We have systematically made a set of precisely defined, single-gene deletions of all nonessential genes in Escherichia coli K-12. Open-reading frame coding regions were replaced with a kanamycin cassette flanked by FLP recognition target sites by using a one-step method for inactivation of chromosomal genes and primers designed to create in-frame deletions upon excision of the resistance cassette. Of 4288 genes targeted, mutants were obtained for 3985. To alleviate problems encountered in high-throughput studies, two independent mutants were saved for every deleted gene. These mutants-the 'Keio collection'-provide a new resource not only for systematic analyses of unknown gene functions and gene regulatory networks but also for genome-wide testing of mutational effects in a common strain background, E. coli K-12 BW25113. We were unable to disrupt 303 genes, including 37 of unknown function, which are candidates for essential genes. Distribution is being handled via GenoBase (http://ecoli.aist-nara.ac.jp/).

/pdf/construction-of-escherichia-coli-k-12-in-frame-single-gene-4c68fx6pb1.pdf

Construction of Escherichia coli K-12 in-frame, single-gene knockout mutants: the Keio collection.

Several well-recognized puzzles in microbiology have remained unsolved for decades. These include latent bacterial infections, unculturable microorganisms, persister cells and biofilm multidrug tolerance. Accumulating evidence suggests that these seemingly disparate phenomena result from the ability of bacteria to enter into a dormant (non-dividing) state. The molecular mechanisms that underlie the formation of dormant persister cells are now being unravelled and are the focus of this Review.

http://www.medicinabiomolecular.com.br/biblioteca/pdfs/Cancer/ca-3102.pdf

Persister cells, dormancy and infectious disease

The looming antibiotic-resistance crisis has penetrated the consciousness of clinicians, researchers, policymakers, politicians and the public at large. The evolution and widespread distribution of antibiotic-resistance elements in bacterial pathogens has made diseases that were once easily treatable deadly again. Unfortunately, accompanying the rise in global resistance is a failure in antibacterial drug discovery. Lessons from the history of antibiotic discovery and fresh understanding of antibiotic action and the cell biology of microorganisms have the potential to deliver twenty-first century medicines that are able to control infection in the resistance era.

Antibacterial drug discovery in the resistance era

Clonal populations of microbial cells often show a high degree of phenotypic variability under homogeneous conditions. Stochastic fluctuations in the cellular components that determine cellular states can cause two distinct subpopulations, a property called bistability. Phenotypic heterogeneity can be readily obtained by interlinking multiple gene regulatory pathways, effectively resulting in a genetic logic-AND gate. Although switching between states can occur within the cells' lifetime, cells can also pass their cellular state over to the next generation by a mechanism known as epigenetic inheritance and thus perpetuate the phenotypic state. Importantly, heterogeneous populations can demonstrate increased fitness compared with homogeneous populations. This suggests that microbial cells employ bet-hedging strategies to maximize survival. Here, we discuss the possible roles of interlinked bistable networks, epigenetic inheritance, and bet-hedging in bacteria.

/pdf/bistability-epigenetics-and-bet-hedging-in-bacteria-nwb59xne6v.pdf

Bistability, epigenetics, and bet-hedging in bacteria.

Although toxin-antitoxin gene cassettes were first found in plasmids, recent database mining has shown that these loci are abundant in free-living prokaryotes, including many pathogenic bacteria. For example, Mycobacterium tuberculosis has 38 chromosomal toxin-antitoxin loci, including 3 relBE and 9 mazEF loci. RelE and MazF are toxins that cleave mRNA in response to nutritional stress. RelE cleaves mRNAs that are positioned at the ribosomal A-site, between the second and third nucleotides of the A-site codon. It has been proposed that toxin-antitoxin loci function in bacterial programmed cell death, but evidence now indicates that these loci provide a control mechanism that helps free-living prokaryotes cope with nutritional stress.

Prokaryotic toxin-antitoxin stress response loci.

