Control of cell division by sex factor F in Escherichia coli. I. The 42.84-43.6 F segment couples cell division of the host bacteria with replication of plasmid DNA

Backbone assignment of CcdB_G100T toxin from E.coli in complex with the toxin binding C-terminal domain of its cognate antitoxin CcdA

The CcdAB system expressed in the E.coli cells is a prototypical example of the bacterial toxin-antitoxin (TA) systems that ensure the survival of the bacterial population under adverse environmental conditions. The solution and crystal structures of CcdA, CcdB and of CcdB in complex with the toxin-binding C-terminal domain of CcdA have been reported. Our interest lies in the dynamics of CcdB-CcdA complex formation. Solution NMR studies have shown that CcdB_G100T, in presence of saturating concentrations of CcdA-c, a truncated C-terminal fragment of CcdA exists in equilibrium between two major populations. Sequence specific backbone resonance assignments of both equilibrium forms of the ~ 27 kDa complex, have been obtained from a suite of triple resonance NMR experiments acquired on 2H, 13C, 15N enriched samples of CcdB_G100T. Analysis of 1H, 13Cα, 13Cβ secondary chemical shifts, shows that both equilibrium forms of CcdB_G100T have five beta-strands and one alpha-helix as the major secondary structural elements in the tertiary structure. The results of these studies are presented below.

Mutational scan inferred binding energetics and structure in intrinsically disordered protein CcdA

Unlike globular proteins, mutational effects on the function of Intrinsically Disordered Proteins (IDPs) are not well-studied. Deep Mutational Scanning of a yeast surface displayed mutant library yields insights into sequence-function relationships in the CcdA IDP. The approach enables facile prediction of interface residues and local structural signatures of the bound conformation. In contrast to previous titration-based approaches which use a number of ligand concentrations, we show that use of a single rationally chosen ligand concentration can provide quantitative estimates of relative binding constants for large numbers of protein variants. This is because the extended interface of IDP ensures that energetic effects of point mutations are spread over a much smaller range than for globular proteins. Our data also provides insights into the much-debated role of helicity and disorder in partner binding of IDPs. Based on this exhaustive mutational sensitivity dataset, a rudimentary model was developed in an attempt to predict mutational effects on binding affinity of IDPs that form alpha-helical structures upon binding.

The High Mutational Sensitivity of ccdA Antitoxin Is Linked to Codon Optimality

Deep mutational scanning studies suggest that synonymous mutations are typically silent and that most exposed, nonactive-site residues are tolerant to mutations. Here, we show that the ccdA antitoxin component of the Escherichia coli ccdAB toxin-antitoxin system is unusually sensitive to mutations when studied in the operonic context. A large fraction (∼80%) of single-codon mutations, including many synonymous mutations in the ccdA gene shows inactive phenotype, but they retain native-like binding affinity towards cognate toxin, CcdB. Therefore, the observed phenotypic effects are largely not due to alterations in protein structure/stability, consistent with a large region of CcdA being intrinsically disordered. E. coli codon preference and strength of ribosome-binding associated with translation of downstream ccdB gene are found to be major contributors of the observed ccdA mutant phenotypes. In select cases, proteomics studies reveal altered ratios of CcdA:CcdB protein levels in vivo, suggesting that the ccdA mutations likely alter relative translation efficiencies of the two genes in the operon. We extend these results by studying single-site synonymous mutations that lead to loss of function phenotypes in the relBE operon upon introduction of rarer codons. Thus, in their operonic context, genes are likely to be more sensitive to both synonymous and nonsynonymous point mutations than inferred previously.

Reassessing the Role of the Type II MqsRA Toxin-Antitoxin System in Stress Response and Biofilm Formation: mqsA Is Transcriptionally Uncoupled from mqsR

Toxin-antitoxin (TA) systems are broadly distributed modules whose biological roles remain mostly unknown. The mqsRA system is a noncanonical TA system in which the toxin and antitoxins genes are organized in operon but with the particularity that the toxin gene precedes that of the antitoxin. This system was shown to regulate global processes such as resistance to bile salts, motility, and biofilm formation. In addition, the MqsA antitoxin was shown to be a master regulator that represses the transcription of the csgD, cspD, and rpoS global regulator genes, thereby displaying a pleiotropic regulatory role. Here, we identified two promoters located in the toxin sequence driving the constitutive expression of mqsA, allowing thereby excess production of the MqsA antitoxin compared to the MqsR toxin. Our results show that both antitoxin-specific and operon promoters are not regulated by stresses such as amino acid starvation, oxidative shock, or bile salts. Moreover, we show that the MqsA antitoxin is not a global regulator as suggested, since the expression of csgD, cspD and rpoS is similar in wild-type and ΔmqsRA mutant strains. Moreover, these two strains behave similarly in terms of biofilm formation and sensitivity to oxidative stress or bile salts.IMPORTANCE There is growing controversy regarding the role of chromosomal toxin-antitoxin systems in bacterial physiology. mqsRA is a peculiar toxin-antitoxin system, as the gene encoding the toxin precedes that of the antitoxin. This system was previously shown to play a role in stress response and biofilm formation. In this work, we identified two promoters specifically driving the constitutive expression of the antitoxin, thereby decoupling the expression of antitoxin from the toxin. We also showed that mqsRA contributes neither to the regulation of biofilm formation nor to the sensitivity to oxidative stress and bile salts. Finally, we were unable to confirm that the MqsA antitoxin is a global regulator. Altogether, our data are ruling out the involvement of the mqsRA system in Escherichia coli regulatory networks.

