A promiscuous antitoxin of bacteriophage T4 ensures successful viral replication

Bacteria are constantly threatened by predation from bacteriophage parasites and, in response, have evolved an array of resistance mechanisms. These resistance mechanisms then place greater selection pressure on the infecting bacteriophages, which develop counter-strategies in a perpetual 'arms race' between virus and host. Toxin-antitoxin (TA) loci are widespread in bacteria and can confer multiple benefits, including resistance to bacteriophages. The study by Otsuka and Yonesaki, published in this issue of Molecular Microbiology, describes a new plasmid-encoded TA system, lsoAB, which confers resistance to a dmd(-) mutant of bacteriophage T4 through the activity of the LsoA toxin. Infections with wild-type T4, however, are unaffected as the Dmd protein acts as an alternative antitoxin to LsoA, thus preventing its anti-bacteriophage activity. Dmd has also been shown to negate the activity of a related toxin, RnlA. This is a striking result indicating that Dmd can act as a promiscuous antitoxin, binding and inhibiting multiple toxin partners, when antitoxin activity is generally considered to be limited to a single cognate toxin. This study is an exciting addition to both the bacteriophage resistance and TA fields, and suggests a greater role for TA system-based resistance and counter-resistance in the world's oldest predator-prey relationship.     

Diversity of bacterial type II toxin-antitoxin systems: a comprehensive search and functional analysis of novel families

Type II toxin-antitoxin (TA) systems are generally composed of two genes organized in an operon, encoding a labile antitoxin and a stable toxin. They were first discovered on plasmids where they contribute to plasmid stability by a phenomenon denoted as 'addiction', and subsequently in bacterial chromosomes. To discover novel families of antitoxins and toxins, we developed a bioinformatics approach based on the 'guilt by association' principle. Extensive experimental validation in Escherichia coli of predicted antitoxins and toxins increased significantly the number of validated systems and defined novel toxin and antitoxin families. Our data suggest that toxin families as well as antitoxin families originate from distinct ancestors that were assembled multiple times during evolution. Toxin and antitoxin families found on plasmids tend to be promiscuous and widespread, indicating that TA systems move through horizontal gene transfer. We propose that due to their addictive properties, TA systems are likely to be maintained in chromosomes even though they do not necessarily confer an advantage to their bacterial hosts. Therefore, addiction might play a major role in the evolutionary success of TA systems both on mobile genetic elements and in bacterial chromosomes.     

Axe-Txe,a broad-spectrum proteic toxin-antitoxin system specified by a multidrug-resistant,clinical isolate of Enterococcus faecium

Enterococcal species of bacteria are now acknowledged as leading causes of bacteraemia and other serious nosocomial infections. However, surprisingly little is known about the molecular mechanisms that promote the segregational stability of antibiotic resistance and other plasmids in these bacteria. Plasmid pRUM (24 873 bp) is a multidrug resistance plasmid identified in a clinical isolate of Enterococcus faecium. A novel proteic-based toxin-antitoxin cassette identified on pRUM was demonstrated to be a functional segregational stability module in both its native host and evolutionarily diverse bacterial species. Induced expression of the toxin protein (Txe) of this system resulted in growth inhibition in Escherichia coli. The toxic effect of Txe was alleviated by co-expression of the antitoxin protein, Axe. Homologues of the axe and txe genes are present in the genomes of a diversity of Eubacteria. These homologues (yefM-yoeB) present in the E. coli chromosome function as a toxin-antitoxin mechanism, although the Axe and YefM antitoxin components demonstrate specificity for their cognate toxin proteins in vivo. Axe-Txe is one of the first functional proteic toxin-antitoxin systems to be accurately described for Gram-positive bacteria.     

In-silico whole-genome sequence analysis of a halotolerant filamentous mangrove cyanobacterium revealed CRISPR-Cas systems with unique properties

Novel CRISPR systems capable of cleaving both DNA and RNA are progressively emerging as attractive tools for genome manipulation of prokaryotic and eukaryotic organisms. We report specific characteristics of CRISPR systems present in Oxynema aestuarii AP17, a halotolerant, filamentous cyanobacterium and the second known member of the Oxynema genus. In-silico analyses of its whole-genome sequence revealed the presence of multiple Type I and Type III CRISPR loci with one Type I-G system previously unreported in cyanobacteria. We further identified the leader sequences at the 5′ end of multiple CRISPR loci, many of which were distinct from previously reported cyanobacterial CRISPR leaders. Phylogenetic analyses of the O. aestuarii AP17 Cas1 proteins revealed two protein sequences that were unique and distantly related to other cyanobacterial Cas1 protein sequences. Our findings are significant because novel Class 1 CRISPR systems possess multi-subunit effectors and are highly flexible for repurposing by protein domain fusions made to the effector complex. Additionally, Type III CRISPRs are particularly useful for genome editing in certain extremophiles for which mesophilic Type II CRISPRs are ineffective.     

