The rifampicin-inducible genes srnB from F and pnd from R483 are regulated by antisense RNAs and mediate plasmid maintenance by killing of plasmid-free segregants

Type I toxin-antitoxin systems in bacteria: from regulation to biological functions

Toxin-antitoxin systems are ubiquitous in the prokaryotic world and widely distributed among chromosomes and mobile genetic elements. Several different toxin-antitoxin system types exist, but what they all have in common is that toxin activity is prevented by the cognate antitoxin. In type I toxin-antitoxin systems, toxin production is controlled by an RNA antitoxin and by structural features inherent to the toxin messenger RNA. Most type I toxins are small membrane proteins that display a variety of cellular effects. While originally discovered as modules that stabilize plasmids, chromosomal type I toxin-antitoxin systems may also stabilize prophages, or serve important functions upon certain stress conditions and contribute to population-wide survival strategies. Here, we will describe the intricate RNA-based regulation of type I toxin-antitoxin systems and discuss their potential biological functions.

Incompatibility Group I1 (IncI1) Plasmids: Their Genetics, Biology, and Public Health Relevance

Bacterial plasmids are extrachromosomal genetic elements that often carry antimicrobial resistance (AMR) genes and genes encoding increased virulence and can be transmissible among bacteria by conjugation. One key group of plasmids is the incompatibility group I1 (IncI1) plasmids, which have been isolated from multiple Enterobacteriaceae of food animal origin and clinically ill human patients. The IncI group of plasmids were initially characterized due to their sensitivity to the filamentous bacteriophage If1. Two prototypical IncI1 plasmids, R64 and pColIb-P9, have been extensively studied, and the plasmids consist of unique regions associated with plasmid replication, plasmid stability/maintenance, transfer machinery apparatus, single-stranded DNA transfer, and antimicrobial resistance. IncI1 plasmids are somewhat unique in that they encode two types of sex pili, a thick, rigid pilus necessary for mating and a thin, flexible pilus that helps stabilize bacteria for plasmid transfer in liquid environments. A key public health concern with IncI1 plasmids is their ability to carry antimicrobial resistance genes, including those associated with critically important antimicrobials used to treat severe cases of enteric infections, including the third-generation cephalosporins. Because of the potential importance of these plasmids, this review focuses on the distribution of the plasmids, their phenotypic characteristics associated with antimicrobial resistance and virulence, and their replication, maintenance, and transfer.

A Review of the Functional Annotations of Important Genes in the AHPND-Causing pVA1 Plasmid

Acute hepatopancreatic necrosis disease (AHPND) is a lethal shrimp disease. The pathogenic agent of this disease is a special Vibrio parahaemolyticus strain that contains a pVA1 plasmid. The protein products of two toxin genes in pVA1, pirAvp and pirBvp, targeted the shrimp's hepatopancreatic cells and were identified as the major virulence factors. However, in addition to pirAvp and pirBvp, pVA1 also contains about ~90 other open-reading frames (ORFs), which may encode functional proteins. NCBI BLASTp annotations of the functional roles of 40 pVA1 genes reveal transposases, conjugation factors, and antirestriction proteins that are involved in horizontal gene transfer, plasmid transmission, and maintenance, as well as components of type II and III secretion systems that may facilitate the toxic effects of pVA1-containing Vibrio spp. There is also evidence of a post-segregational killing (PSK) system that would ensure that only pVA1 plasmid-containing bacteria could survive after segregation. Here, in this review, we assess the functional importance of these pVA1 genes and consider those which might be worthy of further study.

Type I Toxin-Antitoxin Systems: Regulating Toxin Expression via Shine-Dalgarno Sequence Sequestration and Small RNA Binding

Toxin-antitoxin (TA) systems are small genetic loci composed of two adjacent genes: a toxin and an antitoxin that prevents toxin action. Despite their wide distribution in bacterial genomes, the reasons for TA systems being on chromosomes remain enigmatic. In this review, we focus on type I TA systems, composed of a small antisense RNA that plays the role of an antitoxin to control the expression of its toxin counterpart. It does so by direct base-pairing to the toxin-encoding mRNA, thereby inhibiting its translation and/or promoting its degradation. However, in many cases, antitoxin binding is not sufficient to avoid toxicity. Several cis-encoded mRNA elements are also required for repression, acting to uncouple transcription and translation via the sequestration of the ribosome binding site. Therefore, both antisense RNA binding and compact mRNA folding are necessary to tightly control toxin synthesis and allow the presence of these toxin-encoding systems on bacterial chromosomes.

