Toxin-antitoxin loci are highly abundant in free-living but lost from host-associated prokaryotes

Transcriptional inactivation of a regulatory site for replication of Vibrio cholerae chromosome II

The bacterium Vibrio cholerae has two chromosomes. The origin of replication of chromosome I is similar to that of Escherichia coli. The origin-containing region of chromosome II (oriCII) resembles replicons of plasmids such as P1, except for the presence of an additional gene, rctA [Egan, E. S. & Waldor, M. K. (2003) Cell 114, 521-530]. The oriCII region that includes the initiator gene, rctB, can function as a plasmid in E. coli. Here we show that RctB suffices for the oriCII-based plasmid replication, and rctA in cis or trans reduces the plasmid copy number, thereby serving as a negative regulator. The inhibitory activity could be overcome by increasing the concentration of RctB, suggesting that rctA titrates the initiator. Purified RctB bound to a DNA fragment carrying rctA, confirming that the two can interact. Although rctA apparently works as a titrating site, it is nonetheless transcribed. We find that the transcription attenuates the inhibitory activity of the gene, presumably by interfering with RctB binding. RctB, in turn, repressed the rctA promoter and, thereby, could control its own titration by modulating the transcription of rctA. This control circuit appears to be a putative novel mechanism for homeostasis of initiator availability.

Ectopic overexpression of wild-type and mutant hipA genes in Escherichia coli: effects on macromolecular synthesis and persister formation

Persistence is an epigenetic trait that allows a small fraction of bacteria, approximately one in a million, to survive prolonged exposure to antibiotics. In Escherichia coli an increased frequency of persisters, called "high persistence," is conferred by mutations in the hipA gene, which encodes the toxin entity of the toxin-antitoxin module hipBA. The high-persistence allele hipA7 was originally identified because of its ability to confer high persistence, but little is known about the physiological role of the wild-type hipA gene. We report here that the expression of wild-type hipA in excess of hipB inhibits protein, RNA, and DNA synthesis in vivo. However, unlike the RelE and MazF toxins, HipA had no effect on protein synthesis in an in vitro translation system. Moreover, the expression of wild-type hipA conferred a transient dormant state (persistence) to a sizable fraction of cells, whereas the rest of the cells remained in a prolonged dormant state that, under appropriate conditions, could be fully reversed by expression of the cognate antitoxin gene hipB. In contrast, expression of the mutant hipA7 gene in excess of hipB did not markedly inhibit protein synthesis as did wild-type hipA and yet still conferred persistence to ca. 10% of cells. We propose that wild-type HipA, upon release from HipB, is able to inhibit macromolecular synthesis and induces a bacteriostatic state that can be reversed by expression of the hipB gene. However, the ability of the wild-type hipA gene to generate a high frequency of persisters, equal to that conferred by the hipA7 allele, may be distinct from the ability to block macromolecular synthesis.

Dynamic metabolic adjustments and genome plasticity are implicated in the heat shock response of the extremely thermoacidophilic archaeon Sulfolobus solfataricus

Approximately one-third of the open reading frames encoded in the Sulfolobus solfataricus genome were differentially expressed within 5 min following an 80 to 90 degrees C temperature shift at pH 4.0. This included many toxin-antitoxin loci and insertion elements, implicating a connection between genome plasticity and metabolic regulation in the early stages of stress response.

Rickettsia felis, from culture to genome sequencing

Rickettsia felis has been recently cultured in XTC2 cells. This allows production of enough bacteria to create a genomic bank and to sequence it. The chromosome of R. felis is longer than that of previously sequenced rickettsiae and it possess 2 plasmids. Microscopically, this bacterium exhibits two forms of pili: one resembles a conjugative pilus and another forms hair-like projections that may play a role in pathogenicity. R. felis also exhibits several copies of ankyrin-repeat genes and tetratricopeptide encoding gene that are specifically linked to pathogenic host-associated bacteria. It also contains toxin-antitoxin system encoding genes that are extremely rare in intracellular bacteria and may be linked to plasmid maintenance.