Comprehensive comparative-genomic analysis of Type 2 toxin-antitoxin systems and related mobile stress response systems in prokaryotes

Background  

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.     

毒素-抗毒素系统在应激环境下的生物学作用的研究进展

毒素-抗毒素系统（toxin-antitoxin system,TAS）广泛存在于细菌染色体及质粒上,是细菌中含量丰富的小型遗传元件。TAS通常由两个紧密相连的基因组成,分别编码毒素（toxin）和抗毒素（antitoxin）,稳定的毒素能够损伤宿主细胞,不稳定的抗毒素能够保护宿主细胞免于毒素的损伤作用。依据其性质和作用方式,目前已经发现三种型别的TAS。TAS具有多种生物学作用,如诱导程序性细胞死亡（programmed cell death,PCD）,应激条件下介导持留菌形成（persistence）,稳定基因大片段等。本文就近几年TAS在应激条件下的生物学作用的研究进展做一综述。     

Toxin–antitoxin systems: why so many,what for?

Toxin-antitoxin (TA) systems are small genetic modules that are abundant in bacterial genomes. Three types have been described so far, depending on the nature and mode of action of the antitoxin component. While type II systems are surprisingly highly represented because of their capacity to move by horizontal gene transfer, type I systems appear to have evolved by gene duplication and are more constrained. Type III is represented by a unique example located on a plasmid. Type II systems promote stability of mobile genetic elements and might act at the selfish level. Conflicting hypotheses about chromosomally encoded systems, from programmed cell death and starvation-induced stasis to protection against invading DNA and stabilization of large genomic fragments have been proposed.     

Bacterial toxin-antitoxin systems and perspectives for their application in medicine

The structure of various toxin-antitoxin (TA) families and the principles of their action are reviewed. TA loci are widely distributed in the genomes of eubacteria and archaea. Most TA systems are two-component and function in a similar way: a stable toxin alters vitally important cell functions and can be inactivated by a labile antitoxin.     

Genetic characterization of two putative toxin-antitoxin systems on cryptic plasmids from Bacillus thuringiensis strain YBT-1520

A novel putative toxin-antitoxin segregational stability system named KyAB system was identified in a novel native plasmid pBMB8240 from Bacillus thuringiensis strain YBT-1520, based on sequences homology with other toxin-antitoxin systems, the lethal activity of the KyB putative toxin in Escherichia coli and the stabilizing effect of the kyAB system in Bacillus thuringiensis. Secondarily, the native plasmid pBMB9741 from the same strain was resequenced and the corrected plasmid was named as pBMB7635. Based on sequence homology with the tasAB system and the lethal activity of toxin protein in Escherichia coli, a tasAB-like putative toxin-antitoxin system was identified on pBMB7635.     

A Moderate Toxin,GraT, Modulates Growth Rate and Stress Tolerance of Pseudomonas putida

Chromosomal toxin-antitoxin (TA) systems are widespread among free-living bacteria and are supposedly involved in stress tolerance. Here, we report the first TA system identified in the soil bacterium Pseudomonas putida. The system, encoded by the loci PP1586-PP1585, is conserved in pseudomonads and belongs to the HigBA family. The new TA pair was named GraTA for the growth rate-affecting ability of GraT and the antidote activity of GraA. The GraTA system shares many features common to previously described type II TA systems. The overexpression of GraT is toxic to the antitoxin deletion mutants, since the toxin''s neutralization is achieved by binding of the antitoxin. Also, the graTA operon structure and autoregulation by antitoxin resemble those of other TA loci. However, we were able to delete the antitoxin gene from the chromosome, which shows the unusually mild toxicity of innate GraT compared to previously described toxins. Furthermore, GraT is a temperature-dependent toxin, as its growth-regulating effect becomes more evident at lower temperatures. Besides affecting the growth rate, GraT also increases membrane permeability, resulting in higher sensitivity to some chemicals, e.g., NaCl and paraquat. Nevertheless, the active toxin helps the bacteria survive under different stressful conditions and increases their tolerance to several antibiotics, including streptomycin, kanamycin, and ciprofloxacin. Therefore, our data suggest that GraT may represent a new class of mild chromosomal regulatory toxins that have evolved to be less harmful to their host bacterium. Their moderate toxicity might allow finer growth and metabolism regulation than is possible with strong growth-arresting or bactericidal toxins.     