Hypothesis: type I toxin-antitoxin genes enter the persistence field-a feedback mechanism explaining membrane homoeostasis

Bacteria form persisters, cells that are tolerant to multiple antibiotics and other types of environmental stress. Persister formation can be induced either stochastically in single cells of a growing bacterial ensemble, or by environmental stresses, such as nutrient starvation, in a subpopulation of cells. In many cases, the molecular mechanisms underlying persistence are still unknown. However, there is growing evidence that, in enterobacteria, both stochastically and environmentally induced persistence are controlled by the second messenger (p)ppGpp. For example, the 'alarmone' (p)ppGpp activates Lon, which, in turn, activates type II toxin-antitoxin (TA) modules to thereby induce persistence. Recently, it has been shown that a type I TA module, hokB/sokB, also can induce persistence. In this case, the underlying mechanism depends on the universally conserved GTPase Obg and, surprisingly, also (p)ppGpp. In the presence of (p)ppGpp, Obg stimulates hokB transcription and induces persistence. HokB toxin expression is under both negative and positive control: SokB antisense RNA inhibits hokB mRNA translation, while (p)ppGpp and Obg together stimulate hokB transcription. HokB is a small toxic membrane protein that, when produced in modest amounts, leads to membrane depolarization, cell stasis and persistence. By contrast, overexpression of HokB disrupts the membrane potential and kills the cell. These observations raise the question of how expression of HokB is regulated. Here, I propose a homoeostatic control mechanism that couples HokB expression to the membrane-bound RNase E that degrades and inactivates SokB antisense RNA.This article is part of the themed issue 'The new bacteriology'.

Sequence of the R1 plasmid and comparison to F and R100

The R1 antibiotic resistance plasmid, originally discovered in a clinical Salmonella isolate in London, 1963, has served for decades as a key model for understanding conjugative plasmids. Despite its scientific importance, a complete sequence of this plasmid has never been reported. We present the complete genome sequence of R1 along with a brief review of the current knowledge concerning its various genetic systems and a comparison to the F and R100 plasmids. R1 is 97,566 nucleotides long and contains 120 genes. The plasmid consists of a backbone largely similar to that of F and R100, a Tn21-like transposon that is nearly identical to that of R100, and a unique 9-kb sequence that bears some resemblance to sequences found in certain Klebsiella oxytoca strains. These three regions of R1 are separated by copies of the insertion sequence IS1. Overall, the structure of R1 and comparison to F and R100 suggest a fairly stable shared conjugative plasmid backbone into which a variety of mobile elements have inserted to form an "accessory" genome, containing multiple antibiotic resistance genes, transposons, remnants of phage genes, and genes whose functions remain unknown.

pCERC3 from a commensal ST95 Escherichia coli: A ColV virulence-multiresistance plasmid carrying a sul3-associated class 1 integron

The rare sulphonamide resistance gene sul3 was found in the commensal Escherichia coli ST95 strain 22.1-R1 that was isolated in 2010 from the faeces of a healthy Australian adult. The genome of 22.1-R1 was sequenced and a 144,344bp RepFII/FIB plasmid, pCERC3, carrying sul3 was assembled. The sul3 gene is part of a class 1 integron featuring a sul3-containing conserved segment (sul3-CS) that replaced the classic sul1-containing 3'-conserved segment (3'-CS) usually seen in class 1 integrons. The integron contained the cassette array dfrA12-orfF-aadA2-cmlA1-aadA1-qacH, conferring resistance to trimethoprim, streptomycin, spectinomycin, chloramphenicol and quaternary ammonium compound. Two additional antibiotic resistance genes, blaTEM (ampicillin resistance) and tetA(B) (tetracycline) were adjacent to the integron, forming a single resistance region. In pCERC3, the sul3-type class 1 integron was flanked by sequence derived from the tnp and mer modules of Tn21 and was in the same location as In2, the sul1-containing In5-type class 1 integron of Tn21. At one end the sequence extends into Tn2670-derived sequence and then into sequence derived from the plasmid NR1 (R100). Examination of the sequences of eleven more complete sul3-containing plasmids in GenBank confirmed the relationship between sul3-associated integrons and Tn21/Tn2670/NR1. This suggests that the events that formed sul3-associated class 1 integrons occurred within the Tn21/Tn2670 context, most likely in NR1 or a related plasmid. The backbone of pCERC3 is most closely related to the backbones of ColV virulence plasmids and contains a complete ColV operon as well as several virulence associated genes and gene clusters. Hence, pCERC3 is both an antibiotic resistance and virulence plasmid.

Linking bacterial type I toxins with their actions

Bacterial type I toxin-antitoxin systems consist of stable toxin-encoding mRNAs whose expression is counteracted by unstable RNA antitoxins. Accumulating evidence suggests that these players belong to broad regulatory networks influencing overall bacterial physiology. The majority of known transmembrane type I toxic peptides have conserved structural characteristics. However, recent studies demonstrated that their mechanisms of toxicity are diverse and complex. To better assess the current state of the art, type I toxins can be grouped into two classes according to their location and mechanisms of action: membrane-associated toxins acting by pore formation and/or by nucleoid condensation; and cytosolic toxins inducing nucleic acid cleavage. This classification will evolve as a result of future investigations.

