wall biosynthesis by degrading an undecaprenyl phosphate-linked peptidoglycan precursor ( 7 ), colicin E2 degrades DNA templates ( 8 ) and colicin E3 degrades 16S ribosomal RNA resulting in slow translation ( 9 ). Therefore, colicins can target specific microbes by penetrating cells and disrupting cellular components.…”

Section: Introductionmentioning

confidence: 99%

Rapid production and characterization of antimicrobial colicins using Escherichia coli-based cell-free protein synthesis

et al. 2018

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Colicins are antimicrobial proteins produced by Escherichia coli, which, upon secretion from the host, kill non-host E. coli strains by forming pores in the inner membrane and degrading internal cellular components such as DNA and RNA. Due to their unique cell-killing activities, colicins are considered viable alternatives to conventional antibiotics. Recombinant production of colicins requires co-production of immunity proteins to protect host cells; otherwise, the colicins are lethal to the host. In this study, we used cell-free protein synthesis (CFPS) to produce active colicins without the need for protein purification and co-production of immunity proteins. Cell-free synthesized colicins were active in killing model E. coli cells with different modes of cytotoxicity. Pore-forming colicins E1 and nuclease colicin E2 killed actively growing cells in a nutrient-rich medium, but the cytotoxicity of colicin Ia was low compared to E1 and E2. Moreover, colicin E1 effectively killed cells in a nutrient-free solution, while the activity of E2 was decreased compared to nutrient-rich conditions. Both colicins E1 and E2 decreased the level of persister cells (metabolically dormant cell populations that are insensitive to antibiotics) by up to six orders of magnitude compared to that of the rifampin pretreated persister cells. This study finds that colicins can eradicate non-growing cells including persisters, and that CFPS is a promising platform for rapid production and characterization of toxic proteins.

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The Colicin E1 TolC Box: Identification of a Domain Required for Colicin E1 Cytotoxicity and TolC Binding

Cited by 14 publications

References 48 publications

Colicin E1 opens its hinge to plug TolC

Colicin E1 opens its hinge to plug TolC

Dead cells release a ‘necrosignal’ that activates antibiotic survival pathways in bacterial swarms

Rapid production and characterization of antimicrobial colicins using Escherichia coli-based cell-free protein synthesis

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