Molecular mechanism governing ratio-dependent transcription regulation in the ccdAB operon

Bacteria can become transiently tolerant to several classes of antibiotics. This phenomenon known as persistence is regulated by small genetic elements called toxin-antitoxin modules with intricate yet often poorly understood self-regulatory features. Here, we describe the structures of molecular complexes and interactions that drive the transcription regulation of the ccdAB toxin-antitoxin module. Low specificity and affinity of the antitoxin CcdA2 for individual binding sites on the operator are enhanced by the toxin CcdB2, which bridges the CcdA2 dimers. This results in a unique extended repressing complex that spirals around the operator and presents equally spaced DNA binding sites. The multivalency of binding sites induces a digital on-off switch for transcription, regulated by the toxin:antitoxin ratio. The ratio at which this switch occurs is modulated by non-specific interactions with the excess chromosomal DNA. Altogether, we present the molecular mechanisms underlying the ratio-dependent transcriptional regulation of the ccdAB operon.

Homodimeric Escherichia coli Toxin CcdB (Controller of Cell Division or Death B Protein) Folds via Parallel Pathways

The existence of parallel pathways in the folding of proteins seems intuitive, yet remains controversial. We explore the folding kinetics of the homodimeric Escherichia coli toxin CcdB (Controller of Cell Division or Death B protein) using multiple optical probes and approaches. Kinetic studies performed as a function of protein and denaturant concentrations demonstrate that the folding of CcdB is a four-state process. The two intermediates populated during folding are present on parallel pathways. Both form by rapid association of the monomers in a diffusion limited manner and appear to be largely unstructured, as they are silent to the optical probes employed in the current study. The existence of parallel pathways is supported by the insensitivity of the amplitudes of the refolding kinetic phases to the different probes used in the study. More importantly, interrupted refolding studies and ligand binding studies clearly demonstrate that the native state forms in a biexponential manner, implying the presence of at least two pathways. Our studies indicate that the CcdA antitoxin binds only to the folded CcdB dimer and not to any earlier folding intermediates. Thus, despite being part of the same operon, the antitoxin does not appear to modulate the folding pathway of the toxin encoded by the downstream cistron. This study highlights the utility of ligand binding in distinguishing between sequential and parallel pathways in protein folding studies, while also providing insights into molecular interactions during folding in Type II toxin-antitoxin systems.

DNA Topoisomerases

DNA topoisomerases are enzymes that control the topology of DNA in all cells. There are two types, I and II, classified according to whether they make transient single- or double-stranded breaks in DNA. Their reactions generally involve the passage of a single- or double-strand segment of DNA through this transient break, stabilized by DNA-protein covalent bonds. All topoisomerases can relax DNA, but DNA gyrase, present in all bacteria, can also introduce supercoils into DNA. Because of their essentiality in all cells and the fact that their reactions proceed via DNA breaks, topoisomerases have become important drug targets; the bacterial enzymes are key targets for antibacterial agents. This article discusses the structure and mechanism of topoisomerases and their roles in the bacterial cell. Targeting of the bacterial topoisomerases by inhibitors, including antibiotics in clinical use, is also discussed.

Plasmids in the driving seat: The regulatory RNA Rcd gives plasmid ColE1 control over division and growth of its E. coli host

Regulation by non-coding RNAs was found to be widespread among plasmids and other mobile elements of bacteria well before its ubiquity in the eukaryotic world was suspected. As an increasing number of examples was characterised, a common mechanism began to emerge. Non-coding RNAs, such as CopA and Sok from plasmid R1, or RNAI from ColE1, exerted regulation by refolding the secondary structures of their target RNAs or modifying their translation. One regulatory RNA that seemed to swim against the tide was Rcd, encoded within the multimer resolution site of ColE1. Required for high fidelity maintenance of the plasmid in recombination-proficient hosts, Rcd was found to have a protein target, elevating indole production by stimulating tryptophanase. Rcd production is up-regulated in dimer-containing cells and the consequent increase in indole is part of the response to the rapid accumulation of dimers by over-replication (known as the dimer catastrophe). It is proposed that indole simultaneously inhibits cell division and plasmid replication, stopping the catastrophe and allowing time for the resolution of dimers to monomers. The idea of a plasmid-mediated cell division checkpoint, proposed but then discarded in the 1980s, appears to be enjoying a revival.

Plasmid addiction systems: perspectives and applications in biotechnology

Biotechnical production processes often operate with plasmid-based expression systems in well-established prokaryotic and eukaryotic hosts such as Escherichia coli or Saccharomyces cerevisiae, respectively. Genetically engineered organisms produce important chemicals, biopolymers, biofuels and high-value proteins like insulin. In those bioprocesses plasmids in recombinant hosts have an essential impact on productivity. Plasmid-free cells lead to losses in the entire product recovery and decrease the profitability of the whole process. Use of antibiotics in industrial fermentations is not an applicable option to maintain plasmid stability. Especially in pharmaceutical or GMP-based fermentation processes, deployed antibiotics must be inactivated and removed. Several plasmid addiction systems (PAS) were described in the literature. However, not every system has reached a full applicable state. This review compares most known addiction systems and is focusing on biotechnical applications.

Rejuvenation of CcdB-poisoned gyrase by an intrinsically disordered protein domain

Toxin-antitoxin modules are small regulatory circuits that ensure survival of bacterial populations under challenging environmental conditions. The ccd toxin-antitoxin module on the F plasmid codes for the toxin CcdB and its antitoxin CcdA. CcdB poisons gyrase while CcdA actively dissociates CcdB:gyrase complexes in a process called rejuvenation. The CcdA:CcdB ratio modulates autorepression of the ccd operon. The mechanisms behind both rejuvenation and regulation of expression are poorly understood. We show that CcdA binds consecutively to two partially overlapping sites on CcdB, which differ in affinity by six orders of magnitude. The first, picomolar affinity interaction triggers a conformational change in CcdB that initiates the dissociation of CcdB:gyrase complexes by an allosteric segmental binding mechanism. The second, micromolar affinity binding event regulates expression of the ccd operon. Both functions of CcdA, rejuvenation and autoregulation, are mechanistically intertwined and depend crucially on the intrinsically disordered nature of the CcdA C-terminal domain.