The opportunistic marine pathogen Vibrio parahaemolyticus becomes virulent by acquiring a plasmid that expresses a deadly toxin

Acute hepatopancreatic necrosis disease (AHPND) is a severe, newly emergent penaeid shrimp disease caused by Vibrio parahaemolyticus that has already led to tremendous losses in the cultured shrimp industry. Until now, its disease-causing mechanism has remained unclear. Here we show that an AHPND-causing strain of V. parahaemolyticus contains a 70-kbp plasmid (pVA1) with a postsegregational killing system, and that the ability to cause disease is abolished by the natural absence or experimental deletion of the plasmid-encoded homologs of the Photorhabdus insect-related (Pir) toxins PirA and PirB. We determined the crystal structure of the V. parahaemolyticus PirA and PirB (PirA(vp) and PirB(vp)) proteins and found that the overall structural topology of PirA(vp)/PirB(vp) is very similar to that of the Bacillus Cry insecticidal toxin-like proteins, despite the low sequence identity (<10%). This structural similarity suggests that the putative PirAB(vp) heterodimer might emulate the functional domains of the Cry protein, and in particular its pore-forming activity. The gene organization of pVA1 further suggested that pirAB(vp) may be lost or acquired by horizontal gene transfer via transposition or homologous recombination.

sRNA antitoxins: more than one way to repress a toxin

Bacterial toxin-antitoxin loci consist of two genes: one encodes a potentially toxic protein, and the second, an antitoxin to repress its function or expression. The antitoxin can either be an RNA or a protein. For type I and type III loci, the antitoxins are RNAs; however, they have very different modes of action. Type I antitoxins repress toxin protein expression through interacting with the toxin mRNA, thereby targeting the mRNA for degradation or preventing its translation or both; type III antitoxins directly bind to the toxin protein, sequestering it. Along with these two very different modes of action for the antitoxin, there are differences in the functions of the toxin proteins and the mobility of these loci between species. Within this review, we discuss the major differences as to how the RNAs repress toxin activity, the potential consequences for utilizing different regulatory strategies, as well as the confirmed and potential biological roles for these loci across bacterial species.

To be or not to be: regulation of restriction-modification systems and other toxin-antitoxin systems

One of the simplest classes of genes involved in programmed death is that containing the toxin–antitoxin (TA) systems of prokaryotes. These systems are composed of an intracellular toxin and an antitoxin that neutralizes its effect. These systems, now classified into five types, were initially discovered because some of them allow the stable maintenance of mobile genetic elements in a microbial population through postsegregational killing or the death of cells that have lost these systems. Here, we demonstrate parallels between some TA systems and restriction–modification systems (RM systems). RM systems are composed of a restriction enzyme (toxin) and a modification enzyme (antitoxin) and limit the genetic flux between lineages with different epigenetic identities, as defined by sequence-specific DNA methylation. The similarities between these systems include their postsegregational killing and their effects on global gene expression. Both require the finely regulated expression of a toxin and antitoxin. The antitoxin (modification enzyme) or linked protein may act as a transcriptional regulator. A regulatory antisense RNA recently identified in an RM system can be compared with those RNAs in TA systems. This review is intended to generalize the concept of TA systems in studies of stress responses, programmed death, genetic conflict and epigenetics.

The hok mRNA family

The hok/sok toxin-antitoxin system of Escherichia coli plasmid R1 increases plasmid maintenance by killing plasmid-free daughter cells. The hok/sok locus specifies two RNAs: hok mRNA, which encodes a toxic transmembrane protein, and sok antisense RNA, which binds a complementary region in the hok mRNA and induces transcript degradation. During cell growth, the cis-encoded sok RNA inhibits expression of the Hok toxin. In plasmid-free segregants, the rapid decay of sok RNA relative to hok mRNA permits Hok translation, leading to cell death. This post-segregational killing mechanism relies upon the ability of the hok mRNA to adopt alternative structural configurations, which affect ease of translation and the susceptibility of the molecule to degradation. The full-length hok transcript is stable, highly structured and immune to ribosome and antisense RNA binding. Gradual 3' end processing produces dramatic structural rearrangements in the mRNA, which render the molecule translationally active and expose the sok RNA binding site. During transcription, premature ribosome and sok binding are prevented through the formation of transient metastable hairpins in the 5' end of the nascent transcript. Several hok mRNA paralogs have been identified in the genome of E. coli, and Hok protein orthologs found in the genomes of Enterobacteria. Using a combination of automated search and extensive manual editing, we compiled a multiple sequence alignment for the hok mRNA. All three experimentally validated hok mRNA structures are mapped onto this alignment, which has been submitted to the Rfam database for RNA families.