Tuberculosis chemotherapy: the influence of bacillary stress and damage response pathways on drug efficacy

The global tuberculosis (TB) control effort is focused on interrupting transmission of the causative agent, Mycobacterium tuberculosis, through chemotherapeutic intervention in active infectious disease. The insufficiency of this approach is manifest in the inexorable annual increase in TB infection and mortality rates and the emergence of multidrug-resistant isolates. Critically, the limited efficacy of the current frontline anti-TB drug combination suggests that heterogeneity of host and bacillary physiologies might impair drug activity. This review explores the possibility that strategies enabling adaptation of M. tuberculosis to hostile in vivo conditions might contribute to the subversion of anti-TB chemotherapy. In particular, evidence that infecting bacilli are exposed to environmental and host immune-mediated DNA-damaging insults suggests a role for error-prone DNA repair synthesis in the generation of chromosomally encoded antibiotic resistance mutations. The failure of frontline anti-TB drugs to sterilize a population of susceptible bacilli is independent of genetic resistance, however, and instead implies the operation of alternative tolerance mechanisms. Specifically, it is proposed that the emergence of persister subpopulations might depend on the switch to an altered metabolic state mediated by the stringent response alarmone, (p)ppGpp, possibly involving some or all of the many toxin-antitoxin modules identified in the M. tuberculosis genome.

Shutdown decay of mRNA

Although plasmid-borne and chromosomal toxin-antitoxin (TA) operons have been known for some time, the recent identification of mRNA as the target of at least two different classes of toxins has led to a dramatic renewal of interest in these systems as mediators of stress responses. Members of the MazF/PemK family, the so-called mRNA interferases, are ribonucleases that inhibit translation by destroying cellular mRNAs under stress conditions, while the founder member of the RelE family promotes cleavage of mRNAs through the ribosome. Detailed structures of these enzymes, often in complex with their inhibitors, have provided vital clues to their mechanisms of action. The primary role and regulation of these systems has been the subject of some controversy. One model suggests they play a beneficial role by wiping the slate clean and preventing wasteful energy consumption by the translational apparatus during adaptation to stress conditions, while another favours the idea that their main function is programmed cell death. The two models might not be mutually exclusive if a side-effect of prolonged exposure to toxic RNase activity without de novo synthesis of the inhibitor were a state of dormancy for which we do not yet understand the key to recovery. In this review, I discuss the recent developments in the rapidly expanding field of what I refer to as bacterial shutdown decay.

Persisters: a distinct physiological state of E. coli

Background

Bacterial populations contain persisters, phenotypic variants that constitute approximately 1% of cells in stationary phase and biofilm cultures. Multidrug tolerance of persisters is largely responsible for the inability of antibiotics to completely eradicate infections. Recent progress in understanding persisters is encouraging, but the main obstacle in understanding their nature was our inability to isolate these elusive cells from a wild-type population since their discovery in 1944.

Results

We hypothesized that persisters are dormant cells with a low level of translation, and used this to physically sort dim E. coli cells which do not contain sufficient amounts of unstable GFP expressed from a promoter whose activity depends on the growth rate. The dim cells were tolerant to antibiotics and exhibited a gene expression profile distinctly different from those observed for cells in exponential or stationary phases. Genes coding for toxin-antitoxin module proteins were expressed in persisters and are likely contributors to this condition.

Conclusion

We report a method for persister isolation and conclude that these cells represent a distinct state of bacterial physiology.

MazG -- a regulator of programmed cell death in Escherichia coli

We have previously reported that mazEF, the first regulatable chromosomal 'addiction module' located on the Escherichia coli chromosome, downstream from the relA gene, plays a crucial role in the programmed cell death in bacteria under stressful conditions. It consists of a pair of genes encoding a stable toxin, MazF, and MazE, a labile antitoxin interacting with MazF to form a complex. The cellular target of MazF toxin was recently described to be cellular mRNA, which is degraded by this toxin. On the same operon, downstream to the mazEF genes, we found another open reading frame, which was called mazG. Recently, it was shown that the MazG protein has a nucleotide pyrophosphohydrolase activity. Here we show that mazG is being transcribed in the same polycistronic mRNA with mazEF. We also show that the enzymatic activity of MazG is inhibited by MazEF proteins. When the complex MazEF was added, the enzymatic activity of MazG was about 70% inhibited. We demonstrate that the enzymatic activity of MazG in vivo causes depletion of guanosine 3',5'-bispyrophosphate (ppGpp), synthesized by RelA under amino acid starvation conditions. Based on our results, we propose a model in which this third gene, which is unique for chromosomal addiction systems, has a function of limiting the deleterious activity of MazF toxin. In addition, MazG solves a frequently encountered biological problem: how to avoid the persistence of a toxic product beyond the time when its toxicity is useful to the survival of the population.