DNA topoisomerases: harnessing and constraining energy to govern chromosome topology

DNA topoisomerases are a diverse set of essential enzymes responsible for maintaining chromosomes in an appropriate topological state. Although they vary considerably in structure and mechanism, the partnership between topoisomerases and DNA has engendered commonalities in how these enzymes engage nucleic acid substrates and control DNA strand manipulations. All topoisomerases can harness the free energy stored in supercoiled DNA to drive their reactions; some further use the energy of ATP to alter the topology of DNA away from an enzyme-free equilibrium ground state. In the cell, topoisomerases regulate DNA supercoiling and unlink tangled nucleic acid strands to actively maintain chromosomes in a topological state commensurate with particular replicative and transcriptional needs. To carry out these reactions, topoisomerases rely on dynamic macromolecular contacts that alternate between associated and dissociated states throughout the catalytic cycle. In this review, we describe how structural and biochemical studies have furthered our understanding of DNA topoisomerases, with an emphasis on how these complex molecular machines use interfacial interactions to harness and constrain the energy required to manage DNA topology.

Comparison of a fimbrial versus an autotransporter display system for viral epitopes on an attenuated Salmonella vaccine vector

Attenuated Salmonella have been used as vectors to deliver foreign antigens as live vaccines. We have previously developed an efficient surface-display system by genetically engineering 987P fimbriae to present transmissible gastroenteritis virus (TGEV) C and A epitopes for the induction of anti-TGEV antibodies with a Salmonella vaccine vector. Here, this system was compared with an autotransporter protein surface display system. The TGEV C and A epitopes were fused to the passenger domain of the MisL autotransporter of Salmonella. Expression of both the MisL- and 987P subunit FasA-fusions to the TGEV epitopes were under the control of in vivo-induced promoters. Expression of the TGEV epitopes from the Salmonella typhimurium CS4552 (crp cya asd pgtE) vaccine strain was greater when the epitopes were fused to MisL than when they were fused to the 987P FasA subunit. However, when BALB/c mice were orally immunized with the Salmonella vector expressing the TGEV epitopes from either one of the fusion constructs or both together, the highest level of anti-TGEV antibody was obtained with the 987P-TGEV immunogen-displaying vector. This result suggested that better immune responses towards specific epitopes could be obtained by using a polymeric display system such as fimbriae.

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.

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.

Characterization of the Phd repressor-antitoxin boundary

The P1 plasmid addiction operon (a classic toxin-antitoxin system) encodes Phd, an unstable 73-amino-acid repressor-antitoxin protein, and Doc, a stable toxin. It was previously shown by deletion analysis that the N terminus of Phd was required for repressor activity and that the C terminus was required for antitoxin activity. Since only a quarter of the protein or less was required for both activities, it was hypothesized that Phd might have a modular organization. To further test the modular hypothesis, we constructed and characterized a set of 30 point mutations in the third and fourth quarters of Phd. Four mutations (PhdA36H, V37A, I38A, and F44A) had major defects in repressor activity. Five mutations (PhdD53A, D53R, E55A, F56A, and F60A) had major defects in antitoxin activity. As predicted by the modular hypothesis, point mutations affecting each activity belonged to disjoint, rather than overlapping, sets and were separated rather than interspersed within the linear sequence. A final deletion experiment demonstrated that the C-terminal 24 amino acid residues of Phd (preceded by a methionine) retained full antitoxin activity.

Widespread distribution of a lexA-regulated DNA damage-inducible multiple gene cassette in the Proteobacteria phylum

The SOS response comprises a set of cellular functions aimed at preserving bacterial cell viability in front of DNA injuries. The SOS network, negatively regulated by the LexA protein, is found in many bacterial species that have not suffered major reductions in their gene contents, but presents distinctly divergent LexA-binding sites across the Bacteria domain. In this article, we report the identification and characterization of an imported multiple gene cassette in the Gamma Proteobacterium Pseudomonas putida that encodes a LexA protein, an inhibitor of cell division (SulA), an error-prone polymerase (DinP) and the alpha subunit of DNA polymerase III (DnaE). We also demonstrate that these genes constitute a DNA damage-inducible operon that is regulated by its own encoded LexA protein, and we establish that the latter is a direct derivative of the Gram-positive LexA protein. In addition, in silico analyses reveal that this multiple gene cassette is also present in many Proteobacteria families, and that both its gene content and LexA-binding sequence have evolved over time, ultimately giving rise to the lexA lineage of extant Gamma Proteobacteria.

Comparative analysis of superintegrons: engineering extensive genetic diversity in the Vibrionaceae

Integrons are natural tools for bacterial evolution and innovation. Their involvement in the capture and dissemination of antibiotic-resistance genes among Gram-negative bacteria is well documented. Recently, massive ancestral versions, the superintegrons (SIs), were discovered in the genomes of diverse proteobacterial species. SI gene cassettes with an identifiable activity encode proteins related to simple adaptive functions, including resistance, virulence, and metabolic activities, and their recruitment was interpreted as providing the host with an adaptive advantage. Here, we present extensive comparative analysis of SIs identified among the Vibrionaceae. Each was at least 100 kb in size, reaffirming the participation of SIs in the genome plasticity and heterogeneity of these species. Phylogenetic and localization data supported the sedentary nature of the functional integron platform and its coevolution with the host genome. Conversely, comparative analysis of the SI cassettes was indicative of both a wide range of origin for the entrapped genes and of an active cassette assembly process in these bacterial species. The signature attC sites of each species displayed conserved structural characteristics indicating that symmetry rather than sequence was important in the recognition of such a varied collection of target recombination sequences by a single site-specific recombinase. Our discovery of various addiction module cassettes within each of the different SIs indicates a possible role for them in the overall stability of large integron cassette arrays.