Divergently overlapping cis-encoded antisense RNA regulating toxin-antitoxin systems from E. coli: hok/sok, ldr/rdl, symE/symR

Toxin-antitoxin (TA) systems are categorized into three classes based on the type of antitoxin. In type I TA systems, the antitoxin is a small antisense RNA that inhibits translation of small toxic proteins by binding to the corresponding mRNAs. Those type I TA systems were originally identified as plasmid stabilization modules rendering a post-segregational killing (PSK) effect on the host cells. The type I TA loci also exist on the Escherichia coli chromosome but their biological functions are less clear. Genetic organization and regulatory elements of hok/sok and ldr/rdl families are very similar and the toxins are predicted to contain a transmembrane domain, but otherwise share no detectable sequence similarity. This review will give an overview of the type I TA modules of E. coli K-12, especially hok/sok, ldr/rdl and SOS-inducible symE/symR systems, which are regulated by divergently overlapping cis-encoded antisense RNAs.

Analyzing the decay of stable RNAs in E. coli

Stable RNA, mainly comprised of rRNA and tRNA, accounts for the majority of cellular RNA. Although normally stable under favorable growth conditions in the laboratory, these RNA species undergo extensive degradation responding to many environmental changes and stress conditions. Multiple ribonucleases and other enzymes may be involved in the decay of stable RNA. The onset and rate of degradation are probably determined by the status of the RNA as well as the availability of the degrading activities. The elucidation of pathways for stable RNA decay has been benefited by many biochemical and genetic approaches. These include purification of the enzymes and characterization of their substrate specificity in vitro, and studies of stable RNA decay by inactivating and overexpressing the degradation activities in vivo. Furthermore, RNA degradation intermediates have been characterized in detail, such as determining the sizes, the sequences, the 5'- and 3'-termini, etc. In this work, we describe the methods that are most commonly used in the study of the degradation and processing of stable RNA in E. coli. Most of them should be also useful in studies of other RNA species or RNA from other organisms.

Small toxic proteins and the antisense RNAs that repress them

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.

Bacterial mitosis: partitioning protein ParA oscillates in spiral-shaped structures and positions plasmids at mid-cell

The par2 locus of Escherichia coli plasmid pB171 encodes oscillating ATPase ParA, DNA binding protein ParB and two cis-acting DNA regions to which ParB binds (parC1 and parC2). Three independent techniques were used to investigate the subcellular localization of plasmids carrying par2. In cells with a single plasmid focus, the focus located preferentially at mid-cell. In cells with two foci, these located at quarter-cell positions. In the absence of ParB and parC1/parC2, ParA-GFP formed stationary helices extending from one end of the nucleoid to the other. In the presence of ParB and parC1/parC2, ParA-GFP oscillated in spiral-shaped structures. Amino acid substitutions in ParA simultaneously abolished ParA spiral formation, oscillation and either plasmid localization or plasmid separation at mid-cell. Therefore, our results suggest that ParA spirals position plasmids at the middle of the bacterial nucleoid and subsequently separate them into daughter cells.

Intricate interactions within the ccd plasmid addiction system

The ccd addiction system plays a crucial role in the stable maintenance of the Escherichia coli F plasmid. It codes for a stable toxin (CcdB) and a less stable antidote (CcdA). Both are expressed at low levels during normal cell growth. Upon plasmid loss, CcdB outlives CcdA and kills the cell by poisoning gyrase. The interactions between CcdB, CcdA, and its promoter DNA were analyzed. In solution, the CcdA-CcdB interaction is complex, leading to various complexes with different stoichiometry. CcdA has two binding sites for CcdB and vice versa, permitting soluble hexamer formation but also causing precipitation, especially at CcdA:CcdB ratios close to one. CcdA alone, but not CcdB, binds to promoter DNA with high on and off rates. The presence of CcdB enhances the affinity and the specificity of CcdA-DNA binding and results in a stable CcdA*CcdB*DNA complex with a CcdA:CcdB ratio of one. This (CcdA(2)CcdB(2))(n) complex has multiple DNA-binding sites and spirals around the 120-bp promoter region.

The double par locus of virulence factor pB171: DNA segregation is correlated with oscillation of ParA

Prokaryotic plasmids and chromosomes encode partitioning (par) loci that segregate DNA to daughter cells before cell division. Recent database analyses showed that almost all known par loci encode an ATPase and a DNA-binding protein, and one or more cis-acting regions where the proteins act. All par-encoded ATPases belong to one of two protein superfamilies, Walker-type and actin-like ATPases. This property was recently used to divide par loci into Types I and II loci. We show here that the Escherichia coli virulence factor pB171 encodes a double par locus that consists of one Type I and one Type II locus. Separately, each locus stabilized a test-plasmid efficiently. Together, the two loci mediated even more efficient plasmid stabilization. The par loci have a unique genetic organization in that they share a common central region at which the two different DNA-binding proteins probably act. Interestingly, a fusion protein consisting of the Walker-type ParA ATPase and Gfp was functional and oscillated in nucleoid regions on a time scale of minutes. ParA-green fluorescent protein (Gfp) oscillation depended on both ParB and parC but was independent of minCDE. Point mutations in the Walker A box motif simultaneously abolished plasmid stabilization and ParA-Gfp oscillation. These observations raise the possibility that ParA oscillation is prerequisite for active plasmid segregation.

