Project description:Toxin/antitoxin (TA) systems, viewed as essential regulators of growth arrest and programmed cell death, are widespread among prokaryotes, but remain sparsely annotated. We present RASTA-Bacteria, an automated method allowing quick and reliable identification of TA loci in sequenced prokaryotic genomes, whether they are annotated open reading frames or not. The tool successfully confirmed all reported TA systems, and spotted new putative loci upon screening of sequenced genomes. RASTA-Bacteria is publicly available at http://genoweb.univ-rennes1.fr/duals/RASTA-Bacteria.

Project description:Rickettsia spp. can cause mild to severe human disease. These intracellular bacteria are associated with arthropods, nematodes and trematodes, and usually, are efficiently transmitted transovarially to the progeny of the invertebrate host. We recently demonstrated foreign gene acquisition by lateral gene transfer in Rickettsia genomes. The unexpected presence of laterally transferred toxin-antitoxin (TA) genetic elements (including vapBC) in several Rickettsia genomes has not been connected with the pathogenic process or the host-bacteria relationship. We suspect that vapBC are selfish genetic elements that addict eukaryotic hosts to Rickettsia. We identified a statistical link between the transovarial transmission of Rickettsia in invertebrate hosts and the presence of TA operons, specifically vapBC, in the Rickettsia genome. These TA are neighboring to type IV secretion genes. Tunel assays and whole-genome expression of infected cells showed that antibiotic eradication of TA-containing Rickettsia from the host in cell culture initiates a proapoptotic program. Rickettsia VapC toxins inhibit the growth of transformed Escherichia coli and Saccharomyces cerevisiae. Rickettsia toxin presents in vitro RNase activity. Annexin-V staining and time-lapse video showed that intracytoplasmic injections of VapC toxins in cells cause apoptosis. These data demonstrate that host cells may develop a dependence on Rickettsia spp. expressing the vapBC operon. This would constitute a new evolutionary M-bM-^@M-^\mafia strategyM-bM-^@M-^] of intracellular bacteria based on host addiction. Fresh cells from the human microvascular endothelial cell line (HMEC-1) [26] were infected with R. felis California-2 strain in the presence and absence of antibiotics, at a rate of 5 bacteria per eukaryotic cell. Then, we added or not antibiotics (chloramphenicol 50 M-BM-5g/ml or doxycycline to 40 M-BM-5g/ml) in both experimental (R.felis-infected) and control, mock-infected cells for 6 hours. The cells were harvested and RNA was extracted using the RNeasy Mini Kit (Qiagen). DNA contamination was removed using the Turbo DNA-free Kit (Ambion). RNA were labeled using the Quick Amp Labeling Kit One-color (Agilent) and hybridized onto a Whole Human Genome Microarray, 4x44K (Agilent) as recommended by the manufacturer. Arrays were scanned with DNA Microarray Scanner (Agilent), and data were extracted using Feature Extractor (Agilent).

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Rickettsia spp. can cause mild to severe human disease. These intracellular bacteria are associated with arthropods, nematodes and trematodes, and usually, are efficiently transmitted transovarially to the progeny of the invertebrate host. We recently demonstrated foreign gene acquisition by lateral gene transfer in Rickettsia genomes. The unexpected presence of laterally transferred toxin-antitoxin (TA) genetic elements (including vapBC) in several Rickettsia genomes has not been connected with the pathogenic process or the host-bacteria relationship. We suspect that vapBC are selfish genetic elements that addict eukaryotic hosts to Rickettsia. We identified a statistical link between the transovarial transmission of Rickettsia in invertebrate hosts and the presence of TA operons, specifically vapBC, in the Rickettsia genome. These TA are neighboring to type IV secretion genes. Tunel assays and whole-genome expression of infected cells showed that antibiotic eradication of TA-containing Rickettsia from the host in cell culture initiates a proapoptotic program. Rickettsia VapC toxins inhibit the growth of transformed Escherichia coli and Saccharomyces cerevisiae. Rickettsia toxin presents in vitro RNase activity. Annexin-V staining and time-lapse video showed that intracytoplasmic injections of VapC toxins in cells cause apoptosis. These data demonstrate that host cells may develop a dependence on Rickettsia spp. expressing the vapBC operon. This would constitute a new evolutionary “mafia strategy” of intracellular bacteria based on host addiction.

Project description:TADB2.0 (http://bioinfo-mml.sjtu.edu.cn/TADB2/) is an updated database that provides comprehensive information about bacterial type II toxin-antitoxin (TA) loci. Compared with the previous version, the database refined and the new data schema is employed. With the aid of text mining and manual curation, it recorded 6193 type II TA loci in 870 replicons of bacteria and archaea, including 105 experimentally validated TA loci. In addition, the newly developed tool TAfinder combines the homolog searches and the operon structure detection, allowing the prediction for type II TA pairs in bacterial genome sequences. It also helps to investigate the genomic context of predicted TA loci for putative virulence factors, antimicrobial resistance determinants and mobile genetic elements via alignments to the specific public databases. Additionally, the module TAfinder-Compare allows comparing the presence of the given TA loci across the close relative genomes. With the recent updates, TADB2.0 might provide better support for understanding the important roles of type II TA systems in the prokaryotic life activities.