Molecular interactions of the CcdB poison with its bacterial target, the DNA gyrase

The ccd poison/antidote system of the F plasmid encodes CcdB, a toxin targeting the essential DNA gyrase of E. coli, and CcdA, the unstable antidote that interacts with CcdB to neutralise its toxicity. Gyrase belongs to the topoisomerase II class of enzymes and is a well-validated target for efficient therapeutic drugs, i. e. the quinolones. CcdB acts on gyrase in a similar way as quinolones do, both compounds induce double-strand breaks in DNA. Interestingly, the CcdB-binding domain of gyrase is different than that of quinolones. Therefore, novel classes of therapeutic drugs could be derived from the analysis of the interaction between CcdB and gyrase.

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.

Specific protein-DNA and protein-protein interaction in the hig gene system, a plasmid-borne proteic killer gene system of plasmid Rts1

The hig (host inhibition of growth) gene system of plasmid Rts1 belongs to the plasmid-encoded proteic killer gene family. Among the proteic killer genes described so far, hig is unique in that the toxin gene (higB) exists upstream of the antidote gene (higA). There are two promoters in the hig locus, Phig and PhigA, and only the former, which expresses both higB and higA genes, is negatively controlled by HigA and HigB proteins. In this study, we purified HigA protein by means of GST fusion. The electrophoretic mobility shift assay using the purified protein revealed that HigA specifically bound to the Phig region, but not to PhigA. The HigA-binding sequence was determined by DNase I footprinting assay to be a 56-bp sequence that completely covered the -35 and -10 boxes of Phig. The presence of two inverted repeats in the binding sequence and the identification of a dimer form of HigA by cross-linking experiment suggested that the protein bound to the Phig region as a dimer. HigB was purified as a GST fusion protein as well, though it was achieved only in the presence of HigA. HigA and GST-HigB formed a highly stable complex where the two proteins were present in an equimolar ratio.

Addiction modules and programmed cell death and antideath in bacterial cultures

In bacteria, programmed cell death is mediated through "addiction modules" consisting of two genes. The product of the second gene is a stable toxin, whereas the product of the first is a labile antitoxin. Here we extensively review what is known about those modules that are borne by one of a number of Escherichia coli extrachromosomal elements and are responsible for the postsegregational killing effect. We focus on a recently discovered chromosomally borne regulatable addiction module in E. coli that responds to nutritional stress and also on an antideath gene of the E. coli bacteriophage lambda. We consider the relation of these two to programmed cell death and antideath in bacterial cultures. Finally, we discuss the similarities between basic features of programmed cell death and antideath in both prokaryotes and eukaryotes and the possibility that they share a common evolutionary origin.

The interaction of DNA gyrase with the bacterial toxin CcdB: evidence for the existence of two gyrase-CcdB complexes

CcdB is a bacterial toxin that targets DNA gyrase. Analysis of the interaction of CcdB with gyrase reveals two distinct complexes. An initial complex (alpha) is formed by direct interaction between GyrA and CcdB; this complex can be detected by affinity column and gel-shift analysis, and has a proteolytic signature which is characterised by a 49 kDa fragment of GyrA. Surface plasmon resonance shows that CcdB binds to the N-terminal domain of GyrA with high affinity. In this mode of binding, CcdB does not affect the ability of gyrase to hydrolyse ATP or promote supercoiling. Incubation of this initial complex with ATP in the presence of GyrB and DNA slowly converts it to a second complex (beta), which has a lower rate of ATP hydrolysis and is unable to catalyse supercoiling. The efficiency of formation of this inactive complex is dependent on the concentrations of ATP and CcdB. We suggest that the conversion between the two complexes proceeds via an intermediate, whose formation is dependent on the rate of ATP hydrolysis.

Interactions of CcdB with DNA gyrase. Inactivation of Gyra, poisoning of the gyrase-DNA complex, and the antidote action of CcdA

The F plasmid-carried bacterial toxin, the CcdB protein, is known to act on DNA gyrase in two different ways. CcdB poisons the gyrase-DNA complex, blocking the passage of polymerases and leading to double-strand breakage of the DNA. Alternatively, in cells that overexpress CcdB, the A subunit of DNA gyrase (GyrA) has been found as an inactive complex with CcdB. We have reconstituted the inactive GyrA-CcdB complex by denaturation and renaturation of the purified GyrA dimer in the presence of CcdB. This inactivating interaction involves the N-terminal domain of GyrA, because similar inactive complexes were formed by denaturing and renaturing N-terminal fragments of the GyrA protein in the presence of CcdB. Single amino acid mutations, both in GyrA and in CcdB, that prevent CcdB-induced DNA cleavage also prevent formation of the inactive complexes, indicating that some essential interaction sites of GyrA and of CcdB are common to both the poisoning and the inactivation processes. Whereas the lethal effect of CcdB is most probably due to poisoning of the gyrase-DNA complex, the inactivation pathway may prevent cell death through formation of a toxin-antitoxin-like complex between CcdB and newly translated GyrA subunits. Both poisoning and inactivation can be prevented and reversed in the presence of the F plasmid-encoded antidote, the CcdA protein. The products of treating the inactive GyrA-CcdB complex with CcdA are free GyrA and a CcdB-CcdA complex of approximately 44 kDa, which may correspond to a (CcdB)2(CcdA)2 heterotetramer.

Toxin-antitoxin systems homologous with relBE of Escherichia coli plasmid P307 are ubiquitous in prokaryotes

Toxin-antitoxin systems encoded by bacterial plasmids and chromosomes specify two proteins, a cytotoxin and an antitoxin. The antitoxins neutralize the cognate toxins by forming tight complexes with them. The antitoxins are unstable due to degradation by cellular proteases (Lon or Clp), whereas the toxins are stable. Here we show that orf7 (denoted relBP307) and orf6 (denoted relEP307) of Escherichia coli plasmid P307 are homologous to the relBE genes of E. coli and constitute a two-component toxin-antitoxin system: (i) relEP307 encodes a cytotoxin lethal or inhibitory to host cells; (ii) relBP307 encodes an antitoxin that prevents the lethal action of the relE-encoded toxin; (iii) RelBP307 antitoxin is degraded by Lon protease; (iv) RelBP307 antitoxin autoregulates the relBE operon of P307 at the level of transcription; (v) RelEP307 toxin acts as a co-repressor of transcription; and (vi) the relBE system stabilizes a mini-P307 replicon by the killing of plasmid-free cells. Using database searching, we found relBE homologues on the chromosomes of many Gram-negative and Gram-positive bacteria. Even more surprising, numerous relBE-homologous gene systems are present on the chromosomes of Archae. Thus, toxin-antitoxin systems homologous with relBE of E. coli are ubiquitous in prokaryotic organisms.