Postsegregational killing does not increase plasmid stability but acts to mediate the exclusion of competing plasmids

Postsegregational killing (PSK) systems consist of a tightly linked toxin-antitoxin pair. Antitoxin must be continually produced to prevent the longer lived toxin from killing the cell. PSK systems on plasmids are widely believed to benefit the plasmid by ensuring its stable vertical inheritance. However, experimental tests of this "stability" hypothesis were not consistent with its predictions. We suggest an alternative hypothesis to explain the evolution of PSK: that PSK systems have been selected through benefiting host plasmids in environments where plasmids must compete during horizontal reproduction. In this "competition" hypothesis, success of PSK systems is a consequence of plasmid-plasmid competition, rather than from an adaptive plasmid-host relationship. In support of this hypothesis, a plasmid-encoded parDE PSK system mediated the exclusion of an isogenic DeltaparDE plasmid. An understanding of how PSK systems influence plasmid success may provide insight into the evolution of other determinants (e.g., antibiotic resistance and virulence) also rendering a cell potentially dependent on an otherwise dispensable plasmid.

The antisense RNA of the par locus of pAD1 regulates the expression of a 33-amino-acid toxic peptide by an unusual mechanism

The par stability determinant of the Enterococcus faecalis plasmid pAD1 is the first antisense RNA-regulated post-segregational killing system (PSK) identified in a Gram-positive organism. Par encodes two small, convergently transcribed RNAs, designated RNA I and RNA II, which are the toxin and antidote of the par PSK system respectively. RNA I encodes an open reading frame of 33 codons designated fst. The results presented here demonstrate that the peptide encoded by fst is the par toxin. The fst sequence was shown to be sufficient for cell killing, and removal of the final codon inactivated the toxin. In vitro translation reactions of purified RNA I transcript produced a product of the expected size for the fst-encoded peptide. This product was not produced when purified RNA II transcript was added to the translation reaction. Toeprint analysis demonstrated that purified RNA II was able to inhibit ribosome binding to RNA I. These data suggest that fst expression is regulated by RNA II via an antisense RNA mechanism. In vitro translation studies and toeprint analyses also indicated that fst expression is internally regulated by a stem-loop structure at the 5' end of RNA I. Removal of this structure resulted in better ribosome binding to RNA I and a 300-fold increase in production of the fst-encoded peptide. Finally, RNA II was shown to be less stable than RNA I in vivo, providing a basis for the selective expression of fst in plasmid-free cells.

Antisense RNA regulation of the pAD1 par post-segregational killing system requires interaction at the 5' and 3' ends of the RNAs

The par stability determinant of the Enterococcus faecalis plasmid pAD1 is the first antisense RNA-regulated post-segregational killing system (PSK) identified in a Gram-positive organism. Par encodes two small, convergently transcribed RNAs, designated RNA I and RNA II, which are the toxin and antidote of the par PSK system respectively. RNA I encodes an open reading frame for a 33-amino-acid toxin called Fst. Expression of fst is regulated post-transcriptionally by RNA II. In this paper, RNA II is shown to interact with RNA I by a unique antisense RNA mechanism. RNA I and RNA II contain complementary direct repeats at their 5' ends and a complementary transcriptional terminator stem-loop at their 3' ends. Deletion of the terminator or mutations within the terminator loop of RNA II severely reduced the rate of interaction in vitro. Mutations in the 5' direct repeats of RNA II prevented the RNAs from interacting in vitro. For these mutations in RNA II, complementary mutations in RNA I were shown to restore interaction. The reduced binding efficiency of the RNA II mutants was paralleled by the failure of these mutants to suppress par-mediated killing in vivo. These results indicate that regions at both the 5' and the 3' ends of the par transcripts are important for RNA I-RNA II interaction.

Multiple hok genes on the chromosome of Escherichia coli

The hok/sok locus of plasmid R1 mediates plasmid stabilization by the killing of plasmid-free cells. Many bacterial plasmids carry similar loci. For example, the F plasmid carries two hok homologues, flm and srnB, that mediate plasmid stabilization by this specialized type of programmed cell death. Here, we show that the chromosome of E. coli K-12 codes for five hok homologous loci, all of which specify Hok-like toxins. Three of the loci appear to be inactivated by the insertion elements IS150 or IS186 located close to but not in the toxin-encoding reading frames (i.e. hokA, hokC and hokE), one system is probably inactivated by point mutation (hokB), whereas the fifth system is inactivated by a major genetic rearrangement (hokD). In the ECOR collection of wild-type E. coli strains, we identified hokA and hokC loci without IS elements. A molecular and a genetic analysis show that the hokA and hokC loci specify unstable antisense RNAs and stable toxin-encoding mRNAs that are processed at their 3' ends. An alignment of the mRNA sequences reveals all the regulatory elements known to be required for correct folding and refolding of the plasmid-encoded mRNAs. The conserved elements include fbi that ensure a long-range interaction in the full-length mRNAs, and tac and antisense RNA target stem-loops that are required for translation and rapid antisense RNA binding of the processed mRNAs. Consistently, we find that the chromosome-encoded mRNAs are processed at their 3' ends, resulting in the presumed translationally active mRNAs. Despite the presence of all of the regulatory elements, the chromosome-encoded loci do not mediate plasmid stabilization by killing of plasmid-free cells. The chromosome-encoded mRNAs are poorly translated in vitro, thus yielding an explanation for the lacking phenotype. These observations suggest that the chromosomal hok-like genes may be induced by an as yet unknown signal.

