Overproduction of the Lon protease triggers inhibition of translation in Escherichia coli: involvement of the yefM‐yoeB toxin‐antitoxin system
SummaryIn Escherichia coli , the Lon ATP-dependent protease is responsible for degradation of several regulatory proteins and for the elimination of abnormal proteins. Previous studies have shown that the overproduction of Lon is lethal. Here, we showed that Lon overproduction specifically inhibits translation through at least two different pathways. We have identified one of the pathways as being the chromosomal yefM-yoeB toxin-antitoxin system. The existence of a second pathway is demonstrated by the observation that the deletion of the yefM-yoeB system did not completely suppress lethality and translation inhibition. We also showed that the YoeB toxin induces cleavage of translated mRNAs and that Lon overproduction specifically activates YoeB-dependent mRNAs cleavage. Indeed, none of the other identified chromosomal toxin-antitoxin systems ( relBE , mazEF , chpB and dinJ-yafQ ) was involved in Lon-dependent lethality, translation inhibition and mRNA cleavage even though the RelB and MazE antitoxins are known to be Lon substrates. Based on our results and other studies, translation inhibition appears to be the key element that triggers chromosomal toxin-antitoxin systems. We propose that under Lon overproduction conditions, translation inhibition is mediated by Lon degradation of a component of the YoeB-independent pathway, in turn activating the YoeB toxin by preventing synthesis of its unstable YefM antidote.
What Is the Benefit to Escherichia coli of Having Multiple Toxin-Antitoxin Systems in Its Genome?
The Escherichia coli K-12 chromosome encodes at least five proteic toxin-antitoxin (TA) systems. The mazEF and relBE systems have been extensively characterized and were proposed to be general stress response modules. On one hand, mazEF was proposed to act as a programmed cell death system that is triggered by a variety of stresses. On the other hand, relBE and mazEF were proposed to serve as growth modulators that induce a dormancy state during amino acid starvation. These conflicting hypotheses led us to test a possible synergetic effect of the five characterized E. coli TA systems on stress response. We compared the behavior of a wild-type strain and its derivative devoid of the five TA systems under various stress conditions. We were unable to detect TA-dependent programmed cell death under any of these conditions, even under conditions previously reported to induce it. Thus, our results rule out the programmed-cell-death hypothesis. Moreover, the presence of the five TA systems advantaged neither recovery from the different stresses nor cell growth under nutrient-limited conditions in competition experiments. This casts a doubt on whether TA systems significantly influence bacterial fitness and competitiveness during non-steady-state growth conditions.Most bacterial genomes harbor multiple toxin-antitoxin (TA) systems (for reviews on TA systems, see references 6, 13, 18, and 24). Based on sequence homology, seven families of proteic TA systems have been defined (3, 40). Members of a given family can be found at multiple locations within a genome (e.g., in the genomic core, genomic islands, and mobile genetic elements) and in multiple bacterial species. This ubiquity strongly suggests that TA systems move from one location to another through horizontal gene transfer. The first characterized TA operons were discovered 25 years ago on low-copynumber plasmids, and it became rapidly clear that their role is to maintain the plasmid that carries them in growing bacterial populations. The molecular mechanism underlying plasmid maintenance is called postsegregational killing and relies on the differential stabilities of the two components (antitoxin and toxin). Upon plasmid loss, de novo synthesis of the plasmidencoded TA components ceases and the unstable antitoxin protein is degraded by an ATP-dependent protease, which results in toxin release. The toxin is then able to interact with its target and interfere with essential cellular processes (e.g., DNA replication or protein synthesis). Ultimately, this leads to the selective killing of the plasmid-free progeny.In contrast to that of plasmidic systems, the biological function of chromosomal TA systems is still an area of debate. There are at least five proteic TA systems that have been identified so far in the Escherichia coli K-12 (MG1655) chromosome: mazEF, relBE, yefM-yoeB, chpB, and dinJ-yafQ (1,4,20,21,35,38,46). The most prevalent hypothesis is that they are involved in general stress response, as suggested by extensive studies on mazEF and relBE (e.g., refe...
SummaryType II toxin-antitoxin (TA) systems are considered as protein pairs in which a specific toxin is associated with a specific antitoxin. We have identified a novel antitoxin family (paaA) that is associated with parE toxins. The paaA-parE gene pairs form an operon with a third component (paaR) encoding a transcriptional regulator. Two paralogous paaR-paaA-parE systems are found in E. coli O157:H7. Deletions of the paaAparE pairs in O157:H7 allowed us to show that these systems are expressed in their natural host and that PaaA antitoxins specifically counteract toxicity of their associated ParE toxin. For the paaR2-paaA2-parE2 system, PaaR2 and Paa2-ParE2 complex are able to regulate the operon expression and both are necessary to ensure complete repression. The paaR2-paaA2-parE2 system mediates ClpXP-dependent post-segregational killing. The PaaR2 regulator appears to be essential for this function, most likely by maintaining an appropriate antitoxin : toxin ratio in steady-state conditions. Ectopic overexpression of ParE2 is bactericidal and is not resuscitated by PaaA2 expression. ParE2 colocalizes with the nucleoid, while it is diffusely distributed in the cytoplasm when PaaA2 is coexpressed. This indicates that ParE2 interacts with DNA-gyrase cycling on DNA and that coexpression of PaaA2 antitoxin sequesters ParE2 away from its target by protein-protein complex formation.