Bacterial death by DNA gyrase poisoning

DNA gyrase is an essential topoisomerase that is found in all bacteria and is the target of potent antibiotics, such as the quinolones. By creating DNA lesions and inducing the bacterial SOS response, these drugs are not only highly cytotoxic but also mutagenic. Discovery and analysis of natural molecules with anti-gyrase activities, such as the CcdB or microcin B17 proteins, hold promise for understanding further topoisomerase reactions and for the design of new antibiotics.

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.

Identification of DNA gyrase inhibitor (GyrI) in Escherichia coli

DNA gyrase is an essential enzyme in DNA replication in Escherichia coli. It mediates the introduction of negative supercoils near oriC, removal of positive supercoils ahead of the growing DNA fork, and separation of the two daughter duplexes. In the course of purifying DNA gyrase from E. coli KL16, we found an 18-kDa protein that inhibited the supercoiling activity of DNA gyrase, and we coined it DNA gyrase inhibitory protein (GyrI). Its NH2-terminal amino acid sequence of 16 residues was determined to be identical to that of a putative gene product (a polypeptide of 157 amino acids) encoded by yeeB (EMBL accession no. U00009) and sbmC (Baquero, M. R., Bouzon, M., Varea, J., and Moreno, F. (1995) Mol. Microbiol. 18, 301-311) of E. coli. Assuming the identity of the gene (gyrI) encoding GyrI with the previously reported genes yeeB and sbmC, we cloned the gene after amplification by polymerase chain reaction and purified the 18-kDa protein from an E. coli strain overexpressing it. The purified 18-kDa protein was confirmed to inhibit the supercoiling activity of DNA gyrase in vitro. In vivo, both overexpression and antisense expression of the gyrI gene induced filamentous growth of cells and suppressed cell proliferation. GyrI protein is the first identified chromosomally nucleoid-encoded regulatory factor of DNA gyrase in E. coli.

The interaction of the F plasmid killer protein, CcdB, with DNA gyrase: induction of DNA cleavage and blocking of transcription

We have studied the interaction of the F plasmid killer protein CcdB with its intracellular target DNA gyrase. We confirm that CcdB can induce DNA cleavage by gyrase and show that this cleavage reaction requires ATP hydrolysis when the substrate is linear DNA, but is independent of hydrolysis when negatively supercoiled DNA is used. The 64 kDa domain of the gyrase A protein, which can catalyse DNA cleavage in the presence of the B protein and quinolone drugs, is unable to cleave DNA in the presence of CcdB unless the C-terminal 33 kDa domain of the gyrase A protein is also present. CcdB-induced DNA cleavage by gyrase requires a minimum length of DNA (> approximately 160 bp), whereas in the presence of quinolone drugs gyrase can cleave much shorter DNA molecules. We show that CcdB, like quinolones, can form a complex with gyrase which can block transcription by RNA polymerase. A model for the interaction of CcdB with gyrase involving the trapping of a post-strand-passage intermediate is suggested. We conclude that CcdB can stabilise a cleavage complex between DNA gyrase and DNA in a manner distinct from quinolones but, like the quinolone-induced cleavage complex, the CcdB-stabilised complex can also form a barrier to the passage of polymerases.

DNA gyrase, topoisomerase IV, and the 4-quinolones

For many years, DNA gyrase was thought to be responsible both for unlinking replicated daughter chromosomes and for controlling negative superhelical tension in bacterial DNA. However, in 1990 a homolog of gyrase, topoisomerase IV, that had a potent decatenating activity was discovered. It is now clear that topoisomerase IV, rather than gyrase, is responsible for decatenation of interlinked chromosomes. Moreover, topoisomerase IV is a target of the 4-quinolones, antibacterial agents that had previously been thought to target only gyrase. The key event in quinolone action is reversible trapping of gyrase-DNA and topoisomerase IV-DNA complexes. Complex formation with gyrase is followed by a rapid, reversible inhibition of DNA synthesis, cessation of growth, and induction of the SOS response. At higher drug concentrations, cell death occurs as double-strand DNA breaks are released from trapped gyrase and/or topoisomerase IV complexes. Repair of quinolone-induced DNA damage occurs largely via recombination pathways. In many gram-negative bacteria, resistance to moderate levels of quinolone arises from mutation of the gyrase A protein and resistance to high levels of quinolone arises from mutation of a second gyrase and/or topoisomerase IV site. For some gram-positive bacteria, the situation is reversed: primary resistance occurs through changes in topoisomerase IV while gyrase changes give additional resistance. Gyrase is also trapped on DNA by lethal gene products of certain large, low-copy-number plasmids. Thus, quinolone-topoisomerase biology is providing a model for understanding aspects of host-parasite interactions and providing ways to investigate manipulation of the bacterial chromosome by topoisomerases.

Plasmid maintenance functions of the large virulence plasmid of Shigella flexneri

The large virulence plasmid pMYSH6000 of Shigella flexneri contains a replicon and a plasmid maintenance stability determinant (Stb) on adjacent SalI fragments. The presence of a RepFIIA replicon on the SalI C fragment was confirmed, and the complete sequence of the adjacent SalI O fragment was determined. It shows homology to part of the transfer (tra) operon of the F plasmid. Stb stabilizes a partition-defective P1 miniplasmid in Escherichia coli. A 1.1-kb region containing a homolog of the F trbH gene was sufficient to confer stability. However, the trbH open reading frame could be interrupted without impairing stability. Deletion analysis implicated the involvement of two small open reading frames, STBORF1 and STBORF2, that fully overlap trbH in the opposite direction. These open reading frames are closely related to the vagC and vagD genes of the Salmonella dublin virulence plasmid and to open reading frame pairs in the F trbH region and in the chromosomes of Dichelobacter nodosus and Haemophilus influenzae. Stb appears to promote better-than-random distribution of plasmid copies and is a plasmid incompatibility determinant. The F homolog does not itself confer stability but exerts incompatibility against the activity of the Stb system. Stb is likely to encode either an active partition system or a postsegregational killing system. It shows little similarity to previously studied plasmid stability loci, but the genetic organization of STBORF1 and STBORF2 resembles that of postsegregational killing mechanisms.