Genome sequence of Rickettsia bellii illuminates the role of amoebae in gene exchanges between intracellular pathogens

The recently sequenced Rickettsia felis genome revealed an unexpected plasmid carrying several genes usually associated with DNA transfer, suggesting that ancestral rickettsiae might have been endowed with a conjugation apparatus. Here we present the genome sequence of Rickettsia bellii, the earliest diverging species of known rickettsiae. The 1,552,076 base pair-long chromosome does not exhibit the colinearity observed between other rickettsia genomes, and encodes a complete set of putative conjugal DNA transfer genes most similar to homologues found in Protochlamydia amoebophila UWE25, an obligate symbiont of amoebae. The genome exhibits many other genes highly similar to homologues in intracellular bacteria of amoebae. We sought and observed sex pili-like cell surface appendages for R. bellii. We also found that R. bellii very efficiently multiplies in the nucleus of eukaryotic cells and survives in the phagocytic amoeba, Acanthamoeba polyphaga. These results suggest that amoeba-like ancestral protozoa could have served as a genetic "melting pot" where the ancestors of rickettsiae and other bacteria promiscuously exchanged genes, eventually leading to their adaptation to the intracellular lifestyle within eukaryotic cells.

Expression of the F plasmid ccd toxin-antitoxin system in Escherichia coli cells under nutritional stress

The ccd system of the F plasmid encodes CcdB, a protein toxic to DNA-gyrase, and CcdA, its antitoxin. The function attributed to this system is to contribute to plasmid stability by killing bacteria that lose the plasmid during cell division. However, the function of ccd in resting bacteria is not clear. Results presented show that ccd transcription increases as bacteria enter stationary phase and that the amount of the Ccd proteins is higher in bacteria under nutritional stress than in growing bacteria. Moreover, an increase in the frequency of Lac+ "adaptive" mutations was observed in stationary-phase bacteria that over-express the Ccd proteins.

Induction of Escherichia coli chromosomal mazEF by stressful conditions causes an irreversible loss of viability

mazEF is a stress-induced toxin-antitoxin module located on the chromosomes of many bacteria. Here we induced Escherichia coli chromosomal mazEF by various stressful conditions. We found an irreversible loss of viability, which is the basic characteristic of cell death. These results further support our previous conclusion that E. coli mazEF mediation of cell death is not a passive process, but an active and genetically "programmed" death response.

The chromosomal relBE2 toxin-antitoxin locus of Streptococcus pneumoniae: characterization and use of a bioluminescence resonance energy transfer assay to detect toxin-antitoxin interaction

Proteic toxin-antitoxin (TA) loci were first identified in bacterial plasmids, and they were regarded as involved in stable plasmid maintenance by a so-called 'addiction' mechanism. Later, chromosomally encoded TA loci were identified and their function ascribed to survival mechanisms when bacteria were subjected to stress. In the search for chromosomally encoded TA loci in Gram-positive bacteria, we identified various in the pathogen Streptococcus pneumoniae. Two of these cassettes, sharing homology with the Escherichia coli relBE locus were cloned and tested for their activity. The relBE2Spn locus resulted to be a bona fide TA locus. The toxin exhibited high toxicity towards E. coli and S. pneumoniae, although in the latter, the chromosomal copy of the antitoxin relB2Spn gene had to be inactivated to detect full toxicity. Cell growth arrest caused by expression of the relE2Spn toxin gene could be reverted by expression of the cognate antitoxin, relB2Spn, although prolonged exposition to the toxin led to cell death. The pneumococcal relBE2Spn locus is the first instance of a chromosomally encoded TA system from Gram-positive bacteria characterized in its own host. We have developed a bioluminescence resonance energy transfer (BRET) assay to detect the interactions between the RelB2Spn antitoxin and the RelE2Spn toxin in vivo. This technique has shown to be amenable to a high-throughput screening (HTS), opening new avenues in the search of molecules with potential antibacterial activity able to inhibit TA interactions.