The stringent response is defined as the physiological changes elicited by amino acid starvation. Many of these changes depend on the regulatory nucleotide ppGpp (guanosine tetraphosphate) synthesized by RelA (ppGpp synthetase I), the relA-encoded protein. The second rel locus of Escherichia coli is called relBE and encodes RelE cytotoxin and RelB antitoxin. RelB counteracts the toxic effect of RelE. In addition, RelB is an autorepressor of relBE transcription. Here we reveal a ppGpp-independent mechanism that reduces the level of translation during amino acid starvation. Artificial overexpression of RelE severely inhibited translation. During amino acid starvation, the presence of relBE caused a significant reduction in the poststarvation level of translation. Concomitantly, relBE transcription was rapidly and strongly induced. Induction of transcription occurred independently of relA and spoT (encoding ppGpp synthetase II), but instead depended on Lon protease. Consistently, Lon was required for degradation of RelB. Replacement of the relBE promoter with a LacI-regulated promoter indicated that strong and ongoing transcription of relBE is required to maintain a proper RelB:RelE ratio during starvation. Thus relBE may be regarded as a previously uncharacterized type of stress-response element that reduces the global level of translation during nutritional stress.

https://www.pnas.org/content/pnas/98/25/14328.full.pdf

RelE, a global inhibitor of translation, is activated during nutritional stress

Toxin–antitoxin Loci as Stress-response-elements: ChpAK/MazF and ChpBK Cleave Translated RNAs and are Counteracted by tmRNA

RelE and ChpAK (MazF) toxins of Escherichia coli have previously been described as proteins that mediate efficient cell killing. We show here that induction of relE or chpAK transcription does not confer cell killing but, instead, induces a static condition in which the cells are still viable but unable to proliferate. Later induction of transcription of the antitoxin genes relB or chpAI fully reversed the static condition induced by RelE and ChpAK respectively. We also provide a mechanistic explanation for these findings. Thus, induction of relE transcription severely inhibited translation, whereas induction of chpAK transcription inhibited both translation and replication. Hence, most likely, lack of colony formation is due to inhibition of translation in the case of relE and inhibition of translation and/or replication in the case of chpAK. Consistent with this proposal, later induction of transcription of the cognate antitoxin genes simultaneously reversed cell stasis and the inhibitory effects of RelE and ChpAK on macromolecular syntheses. These results preclude that RelE and ChpAK mediate cell killing during the conditions used here. In vivo and in vitro analyses of a mutant RelE protein supported that inhibition of colony formation was due to inhibition of translation.

Rapid induction and reversal of a bacteriostatic condition by controlled expression of toxins and antitoxins

RelE of Escherichia coli is a global inhibitor of translation that is activated by nutritional stress. Activation of RelE depends on Lon-mediated degradation of RelB, the antagonist that neutralizes RelE. In vitro, RelE cleaves synthetic mRNAs positioned at the ribosomal A-site. We show here that in vivo overexpression of RelE confers cleavage of mRNA and tmRNA in their coding regions. RelE-mediated cleavage depended on translation of the RNAs and occurred at both sense and stop codons. RelE cleavage of mRNA and tmRNA was also induced by amino acid starvation. An ssrA deletion strain was hypersensitive to RelE, whereas overproduction of tmRNA counteracted RelE toxicity. After neutralization of RelE by RelB, rapid recovery of translation required tmRNA, indicating that tmRNA alleviated RelE toxicity by rescuing ribosomes stalled on damaged mRNAs. RelE proteins from Gram-positive Bacteria and Archaea cleaved tmRNA with a pattern similar to that of E. coli RelE, suggesting that the function and target of RelE may be conserved across the prokaryotic domains.

https://onlinelibrary.wiley.com/doi/pdf/10.1046/j.1365-2958.2003.03512.x

Susanne K. Christensen

Papers

Prokaryotic toxin-antitoxin stress response loci.

RelE, a global inhibitor of translation, is activated during nutritional stress

Toxin–antitoxin Loci as Stress-response-elements: ChpAK/MazF and ChpBK Cleave Translated RNAs and are Counteracted by tmRNA

Rapid induction and reversal of a bacteriostatic condition by controlled expression of toxins and antitoxins

RelE toxins from Bacteria and Archaea cleave mRNAs on translating ribosomes, which are rescued by tmRNA