ATP-dependent degradation of CcdA by Lon protease. Effects of secondary structure and heterologous subunit interactions

CcdA, the antidote protein of the ccd post-segregational killing system carried by the F plasmid, was degraded in vitro by purified Lon protease from Escherichia coli. CcdA had a low affinity for Lon (Km >/=200 microM), and the peptide bond turnover number was approximately 10 min-1. CcdA formed tight complexes with purified CcdB, the killer protein encoded in the ccd operon, and fluorescence and hydrodynamic measurements suggested that interaction with CcdB converted CcdA to a more compact conformation. CcdB prevented CcdA degradation by Lon and blocked the ability of CcdA to activate the ATPase activity of Lon, suggesting that Lon may recognize bonding domains of proteins exposed when their partners are absent. Degradation of CcdA required ATP hydrolysis; however, CcdA41, consisting of the carboxyl-terminal 41 amino acids of CcdA and lacking the alpha-helical secondary structure present in CcdA, was degraded without ATP hydrolysis. Lon cleaved CcdA primarily between aliphatic and hydrophilic residues, and CcdA41 was cleaved at the same peptide bonds, indicating that ATP hydrolysis does not affect cleavage specificity. CcdA lost alpha-helical structure at elevated temperatures (Tm approximately 50 degrees C), and its degradation became independent of ATP hydrolysis at this temperature. ATP hydrolysis may be needed to disrupt interactions that stabilize the secondary structure of proteins allowing the disordered protein greater access to the proteolytic active sites.

Characterization of the stable maintenance properties of the par region of broad-host-range plasmid RK2

A 3.2-kb fragment encoding five genes, parCBA/DE, in two divergently transcribed operons promotes stable maintenance of the replicon of the broad-host-range plasmid RK2 in a vector-independent manner in Escherichia coli. The parDE operon has been shown to contribute to stabilization through the postsegregational killing of plasmid-free daughter cells, while the parCBA operon encodes a resolvase, ParA, that mediates the resolution of plasmid multimers through site-specific recombination. To date, evidence indicates that multimer resolution alone does not play a significant role in RK2 stable maintenance by the parCBA operon in E. coli. It has been proposed, instead, that the parCBA region encodes an additional stability mechanism, a partition system, that ensures that each daughter cell receives a plasmid copy at cell division. However, studies carried out to date have not directly determined the plasmid stabilization activity of the parCBA operon alone. An assessment was made of the relative contributions of postsegregational killing (parDE) and the putative partitioning system (parCBA) to the stabilization of mini-RK2 replicons in E. coli. Mini-RK2 replicons carrying either the entire 3.2-kb (parCBA/DE) fragment or the 2.3-kb parCBA region alone were found to be stably maintained in two E. coli strains tested. The stabilization found is not due to resolution of multimers. The stabilizing effectiveness of parCBA was substantially reduced when the plasmid copy number was lowered, as in the case of E. coli cells carrying a temperature-sensitive mini-RK2 replicon grown at a nonpermissive temperature. The presence of the entire 3.2-kb region effectively stabilized the replicon, however, under both low- and high-copy-number-conditions. In those instances of decreased plasmid copy number, the postsegregational killing activity, encoded by parDE, either as part of the 3.2-kb fragment or alone played the major role in the stabilization of mini-RK2 replicons within the growing bacterial population. Our findings indicate that the parCBA operon functions to stabilize by a mechanism other than cell killing and resolution of plasmid multimers, while the parDE operon functions solely to stabilize plasmids by cell killing. The relative contribution of each system to stabilization depends on plasmid copy number and the particular E. coli host.

Co-induction of DNA relaxation and synthesis of DnaK and GroEL proteins in Escherichia coli by expression of LetD (CcdB) protein, an inhibitor of DNA gyrase encoded by the F factor

We examined the influence of overexpression of LetD (CcdB) protein, an inhibitor of DNA gyrase encoded by the F factor of Escherichia coli, on DNA supercoiling and induction of heat shock proteins. Cells were transformed with a plasmid carrying the structural gene for LetD protein under control of the tac promoter, and LetD protein was induced by adding isopropyl beta-D-thiogalactopyranoside (IPTG) to the culture medium. Analysis by agarose gel electrophoresis in the presence of chloroquine revealed relaxation of plasmid DNA in cells depending on the concentration of IPTG employed for induction. Protein pulse-labeling experiments with [35S]methionine and cysteine revealed that synthesis of DnaK and GroEL proteins was also induced by IPTG, and concentrations necessary for DNA relaxation and induction of the heat shock proteins were much the same. Expression of mutant LetD protein lacking two amino acid residues at the C-terminus induced neither DNA relaxation nor the synthesis of DnaK and GroEL proteins. Induction of wild-type LetD protein but not mutant LetD protein markedly enhanced synthesis of sigma32. We interpret these results to mean that DNA relaxation in cells caused by the expression of LetD protein induces heat shock proteins via increased synthesis of sigma32.