Antisense RNA-regulated programmed cell death

Eubacterial plasmids and chromosomes encode multiple killer genes belonging to the hok gene family. The plasmid-encoded killer genes mediate plasmid stabilization by killing plasmid-free cells. This review describes the genetics, molecular biology, and evolution of the hok gene family. The complicated antisense RNA-regulated control-loop that regulates posttranscriptional and postsegregational activation of killer mRNA translation in plasmid-free cells is described in detail. Nucleotide covariations in the mRNAs reveal metastable stem-loop structures that are formed at the mRNA 5' ends in the nascent transcripts. The metastable structures prevent translation and antisense RNA binding during transcription. Coupled nucleotide covariations provide evidence for a phylogenetically conserved mRNA folding pathway that involves sequential dynamic RNA rearrangements. Our analyses have elucidated an intricate mechanism by which translation of an antisense RNA-regulated mRNA can be conditionally activated. The complex phylogenetic relationships of the plasmid- and chromosome-encoded systems are also presented and discussed.

Programmed cell death by hok/sok of plasmid R1: coupled nucleotide covariations reveal a phylogenetically conserved folding pathway in the hok family of mRNAs

The hok/sok system of plasmid R1 mediates plasmid maintenance by killing of plasmid-free cells. Translation of the stable toxin-encoding hok mRNA is repressed by the unstable Sok antisense RNA. Using genetic algorithm simulations and phylogenetic comparisons, we analyse five plasmid-encoded and two chromosome-encoded hok-homologous mRNAs. A similar folding pathway was found for all mRNAs. Metastable hairpins at the very 5'-ends of the mRNAs were predicted to prevent the formation of structures required for translation and antisense RNA binding. Thus the folding of the mRNA 5'-ends appears to explain the apparent inactivity of the nascent transcripts. In the full-length mRNAs, long-range 5' to 3' interactions were predicted in all cases. The 5' to 3' interactions lock the mRNAs in inactive configurations. Translation of the mRNAs is activated by 3' exonucleolytic processing. Simulation of the 3' processing predicted that it triggers rearrangements of the mRNA 5'-ends with the formation of translational activator and antisense RNA target hairpins. Alignment of the mRNA sequences revealed a large number of nucleotide covariations that support the existence of the proposed secondary structures. Furthermore, coupled covariations support the folding pathway and provide evidence that the mRNA 5'-ends pair with three different partners during the proposed series of dynamic RNA rearrangements.

Combining the hok/sok, parDE, and pnd postsegregational killer loci to enhance plasmid stability

To enhance plasmid segregational stability in bacterial cells, two pairs of independent postsegregational killing loci (genes which induce host killing upon plasmid loss) isolated from plasmids R1, R483, or RP4 (hok+/sok+ pnd+ or hok+/sok+ parDE+) were cloned into a common site of the beta-galactosidase expression vector pMJR1750 (ptac::lacZ+) to form a series of plasmids in which the effect of one or two stability loci on segregational plasmid stability could be discerned. Adding two antisense killer loci (hok+/sok+ pnd+) decreased the specific growth rate by 50% though they were more effective at reducing segregational instability than hok+/sok+ alone. With the ptac promoter induced fully (2.0 mM isopropyl-beta-D-thiogalactopyranoside) and no antibiotic selection pressure, the combination of a proteic killer locus (parDE+) with antisense killer loci (hok+/sok+) had a negligible impact on specific growth rate, maintained high beta-galactosidase expression, and led to a 30 and 190% increase in segregational stability (based on stable generations) as compared to plasmids containing either hok+/sok+ or parDE+ alone, respectively. Use of hok+/sok+ or parDE+ alone with high cloned-gene expression led to ninefold and fourfold increases in the number of stable generations, respectively. Two convenient cloning cassettes have been constructed to facilitate cloning the dual hok+/sok+ parDE+ and hok+/sok+ pnd+ killer systems.