Evolution of the deaminase fold and multiple origins of eukaryotic editing and mutagenic nucleic acid deaminases from bacterial toxin systems

The deaminase-like fold includes, in addition to nucleic acid/nucleotide deaminases, several catalytic domains such as the JAB domain, and others involved in nucleotide and ADP-ribose metabolism. Using sensitive sequence and structural comparison methods, we develop a comprehensive natural classification of the deaminase-like fold and show that its ancestral version was likely to operate on nucleotides or nucleic acids. Consequently, we present evidence that a specific group of JAB domains are likely to possess a DNA repair function, distinct from the previously known deubiquitinating peptidase activity. We also identified numerous previously unknown clades of nucleic acid deaminases. Using inference based on contextual information, we suggest that most of these clades are toxin domains of two distinct classes of bacterial toxin systems, namely polymorphic toxins implicated in bacterial interstrain competition and those that target distantly related cells. Genome context information suggests that these toxins might be delivered via diverse secretory systems, such as Type V, Type VI, PVC and a novel PrsW-like intramembrane peptidase-dependent mechanism. We propose that certain deaminase toxins might be deployed by diverse extracellular and intracellular pathogens as also endosymbionts as effectors targeting nucleic acids of host cells. Our analysis suggests that these toxin deaminases have been acquired by eukaryotes on several independent occasions and recruited as organellar or nucleo-cytoplasmic RNA modifiers, operating on tRNAs, mRNAs and short non-coding RNAs, and also as mutators of hyper-variable genes, viruses and selfish elements. This scenario potentially explains the origin of mutagenic AID/APOBEC-like deaminases, including novel versions from Caenorhabditis, Nematostella and diverse algae and a large class of fast-evolving fungal deaminases. These observations greatly expand the distribution of possible unidentified mutagenic processes catalyzed by nucleic acid deaminases.     

The spirochetal chpK-chromosomal toxin-antitoxin locus induces growth inhibition of yeast and mycobacteria

Toxin-antitoxin systems encoded by bacterial plasmids and chromosomes typically consist of a toxin that inhibits growth of the host cell and a specific antitoxin. In this report, the chpK gene from the chromosomal toxin-antitoxin locus of the spirochete Leptospira interrogans was studied in both prokaryotic and eukaryotic systems. Cloning of the the spirochetal chpK gene into a mycobacterial expressing vector led to dramatic reductions of transformation efficiency in both Mycobacterium smegmatis and Mycobacterium bovis BCG. However, few mycobacterial transformants were obtained. This result could be due to plasmid structural modifications leading to disruption of chpK expression, suggesting that L. interrogans ChpK is highly toxic for mycobacteria. Presence of the L. interrogans chpK gene was also found to inhibit cell growth of the yeast Saccharomyces cerevisiae. These results show that ChpK possesses a broad activity against both prokaryotes and eukaryotes, suggesting that the cellular target of the toxin is conserved in these organisms.     

Structural and functional studies of the Mycobacterium tuberculosis VapBC30 toxin-antitoxin system: implications for the design of novel antimicrobial peptides

Toxin-antitoxin (TA) systems play important roles in bacterial physiology, such as multidrug tolerance, biofilm formation, and arrest of cellular growth under stress conditions. To develop novel antimicrobial agents against tuberculosis, we focused on VapBC systems, which encompass more than half of TA systems in Mycobacterium tuberculosis. Here, we report that theMycobacterium tuberculosis VapC30 toxin regulates cellular growth through both magnesium and manganese ion-dependent ribonuclease activity and is inhibited by the cognate VapB30 antitoxin. We also determined the 2.7-Å resolution crystal structure of the M. tuberculosis VapBC30 complex, which revealed a novel process of inactivation of the VapC30 toxin via swapped blocking by the VapB30 antitoxin. Our study on M. tuberculosis VapBC30 leads us to design two kinds of VapB30 and VapC30-based novel peptides which successfully disrupt the toxin-antitoxin complex and thus activate the ribonuclease activity of the VapC30 toxin. Our discovery herein possibly paves the way to treat tuberculosis for next generation.     