Characterization of mRNA interferases from Mycobacterium tuberculosis

mRNA interferases are sequence-specific endoribonucleases encoded by the toxin-antitoxin systems in the bacterial genomes. MazF from Escherichia coli has been shown to be an mRNA interferase that specifically cleaves at ACA sequences in single-stranded RNAs. It has been shown that MazF induction in E. coli effectively inhibits protein synthesis leading to cell growth arrest in the quasidormant state. Here we have demonstrated that Mycobacterium tuberculosis contains at least seven genes encoding MazF homologues (MazF-mt1 to -mt7), four of which (MazF-mt1, -mt3, -mt4, and -mt6) caused cell growth arrest when induced in E. coli. MazF-mt1 and MazF-mt6 were purified and characterized for their mRNA interferase specificities. We showed that MazF-mt1 preferentially cleaves the era mRNA between U and A in UAC triplet sequences, whereas MazF-mt6 preferentially cleaves U-rich regions in the era mRNA both in vivo and in vitro. These results indicate that M. tuberculosis contains sequence-specific mRNA interferases, which may play a role in the persistent dormancy of this devastating pathogen in human tissues.

Model for RNA Binding and the Catalytic Site of the RNase Kid of the Bacterial parD Toxin–Antitoxin System

The toxin Kid and antitoxin Kis are encoded by the parD operon of Escherichia coli plasmid R1. Kid and its chromosomal homologues MazF and ChpBK have been shown to inhibit protein synthesis in cell extracts and to act as ribosome-independent endoribonucleases in vitro. Kid cleaves RNA preferentially at the 5' side of the A residue in the nucleotide sequence 5'-UA(A/C)-3' of single-stranded regions. Here, we show that RNA cleavage by Kid yields two fragments with a 2':3'-cyclic phosphate group and a free 5'-OH group, respectively. The cleavage mechanism is similar to that of RNases A and T1, involving the uracil 2'-OH group. Via NMR titration studies with an uncleavable RNA mimic, we demonstrate that residues of both monomers of the Kid dimer together form a concatenated RNA-binding surface. Docking calculations based on the NMR chemical shifts, the cleavage mechanism and previously reported mutagenesis data provide a detailed picture of the position of the AUACA fragment within the binding pocket. We propose that residues D75, R73 and H17 form the active site of the Kid toxin, where D75 and R73 are the catalytic base and acid, respectively. The RNA sequence specificity is defined by residues T46, S47, A55, F57, T69, V71 and R73. Our data show the importance of these residues for Kid function, and the implications of our results for related toxins, such as MazF, CcdB and RelE, are discussed.

Iron and fur regulation in Vibrio cholerae and the role of fur in virulence

Regulation of iron uptake and utilization is critical for bacterial growth and for prevention of iron toxicity. In many bacterial species, this regulation depends on the iron-responsive master regulator Fur. In this study we report the effects of iron and Fur on gene expression in Vibrio cholerae. We show that Fur has both positive and negative regulatory functions, and we demonstrate Fur-independent regulation of gene expression by iron. Nearly all of the known iron acquisition genes were repressed by Fur under iron-replete conditions. In addition, genes for two newly identified iron transport systems, Feo and Fbp, were found to be negatively regulated by iron and Fur. Other genes identified in this study as being induced in low iron and in the fur mutant include those encoding superoxide dismutase (sodA), fumarate dehydratase (fumC), bacterioferritin (bfr), bacterioferritin-associated ferredoxin (bfd), and multiple genes of unknown function. Several genes encoding iron-containing proteins were repressed in low iron and in the fur mutant, possibly reflecting the need to reserve available iron for the most critical functions. Also repressed in the fur mutant, but independently of iron, were genes located in the V. cholerae pathogenicity island, encoding the toxin-coregulated pilus (TCP), and genes within the V. cholerae mega-integron. The fur mutant exhibited very weak autoagglutination, indicating a possible defect in expression or assembly of the TCP, a major virulence factor of V. cholerae. Consistent with this observation, the fur mutant competed poorly with its wild-type parental strain for colonization of the infant mouse gut.