Toxin-antitoxin (TA) systems are widely represented on mobile genetic elements as well as in bacterial chromosomes. TA systems encode a toxin and an antitoxin neutralizing it. We have characterized a homolog of the ccd TA system of the F plasmid (ccd F ) located in the chromosomal backbone of the pathogenic O157:H7 Escherichia coli strain (ccd O157 ). The ccd F and the ccd O157 systems coexist in O157:H7 isolates, as these pathogenic strains contain an F-related virulence plasmid carrying the ccd F system. We have shown that the chromosomal ccd O157 system encodes functional toxin and antitoxin proteins that share properties with their plasmidic homologs: the CcdB O157 toxin targets the DNA gyrase, and the CcdA O157 antitoxin is degraded by the Lon protease. The ccd O157 chromosomal system is expressed in its natural context, although promoter activity analyses revealed that its expression is weaker than that of ccd F . ccd O157 is unable to mediate postsegregational killing when cloned in an unstable plasmid, supporting the idea that chromosomal TA systems play a role(s) other than stabilization in bacterial physiology. Our cross-interaction experiments revealed that the chromosomal toxin is neutralized by the plasmidic antitoxin while the plasmidic toxin is not neutralized by the chromosomal antitoxin, whether expressed ectopically or from its natural context. Moreover, the ccd F system is able to mediate postsegregational killing in an E. coli strain harboring the ccd O157 system in its chromosome. This shows that the plasmidic ccd F system is functional in the presence of its chromosomal counterpart.Toxin-antitoxin (TA) proteic systems were originally discovered on low-copy-number plasmids (for reviews on TA systems, see references 11, 22, 24, and 29). They are composed of two genes organized in an operon encoding a toxin and an antitoxin that antagonizes it. The expression of the TA genes is autoregulated at the transcriptional level; the antitoxin acts as a repressor and the toxin often as a corepressor. The antitoxin is an unstable protein degraded by an ATP-dependent protease, while the toxin is a stable protein that inhibits an essential cellular process (e.g., replication and translation). TA systems contribute to plasmid stability by a mechanism called postsegregational killing (PSK). PSK relies on the differential stabilities of the antitoxin and toxin proteins and leads to the killing of daughter bacteria that did not receive a plasmid copy at cell division (31, 50, 53).Recent computational analyses have shown that TA systems are widely represented in eubacterial and archaebacterial chromosomes, suggesting a role for horizontal gene transfer in the spread of these genes (5, 6, 38). The localization of chromosomal TA systems is quite varied. Some are localized within exogenous DNA islands like phages (relBE K-12 in the cryptic lambdoid Qin prophage of Escherichia coli MG1655) (40), transposons (relBE homolog in Tn5401 of Bacillus thuringiensis (23), and superintegrons (relBE, parDE, phd-doc, and hig...
c Toxin-antitoxin (TA) systems have been reported in the genomes of most bacterial species, and their role when located on the chromosome is still debated. TA systems are particularly abundant in the massive cassette arrays associated with chromosomal superintegrons (SI). Here, we describe the characterization of two superintegron cassettes encoding putative TA systems. The first is the phd-doc SI system identified in Vibrio cholerae N16961. We determined its distribution in 36 V. cholerae strains and among five V. metschnikovii strains. We show that this cassette, which is in position 72 of the V. cholerae N16961 cassette array, is functional, carries its own promoter, and is expressed from this location. Interestingly, the phd-doc SI system is unable to control its own expression, most likely due to the absence of any DNA-binding domain on the antitoxin. In addition, this SI system is able to cross talk with the canonical P1 phage system. The second cassette that we characterized is the ccd Vfi cassette found in the V. fischeri superintegron. We demonstrate that CcdB Vfi targets DNA-gyrase, as the canonical CcB F toxin, and that ccd Vfi regulates its expression in a fashion similar to the ccd F operon of the conjugative plasmid F. We also establish that this cassette is functional and expressed in its chromosomal context in V. fischeri CIP 103206T. We tested its functional interactions with the ccdAB F system and found that CcdA Vfi is specific for its associated CcdB Vfi and cannot prevent CcdB F toxicity. Based on these results, we discuss the possible biological functions of these TA systems in superintegrons.
The origin and the evolution of toxin-antitoxin (TA) systems remain to be uncovered. TA systems are abundant in bacterial chromosomes and are thought to be part of the flexible genome that originates from horizontal gene transfer. To gain insight into TA system evolution, we analyzed the distribution of the chromosomally encoded ccd O157 system in 395 natural isolates of Escherichia coli. It was discovered in the E. coli O157:H7 strain in which it constitutes a genomic islet between two core genes ( folA and apaH). Our study revealed that the folA-apaH intergenic region is plastic and subject to insertion of foreign DNA. It could be composed (i) of a repetitive extragenic palindromic (REP) sequence, (ii) of the ccd O157 system or subtle variants of it, (iii) of a large DNA piece that contained a ccdA O157 antitoxin remnant in association with ORFs of unknown function, or (iv) of a variant of it containing an insertion sequence in the ccdA O157 remnant. Sequence analysis and functional tests of the ccd O157 variants revealed that 69% of the variants were composed of an active toxin and antitoxin, 29% were composed of an active antitoxin and an inactive toxin, and in 2% of the cases both ORFs were inactive. Molecular evolution analysis showed that ccdB O157 is under neutral evolution, suggesting that this system is devoid of any biological role in the E. coli species.
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