Project description:The prokaryotic toxin-antitoxin systems (TAS, also referred to as TA loci) are widespread, mobile two-gene modules that can be viewed as selfish genetic elements because they evolved mechanisms to become addictive for replicons and cells in which they reside, but also possess "normal" cellular functions in various forms of stress response and management of prokaryotic population. Several distinct TAS of type 1, where the toxin is a protein and the antitoxin is an antisense RNA, and numerous, unrelated TAS of type 2, in which both the toxin and the antitoxin are proteins, have been experimentally characterized, and it is suspected that many more remain to be identified.We report a comprehensive comparative-genomic analysis of Type 2 toxin-antitoxin systems in prokaryotes. Using sensitive methods for distant sequence similarity search, genome context analysis and a new approach for the identification of mobile two-component systems, we identified numerous, previously unnoticed protein families that are homologous to toxins and antitoxins of known type 2 TAS. In addition, we predict 12 new families of toxins and 13 families of antitoxins, and also, predict a TAS or TAS-like activity for several gene modules that were not previously suspected to function in that capacity. In particular, we present indications that the two-gene module that encodes a minimal nucleotidyl transferase and the accompanying HEPN protein, and is extremely abundant in many archaea and bacteria, especially, thermophiles might comprise a novel TAS. We present a survey of previously known and newly predicted TAS in 750 complete genomes of archaea and bacteria, quantitatively demonstrate the exceptional mobility of the TAS, and explore the network of toxin-antitoxin pairings that combines plasticity with selectivity.The defining properties of the TAS, namely, the typically small size of the toxin and antitoxin genes, fast evolution, and extensive horizontal mobility, make the task of comprehensive identification of these systems particularly challenging. However, these same properties can be exploited to develop context-based computational approaches which, combined with exhaustive analysis of subtle sequence similarities were employed in this work to substantially expand the current collection of TAS by predicting both previously unnoticed, derived versions of known toxins and antitoxins, and putative novel TAS-like systems. In a broader context, the TAS belong to the resistome domain of the prokaryotic mobilome which includes partially selfish, addictive gene cassettes involved in various aspects of stress response and organized under the same general principles as the TAS. The "selfish altruism", or "responsible selfishness", of TAS-like systems appears to be a defining feature of the resistome and an important characteristic of the entire prokaryotic pan-genome given that in the prokaryotic world the mobilome and the "stable" chromosomes form a dynamic continuum.This paper was reviewed by Kenn Gerdes (nominated by Arcady Mushegian), Daniel Haft, Arcady Mushegian, and Andrei Osterman. For full reviews, go to the Reviewers' Reports section.

Project description:E.coli toxin-antitoxin systems

Project description:Toxin and antitoxin (TA) gene pairs are addiction systems that are present in many microbial genomes. Sinorhizobium meliloti is an N2-fixing bacterial symbiont of alfalfa and other leguminous plants, and its genome consists of three large replicons, a circular chromosome (3.7 Mb) and the megaplasmids pSymA (1.4 Mb) and pSymB (1.7 Mb). S. meliloti carries 211 predicted type II TA genes, each encoding a toxin or an antitoxin. We constructed defined deletion strains that collectively removed the entire pSymA and pSymB megaplasmids except for their oriV regions. Of approximately 100 TA genes on pSymA and pSymB, we identified four whose loss was associated with cell death or stasis unless copies of the genes were supplied in trans. Orthologs of three of these loci have been characterized in other organisms (relB/E [sma0471/sma0473], Fic [DOC] [sma2105], and VapC [PIN] [orf2230/sma2231]), and this report contains the first experimental proof that RES/Xre (smb21127/smb21128) loci can function as a TA system. Transcriptome sequencing (RNA-seq) analysis did not reveal transcriptional differences between the TA systems to account for why deletion of the four "active" systems resulted in cell toxicity. These data suggest that severe cell growth phenotypes result from the loss of a few TA systems and that loss of most TA systems may result in more subtle phenotypes. These four TA systems do not appear to play a direct role in the S. meliloti-alfalfa symbiosis, as strains lacking these TA systems had a symbiotic N2 fixation phenotype that was indistinguishable from the wild type.

Project description:The versatile roles of toxin-antitoxin (TA) systems in bacterial physiology and pathogenesis have been investigated for more than three decades. Diverse TA loci in Bacteria and Archaea have been identified in genome-wide studies. The advent of massive parallel sequencing has substantially expanded the number of known bacterial genomic sequences over the last 5 years. In staphylococci, this has translated into an impressive increase from a few tens to a several thousands of available genomes, which has allowed us for the re-evalution of prior conclusions. In this study, we analysed the distribution of mazEF/pemIK family TA system operons in available staphylococcal genomes and their prevalence in mobile genetic elements. 10 novel m azEF/pemIK homologues were identified, each with a corresponding toxin that plays a potentially different and undetermined physiological role. A detailed characterisation of these TA systems would be exceptionally useful. Of particular interest are those associated with an SCCmec mobile genetic element (responsible for multidrug resistance transmission) or representing the joint horizontal transfer of TA systems and determinants of vancomycin resistance from enterococci. The involvement of TA systems in maintaining mobile genetic elements and the associations between novel mazEF/pemIK loci and those which carry drug resistance genes highlight their potential medical importance.

Project description:Type I toxin-antitoxin (TA) systems are widespread genetic modules in bacterial genomes. They express toxic peptides whose overexpression leads to growth arrest or cell death, whereas antitoxins regulate the expression of toxins, acting as labile antisense RNAs. The Staphylococcus aureus (S. aureus) genome contains and expresses several functional type I TA systems, but their biological functions remain unclear. Here we addressed and challenged experimentally, by proteomics, if a type I TA system, the SprF1/SprG1 pair, influences the overall gene expression in S. aureus. Deleted and complemented S. aureus strains were analyzed for their proteomes, both intracellular and extracellular, during growth. Comparison of intracellular proteomes between the strains points on SprF1 antitoxin as an agent downregulating protein expression. In the strain naturally expressing the SprG1 toxin, cytoplasmic proteins are excreted into the medium, but this is not due to unspecific cell leakages. Such toxin-driven release of the cytoplasmic proteins may modulate the host inflammatory response that, in turn, may amplify the S. aureus infection spread.