Genetic addiction: selfish gene's strategy for symbiosis in the genome

The evolution and maintenance of the phenomenon of postsegregational host killing or genetic addiction are paradoxical. In this phenomenon, a gene complex, once established in a genome, programs death of a host cell that has eliminated it. The intact form of the gene complex would survive in other members of the host population. It is controversial as to why these genetic elements are maintained, due to the lethal effects of host killing, or perhaps some other properties are beneficial to the host. We analyzed their population dynamics by analytical methods and computer simulations. Genetic addiction turned out to be advantageous to the gene complex in the presence of a competitor genetic element. The advantage is, however, limited in a population without spatial structure, such as that in a well-mixed liquid culture. In contrast, in a structured habitat, such as the surface of a solid medium, the addiction gene complex can increase in frequency, irrespective of its initial density. Our demonstration that genomes can evolve through acquisition of addiction genes has implications for the general question of how a genome can evolve as a community of potentially selfish genes.

Toxin-antitoxin modules as bacterial metabolic stress managers

Bacterial genomes frequently contain operons that encode a toxin and its antidote. These 'toxin-antitoxin (TA) modules' have an important role in bacterial stress physiology and might form the basis of multidrug resistance. The toxins in TA modules act as gyrase poisons or stall the ribosome by mediating the cleavage of mRNA. The antidotes contain an N-terminal DNA-binding region of variable fold and a C-terminal toxin-inhibiting domain. When bound to toxin, the C-terminal domain adopts an extended conformation. In the absence of toxin, by contrast, this domain (and sometimes the whole antidote protein) remains unstructured, allowing its fast degradation by proteolysis. Under silent conditions the antidote inhibits the toxin and the toxin-antidote complex acts as a repressor for the TA operon, whereas under conditions of activation proteolytic degradation of the antidote outpaces its synthesis.

Small untranslated RNA antitoxin in Bacillus subtilis

Toxin-antitoxin (TA) modules are pairs of genes in which one member encodes a toxin that is neutralized or whose synthesis is prevented by the action of the product of the second gene, an antitoxin, which is either protein or RNA. We now report the identification of a TA module in the chromosome of Bacillus subtilis in which the antitoxin is an antisense RNA. The antitoxin, which is called RatA (for RNA antitoxin A), is a small (222 nucleotides), untranslated RNA that blocks the accumulation of the mRNA for a toxic peptide TxpA (for toxic peptide A; formerly YqdB). The txpA and ratA genes are in convergent orientation and overlap by ca. 75 nucleotides, such that the 3' region of ratA is complementary to the 3' region of txpA. Deletion of ratA led to increased levels of txpA mRNA and lysis of the cells. Overexpression of txpA also caused cell lysis and death, a phenotype that was prevented by simultaneous overexpression of ratA. We propose that the ratA transcript is an antisense RNA that anneals to the 3' end of the txpA mRNA, thereby triggering its degradation.

Characteristics of Streptococcus mutans strains lacking the MazEF and RelBE toxin-antitoxin modules

Two pairs of genes were identified in Streptococcus mutans with similarity to relBE and mazEF toxin-antitoxin (TA) modules of Escherichia coli. Transcription of mazEF and relBE was repressed by amino acid starvation, and relBE expression was repressed by low pH. Mutants lacking MazF, RelE, or both toxins (MRT1) grew in broth media and formed biofilms as well as the parent. Biofilm populations of MRT1 were more resistant to acid killing than the parent or single mutants. MRT1 also exhibited a longer diauxie during growth on glucose and inulin and displayed decreased phosphoenolpyruvate:sugar phosphotransferase activity. This is the first report that demonstrates a physiological role for TA modules in Gram-positive bacteria.