F plasmid CcdB killer protein: ccdB gene mutants coding for non-cytotoxic proteins which retain their regulatory functions

The ccd locus of the F plasmid codes for two gene products, CcdA and CcdB, which contribute to the plasmid's high stability by post-segregational killing of plasmid-free bacteria. Like the quinolones, the CcdB protein is a poison of the DNA-topoisomerase II complexes, while CcdA acts as an antidote against CcdB. In addition to these poison-antipoison properties, the CcdA and CcdB proteins act together at transcription level to repress their own synthesis. In this work, we have isolated, in vivo, and characterized several non-killer CcdB mutants. All missense mutations which inactivate CcdB killer activity are located in the region coding for the last three C-terminal residues. However, the resulting mutant CcdB proteins retain their autoregulatory properties. We conclude that the last three C-terminal residues of CcdB play a key role in poisoning but are not involved in repressor formation.

Positive-selection vectors using the F plasmid ccdB killer gene

Plasmids pKIL18/19 are positive-selection cloning vectors containing an active cytotoxic ccdB gene under the control of the lacP promoter. They are derivatives of high-copy-number pUC18/19 plasmids in which the ccdB killer gene has been fused in phase downstream from the lacP MCS18 and MCS19 multiple cloning sites. When an Escherichia coli wild-type gyrA+ strain is transformed by such vectors, the ccdB gene product blocks bacterial growth. However, if ccdB is inactivated by insertion of a foreign DNA fragment, this recombinant plasmid no longer interferes with host viability. The positive selection of recombinant clones is highly efficient and bench manipulations are simplified to the utmost: E. coli transformants are plated on rich medium and only cells containing recombinant plasmids give rise to colonies. The CcdB protein is a potent poison of gyrase and the gyrA462 mutation confers total resistance to CcdB [Bernard and Couturier, J. Mol. Biol. 226 (1992) 735-745]. Therefore, pKIL18/19 vectors can be amplified and prepared in large quantities in a gyrA462 host. Like pUC vectors, pKIL vectors are designed for general cloning/sequencing procedures.

The antidote and autoregulatory functions of the F plasmid CcdA protein: a genetic and biochemical survey

The ccd operon of the F plasmid contributes to the high stability of the episome by postsegregational killing of plasmid-free bacteria. It contains two genes, ccdA and ccdB, which are negatively autoregulated at the level of transcription, probably by a complex comprising the two gene products. Using the bacterial gyrA462 CcdB resistance mutation and a Pccd-lacZ transcriptional fusion, we have obtained evidence that the CcdB protein by itself has no regulatory activity or operator DNA-binding affinity and needs CcdA in order to effect transcriptional control. The ccd killing mechanism is based on the poison-antidote principle. The CcdB protein is cytotoxic, poisoning DNA-gyrase complexes, while CcdA antagonizes this activity. In order to define functional domains of the CcdA antidote involved in the anti-killer effect, autoregulation or both, we introduced several missense or amber mutations into the CcdA protein by directed mutagenesis. We report on missense CcdA proteins that have lost their autoregulatory properties but are still able to antagonize the lethal activity of CcdB. We show that the five carboxy-terminal amino acid residues of the antidote protein are not required for the antidote effect or for autoregulation. Several missense CcdA polypeptides were generated by suppression of nonsense codons. Two substitutions lead to CcdB-promoted killing: glutamine 33-->cysteine and glutamine 33-->phenylalanine.

Lon-dependent proteolysis of CcdA is the key control for activation of CcdB in plasmid-free segregant bacteria

The ccd locus contributes to the stability of plasmid F by post-segregational killing of plasmid-free bacteria. The ccdB gene product is a potent cell-killing protein and its activity is negatively regulated by the CcdA protein. In this paper, we show that the CcdA protein is unstable and that the degradation of CcdA is dependent on the Lon protease. Differences in the stability of the killer CcdB protein and its antidote CcdA are the key to post-segregational killing. Because the half-life of active CcdA protein is shorter than that of active CcdB protein, persistence of the CcdB protein leads to the death of plasmid-free bacterial segregants.

Regulation by proteolysis: energy-dependent proteases and their targets

A number of critical regulatory proteins in both prokaryotic and eukaryotic cells are subject to rapid, energy-dependent proteolysis. Rapid degradation combined with control over biosynthesis provides a mechanism by which the availability of a protein can be limited both temporally and spatially. Highly unstable regulatory proteins are involved in numerous biological functions, particularly at the commitment steps in developmental pathways and in emergency responses. The proteases involved in energy-dependent proteolysis are large proteins with the ability to use ATP to scan for appropriate targets and degrade complete proteins in a processive manner. These cytoplasmic proteases are also able to degrade many abnormal proteins in the cell.

Cell killing by the F plasmid CcdB protein involves poisoning of DNA-topoisomerase II complexes

In Escherichia coli, the miniF plasmid CcdB protein is responsible for cell death when its action is not prevented by polypeptide CcdA. We report the isolation, localization, sequencing and properties of a bacterial mutant resistant to the cytotoxic activity of the CcdB protein. This mutation is located in the gene encoding the A subunit of topoisomerase II and produces an Arg462----Cys substitution in the amino acid sequence of the GyrA polypeptide. Hence, the mutation was called gyrA462. We show that in the wild-type strain, the CcdB protein promotes plasmid linearization; in the gyrA462 strain, this double-stranded DNA cleavage is suppressed. This indicates that the CcdB protein is responsible for gyrase-mediated double-stranded DNA breakage. CcdB, in the absence of CcdA, induces the SOS pathway. SOS induction is a biological response to DNA-damaging agents. We show that the gyrA462 mutation suppresses this SOS activation, indicating that SOS induction is a consequence of DNA damages promoted by the CcdB protein on gyrase-DNA complexes. In addition, we observe that the CcdBS sensitive phenotype dominates over the resistant phenotype. This is better explained by the conversion, in gyrA+/gyrA462 merodiploid strains, of the wild-type gyrase into a DNA-damaging agent. These results strongly suggest that the CcdB protein, like quinolone antibiotics and a variety of antitumoral drugs, is a DNA topoisomerase II poison. This is the first proteinic poison-antipoison mechanism that has been found to act via the DNA topoisomerase II.