Nucleotide sequence and characterization of the trbABC region of the IncI1 Plasmid R64: existence of the pnd gene for plasmid maintenance within the transfer region

A 6.72-kb DNA sequence between the exc gene and the oriT operon within the transfer region of IncI1 plasmid R64 was sequenced and characterized. Three novel transfer genes, trbA, trbB, and trbC, were found in this region, along with the pnd gene responsible for plasmid maintenance. The trbABC genes appear to be organized into an operon located adjacent to the oriT operon in the opposite orientation. The trbA and trbC genes were shown to be indispensable for R64 plasmid transfer, while residual transfer activity was detected in the case of R64 derivatives carrying the trbB++ deletion mutation. The T7 RNA polymerase-promoter system revealed that the trbB gene produced a 43-kDa protein and the trbC gene produced an 85-kDa protein. The nucleotide sequence of the pnd gene is nearly identical to that of plasmid R483, indicating a function in plasmid maintenance. The plasmid stability test indicated that the mini-R64 derivatives with the pnd gene are more stably maintained in Escherichia coli cells under nonselective conditions than the mini-R64 derivatives without the pnd gene. It was also shown that the R64 transfer system itself is involved in plasmid stability to a certain degree. Deletion of the pnd gene from the tra+ mini-R64 derivative did not affect transfer frequency. DNA segments between the exc and trbA genes for IncI1 plasmids R64, Colb-P9, and R144 were compared in terms of their physical and genetic organization.

Mechanism of post-segregational killing by hok-homologue pnd of plasmid R483: two translational control elements in the pnd mRNA

The pnd system of plasmid R483 mediates plasmid stabilization by killing of plasmid-free cells. The pnd mRNA is very stable and can be translated into PndA protein, a cell toxin which kills the cells from within by damaging the cell membrane. Translation of the pnd mRNA is inhibited by the PndB antisense, a small labile RNA of 63 nt. The rapid decay of the PndB antidote leads to onset of PndA synthesis in plasmid-free segregants or after addition of rifampicin. Surprisingly however, the full-length pnd mRNA was found to be translationally inactive whereas a 3'-end truncated version of it was found to be active. We have therefore suggested previously, that the 3'-end of the full-length pnd mRNA encodes a fold-back inhibitory sequence (fbi), which prevents its translation. Here we present an analysis of the metabolism of the pnd mRNAs. A mutational analysis shows that single point mutations in the fbi motif results in more rapid truncation. The fbi mutations could not be complemented by second-site mutations in either of the pndA or pndC Shine-Dalgarno (SD) elements. Surprisingly, mutations in the pndC SD element also lead to a more rapid truncation. The effect of these latter mutations was, however, complemented by mutations in a proposed anti-SD element upstream of the pndC SD. Mutations in the anti-SD element were lethal. These results show, that the pnd mRNA contains two negative control elements, one located in its very 3'-end (fbi), and one located just upstream of the pndC SD region (the anti-SD element). These observations add to the complexity of the induction scheme previously proposed to explain activation of pndA expression in plasmid-free cells: In addition to its negative effect of translation, the fbi structure also maintains a reduced processing rate in the 3'-end of the mRNA. This permits the accumulation of a reservoir of pnd mRNA, which can be activated by 3'-end processing in plasmid-free cells. The anti-SD may prevent translation of the pnd mRNA during transcription, thus preventing detrimental synthesis of toxin.

A substrate-dependent biological containment system for Pseudomonas putida based on the Escherichia coli gef gene

A model substrate-dependent suicide system to biologically contain Pseudomonas putida KT2440 is reported. The system consists of two elements. One element carries a fusion between a synthetic lac promoter (PA1-04/03) and the gef gene, which encodes a killing function. This element is contained within a transposaseless mini-Tn5 transposon so that it can be integrated at random locations on the Pseudomonas chromosome. The second element, harbored by plasmid pCC102, is designed to control the first and bears a fusion between the promoter of the P. putida TOL plasmid-encoded meta-cleavage pathway operon (Pm) and the lacI gene, encoding the Lac repressor, plus xylS2, coding for a positive regulator of Pm. In liquid culture under optimal growth conditions and in sterile and nonsterile soil microcosms, P. putida KT2440 (pWWO) bearing the containment system behaves as designed. In the presence of a XylS effector, such as m-methylbenzoate, the LacI protein is synthesized, preventing the expression of the killing function. In the absence of effectors, expression of the PA1-04/03::gef cassette is no longer prevented and a high rate of cell killing is observed. Fluctuation test analyses revealed that mutants resistant to cell killing arise at a frequency of around 10(-5) to 10(-6) per cell per generation. Mutations are linked to the killing element rather than to the regulatory one. In bacteria bearing two copies of the killing cassette, the rate of appearance of mutants resistant to killing decreased to as low as 10(-8) per cell per generation.