Balancing at survival's edge: the structure and adaptive benefits of prokaryotic toxin-antitoxin partners

Many prokaryotes express toxin-antitoxin (TA) pairs that are harmful to their hosts if not maintained in delicate balance. The maintenance of potentially lethal toxin-antitoxin pairs could be viewed as a high-risk strategy. However, accumulating evidence suggests that toxin-antitoxin pairs can confer selective evolutionary benefits such as adaptive stress responses, starvation recovery and herd immunity to predation. Many of the known TA pairs interact as proteins, but recent work has identified a new class of antitoxins that are RNA cleavage products. Structural studies have revealed common folds for diverse toxins, highlighting unexpected evolutionary relationships within different toxin classes. TA pairs appear to have diverged in function considerably, to meet the specialised requirements of their varied prokaryotic hosts.     

Analysis of the diversity of a sheep antibody repertoire as revealed from a bacteriophage display library

We have applied bacteriophage display technology to construct and analyze the diversity of an IgG library of >1 x 108 clones from an adult sheep immunized against the hapten atrazine. We have identified eight new VH gene families (VH2-VH9) and five new Vkappa gene families (VkappaV-VkappaIX). The heavy and kappa light chain variable region gene loci were found to be far more diverse than previously thought.     

RNA antitoxins

Recent genomic analyses revealed a surprisingly large number of toxin-antitoxin loci in free-living prokaryotes. The antitoxins are proteins or antisense RNAs that counteract the toxins. Two antisense RNA-regulated toxin-antitoxin gene families, hok/sok and ldr, are unrelated sequence-wise but have strikingly similar properties at the level of gene and RNA organization. Recently, two SOS-induced toxins were found to be regulated by RNA antitoxins. One such toxin, SymE, exhibits similarity with MazE antitoxin and, surprisingly, inhibits translation. Thus, it is possible that an ancestral antitoxin gene evolved into the present toxin gene (symE) whose translation is repressed by an RNA antitoxin (SymR).     

毒性分子-抗毒性分子系统的生物学作用研究进展

毒性分子-抗毒性分子系统(toxin-antitoxin systems,TA systems)被发现广泛存在于细菌染色体、质粒以及古细菌基因组中。TA系统是由2个基因组成的操纵子,这2个基因分别编码稳定的毒性分子和不稳定的抗毒性分子。毒性分子总是蛋白质,抗毒性分子可能是蛋白质或RNA。因此,根据抗毒性分子的性质和作用方式的不同可将TA系统家族分为5种类型。Ⅰ型和Ⅲ型的抗毒性分子是RNA,能抑制毒性分子的合成或者与其隔离;II、IV和V型的抗毒性分子是蛋白质,能隔离、平衡毒性分子作用或抑制其合成。TA系统具有多种生物学功能。目前研究表明,TA系统可能在细菌应激应答、程序化细胞死亡、多重耐药的形成、防止DNA入侵、稳定大基因组片段等方面有重要的作用。     

Small Toxic Proteins and the Antisense RNAs That Repress Them

Summary: There has been a great expansion in the number of small regulatory RNAs identified in bacteria. Some of these small RNAs repress the synthesis of potentially toxic proteins. Generally the toxin proteins are hydrophobic and less than 60 amino acids in length, and the corresponding antitoxin small RNA genes are antisense to the toxin genes or share long stretches of complementarity with the target mRNAs. Given their short length, only a limited number of these type I toxin-antitoxin loci have been identified, but it is predicted that many remain to be found. Already their characterization has given insights into regulation by small RNAs, has suggested functions for the small toxic proteins at the cell membrane, and has led to practical applications for some of the type I toxin-antitoxin loci.     

Novel and stress-regulated microRNAs and other small RNAs from Arabidopsis

MicroRNAs (miRNAs) and short interfering RNAs (siRNAs) are small noncoding RNAs that have recently emerged as important regulators of mRNA degradation, translational repression, and chromatin modification. In Arabidopsis thaliana, 43 miRNAs comprising 15 families have been reported thus far. In an attempt to identify novel and abiotic stress regulated miRNAs and siRNAs, we constructed a library of small RNAs from Arabidopsis seedlings exposed to dehydration, salinity, or cold stress or to the plant stress hormone abscisic acid. Sequencing of the library and subsequent analysis revealed 26 new miRNAs from 34 loci, forming 15 new families. Two of the new miRNAs from three loci are members of previously reported miR171 and miR319 families. Some of the miRNAs are preferentially expressed in specific tissues, and several are either upregulated or downregulated by abiotic stresses. Ten of the miRNAs are highly conserved in other plant species. Fifty-one potential targets with diverse function were predicted for the newly identified miRNAs based on sequence complementarity. In addition to miRNAs, we identified 102 other novel endogenous small RNAs in Arabidopsis. These findings suggest that a large number of miRNAs and other small regulatory RNAs are encoded by the Arabidopsis genome and that some of them may play important roles in plant responses to environmental stresses as well as in development and genome maintenance.