Crystallization of the C-terminal domain of the addiction antidote CcdA in complex with its toxin CcdB

CcdA and CcdB are the antidote and toxin of the ccd addiction module of Escherichia coli plasmid F. The CcdA C-terminal domain (CcdAC36; 36 amino acids) was crystallized in complex with CcdB (dimer of 2 x 101 amino acids) in three different crystal forms, two of which diffract to high resolution. Form II belongs to space group P2(1)2(1)2(1), with unit-cell parameters a = 37.6, b = 60.5, c = 83.8 A and diffracts to 1.8 A resolution. Form III belongs to space group P2(1), with unit-cell parameters a = 41.0, b = 37.9, c = 69.6 A, beta = 96.9 degrees, and diffracts to 1.9 A resolution.

mazEF: a chromosomal toxin-antitoxin module that triggers programmed cell death in bacteria

mazEF is a toxin-antitoxin module located on the Escherichia coli chromosome and that of some other bacteria, including pathogens. mazF specifies for a stable toxin, MazF, and mazE specifies for a labile antitoxin, MazE, that antagonizes MazF. MazF is a sequence-specific mRNA endoribonuclease that initiates a programmed cell death pathway in response to various stresses. The mazEF-mediated death pathway can act as a defense mechanism that prevents the spread of bacterial phage infection, allowing bacterial populations to behave like multicellular organisms.

The PIN-domain toxin-antitoxin array in mycobacteria

PIN-domains (homologues of the pilT N-terminal domain) are small protein domains of approximately 140 amino acids. They are found in a diverse range of organisms and recent evidence from bioinformatics, biochemistry, structural biology and microbiology suggest that the majority of the prokaryotic PIN-domain proteins are the toxic components of toxin-antitoxin (TA) operons. Several microorganisms have a large cohort of these operons. For example, the genome of Mycobacterium tuberculosis encodes 48 PIN-domain proteins, of which 38 are thought to be involved in TA interactions. This large array of PIN-domain TA operons raises questions as to their evolutionary origin and contemporary functional significance. We suggest that the evolutionary origin of genes encoding mycobacterial PIN-domain TA operons is linked to the mobile gene pool, but that TA operons can become resident within the chromosome of host cells from where they might be recruited to fulfil a variety of roles associated with retardation of cell growth and persistence in stressful environments.

Conformational Change in the Catalytic Site of the Ribonuclease YoeB Toxin by YefM Antitoxin

The eubacterial chromosome encodes various addiction modules that control global levels of translation through RNA degradation. Crystal structures of the Escherichia coli YefM2 (antitoxin)-YoeB (toxin) complex and the free YoeB toxin have been determined. The structure of the heterotrimeric complex reveals an asymmetric disorder-to-order recognition strategy, in which one C terminus of the YefM homodimer exclusively interacts with an atypical microbial ribonuclease (RNase) fold of YoeB. Comparison with the YefM-free YoeB structure indicates a conformational rearrangement of the RNase catalytic site of YoeB, induced by interaction with YefM. Complementary biochemical experiments demonstrate that the YoeB toxin has an in vitro RNase activity that preferentially cleaves at the 3' end of purine ribonucleotides.

The genome sequence of Rickettsia felis identifies the first putative conjugative plasmid in an obligate intracellular parasite

We sequenced the genome of Rickettsia felis, a flea-associated obligate intracellular α-proteobacterium causing spotted fever in humans. Besides a circular chromosome of 1,485,148 bp, R. felis exhibits the first putative conjugative plasmid identified among obligate intracellular bacteria. This plasmid is found in a short (39,263 bp) and a long (62,829 bp) form. R.felis contrasts with previously sequenced Rickettsia in terms of many other features, including a number of transposases, several chromosomal toxin–antitoxin genes, many more spoT genes, and a very large number of ankyrin- and tetratricopeptide-motif-containing genes. Host-invasion-related genes for patatin and RickA were found. Several phenotypes predicted from genome analysis were experimentally tested: conjugative pili and mating were observed, as well as β-lactamase activity, actin-polymerization-driven mobility, and hemolytic properties. Our study demonstrates that complete genome sequencing is the fastest approach to reveal phenotypic characters of recently cultured obligate intracellular bacteria.

Rickettsia felis is an obligate intracellular bacterium that lives in fleas and causes spotted fever in humans. Its genome sequence provides the first evidence that such bacteria can undergo conjugation.

Prokaryotic toxin–antitoxin stress response loci

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.