Determinants of an unusually stable mRNA in the bacterium Myxococcus xanthus

Myxococcus xanthus is a Gram-negative bacterium which has a complex life cycle that includes development (fruiting body formation). The gene for myxobacterial haemagglutinin, mbhA, is developmentally regulated and highly expressed. In this report we show that the mbhA mRNA is exceptionally stable for a prokaryotic organism, exhibiting a chemical half life (t1/2) of 150 min at 18 h of development. The mbhA mRNA was not stable in vegetatively growing cells nor was it stable when expressed in Escherichia coli. We have used site-directed mutagenesis of the mbhA gene to analyse some of the determinants which mediate the stability of the mbhA transcript. Sequences within the 3'-untranslated region (3'-UTR) were found to be crucial for mRNA stability. This region of mRNA can potentially form an extremely stable stem-loop structure immediately adjacent to the translational stop codon. A deletion within this region caused a 10-fold increase in the decay rate of the transcript. Furthermore, conditions which were associated with reduced mbhA translation or mutations that caused premature termination of translation drastically reduced mRNA stability even in the presence of the wild type 3'-UTR. These results suggest that a significant aspect of mbhA mRNA stability involves a synergistic interaction of the translational machinery with sequence elements within the 3'-UTR.

Mechanism of killer gene activation. Antisense RNA-dependent RNase III cleavage ensures rapid turn-over of the stable hok, srnB and pndA effector messenger RNAs

The hok/sok, srnB and pnd systems of plasmids R1, F and R438 mediate plasmid maintenance by killing plasmid-free segregants. The systems encode exceptionally stable full-length mRNAs that code for potent cell toxins that kill the cells from within. The systems also produce truncated mRNAs whose appearance is correlated with killing activity. The truncated mRNAs are shortened by 35 to 70 nucleotides in the 3' ends, but have the same 5' ends as the full-length transcripts. Translation of the stable killer mRNAs is regulated by unstable antisense RNAs that are complementary to the leader regions of the full-length and truncated mRNAs. We show here, that both the presence of the antisense RNA and of the host enzyme RNase III is required for rapid cleavage of the truncated mRNAs, and we map the cleavage point in the Hok mRNA in vitro and in vivo to be located between nucleotides +245 and +246. The RNase III cleavage products of the Hok mRNA were found to be very unstable in vivo. Thus, RNase III cleavage seems to be the initial event leading to decay of the killer mRNAs. In an rnc- strain, the truncated mRNA species were found in steady-state cells. This observation indicates that the truncated mRNAs are formed constitutively and independently of the presence of the antisense RNAs. Thus, the antisense RNAs prevent the accumulation of the truncated mRNAs solely by mediating their rapid hydrolysis by RNase III. Furthermore, the generation of the truncated killer mRNAs in the rnc- host indicate that RNase III is dispensable for induction of the killer gene systems. Based on these and on observations obtained previously, we present a molecular model that explains the activation of the killer mRNAs in plasmid-free segregants and after addition of rifampicin.

Analysis of an Escherichia coli mutant strain resistant to the cell-killing function encoded by the gef gene family

The chromosomal genes gef and relF from Escherichia coli and the plasmid-encoded genes hok, flmA, srnB, and pndA constitute the gef gene family, which encodes a cell-killing function. In order to investigate the mechanism of cell killing we have isolated an E. coli mutant strain that is resistant to the overexpression of the toxic proteins encoded by the gef gene family. This phenotype requires at least two mutations, one of which has been mapped to 55.2 minutes. This mutation was sequenced and shown to represent a single base substitution in an open reading frame (ORF178) encoding a putative membrane protein having a molecular mass of 20.1 kDa. ORF178 and an upstream frame, ORF190, probably constitute an operon.

Mechanism of post-segregational killing by the hok/sok system of plasmid R1

The hok/sok locus of plasmid R1, which mediates plasmid stabilization by killing of plasmid-free segregants, codes for two RNAs, Hok mRNA and Sok antisense RNA. Hok mRNA encodes the Hok killer protein of 52 amino acid residues. Expression of hok is regulated post-transcriptionally by Sok antisense RNA. Killing of plasmid-free daughter-cells by the hok/sok system is accomplished through differential decay of the Hok and Sok-RNAs: Hok mRNA is very stable while Sok-RNA decays rapidly, thus leading to derepression of Hok mRNA translation in plasmid-free segregants, ensuring a rapid and selective killing of these cells. Sok antisense RNA is complementary to the leader region of the Hok mRNA. However, the region of complementarity does not overlap with the hok Shine-Dalgarno sequence. Thus, Sok-RNA regulates hok translation indirectly by an as yet unknown mechanism. We show here that Sok antisense RNA regulates the translation of another reading frame located in the hok/sok locus. This new reading frame, which overlaps with almost the entire hok gene, was denoted mok (mediation of killing). Point-mutations that prevent mok translation through the hok translational initiation region abolish efficient expression of hok. Furthermore, these mutations abolish the Sok-RNA-mediated control of hok gene expression. Hence, the antisense-RNA-mediated regulation of the hok gene seems to occur via translational coupling between the hok and mok reading-frames.