The stable maintenance system pem of plasmid R100: degradation of PemI protein may allow PemK protein to inhibit cell growth

We constructed plasmids carrying heat-inducible pemI and pemK genes, which were fused with the collagen-lacZ sequence in frame. The PemK-collagen-LacZ (PemK*) protein produced from the fusion gene upon heat induction inhibited the growth of cells and killed most of the cells in the absence of the PemI protein but did not do so in the presence of the PemI protein. This supports our previous assumption that the PemK protein inhibits cell division, leading to cell death, whereas the PemI protein suppresses the function of the PemK protein. We also constructed the plasmid carrying the heat-inducible pem operon which consists of the intact pemI gene and the pemK gene fused with collagen-lacZ. The simultaneously induced PemI and PemK* proteins did not inhibit the growth of cells. However, the temperature shift to 30 degrees C after induction of both proteins at 42 degrees C caused inhibition of cell growth and death of most cells. This suggests that the PemI protein is somehow inactivated upon the arrest of de novo synthesis of the PemI and PemK* proteins, allowing the PemK* protein to function. We observed that the PemI-collagen-LacZ (PemI*) protein was degraded faster than the PemK* protein, perhaps by the action of a protease(s). In fact, the lon mutation, which caused no apparent degradation of the PemI* protein, did not allow the PemK* protein to function, supporting the suggestion described above. Instability of the PemI protein would explain why the cells which have lost the pem+ plasmid are preferentially killed.

A Salmonella dublin virulence plasmid locus that affects bacterial growth under nutrient-limited conditions

This paper reports the characterization of a new locus, vagC/vagD, on the virulence plasmid of Salmonella dublin. Strain G19, harbouring a TnA insertion in vagC, exhibited reduced virulence although vagC was outside the 8 kb essential virulence region. G19 was also unable to grow on minimal-medium containing various sole carbon/energy sources, unlike the wild-type and plasmid-cured strains. Sequencing of the locus revealed the presence of two ORFs (vagC and vagD) which overlapped by one nucleotide. The VagC polypeptide (12 kDa) was observed using minicell expression. Results indicated that vagD was responsible for the phenotypic differences observed between the wild type and G19, and that vagC modulated the activity of vagD. Furthermore, microscopic analysis of G19 cells harvested from minimal-medium plates showed that a high proportion of cells were elongated, which suggested that vagC and vagD might be involved in coordination of plasmid replication with cell division. We propose that vagD, under certain environmental conditions, acts to prevent cell division until plasmid replication is complete, thus aiding plasmid maintenance. vagC and vagD are absent from the related virulence plasmid of Salmonella typhimurium.

Control of segregation of chromosomal DNA by sex factor F in Escherichia coli. Mutants of DNA gyrase subunit A suppress letD (ccdB) product growth inhibition

The letA (ccdA) and letD (ccdB) genes, located just outside the sequence essential for replication of the F plasmid, apparently contribute to stable maintenance of the plasmid. The letD gene product acts to inhibit partitioning of chromosomal DNA and cell division of the host bacteria, whereas the letA gene product acts to suppress the activity of the letD gene product. To identify the target of the letD gene product, temperature-sensitive growth-defective mutants were screened from bacterial mutants that had escaped the letD product growth inhibition that occurs in hosts carrying an FletA mutant. Of nine mutants analysed, three mutants were shown, by phage P1-mediated transduction and complementation analysis, to have mutations in the gyrA gene and the other six in the groE genes. The nucleotide sequence revealed that one of the gyrA mutants has a base change from G to A at position 641 (resulting in an amino acid change from Gly to Glu at position 214) of the gyrA gene. The mutant GyrA proteins produced by these gyrA(ts) mutants were trans-dominant over wild-type GyrA protein for letD tolerance. The wild-type GyrA protein, produced in excess amounts by means of a multicopy plasmid, overcame growth inhibition of the letD gene product. These observations strongly suggest that the A subunit of DNA gyrase is the target of the LetD protein.

Isolation and characterization of kikA, a region on IncN group plasmids that determines killing of Klebsiella oxytoca

Transfer of the IncN group plasmid pCU1 from Escherichia coli to Klebsiella oxytoca by conjugation kills a large proportion (90 to 95%) of the recipients of plasmid DNA, whereas transfer to E. coli or even to the closely related Enterobacter aerogenes does not. Two regions, kikA and kikB, have been identified on pCU1 that contribute to the Kik (killing in klebsiellas) phenotype. We have localized the kikA region to 500 bp by deletion analysis and show by DNA-DNA hybridization that kikA is highly conserved among the plasmids of incompatibility group N. The expression in K. oxytoca of kikA under the control of the strong inducible E. coli tac promoter results in loss of cell viability. The nucleotide sequence showed two overlapping open reading frames (ORFs) within the kikA region. The first ORF codes for a putative polypeptide of 104 amino acids (ORF104). The second ORF codes for a 70-amino-acid polypeptide (ORF70). The properties of the putative protein encoded by ORF104 and gene fusions of kikA to alkaline phosphatase by using TnphoA suggest that killing may involve an association with the bacterial membrane; however, we could not rule out the possibility that ORF70 plays a role in the Kik phenotype.

The kilA operon of promiscuous plasmid RK2: the use of a transducing phage (lambda pklaA-1) to determine the effects of the lethal klaA gene on Escherichia coli cells

The kil-kor regulon of promiscuous plasmid RK2 includes the replication initiator gene trfA and several potentially host-lethal kil loci (kilA, kilB, kilC, kilE), whose functions may be involved in plasmid maintenance or broad host range. The kilA locus consists of a single operon of three genes (klaA, klaB, klaC), each of which is lethal when expressed from the klaA promoter in the absence of repressors encoded by korA and korB. In this study, we examined the effects of the unregulated klaA gene on the host cell. Bacteriophage lambda was used to construct a transducing phage (lambda pklaA-1) that allows efficient introduction of the klaA gene into Escherichia coli. Cells lacking korA and korB (to allow uncontrolled expression of klaA) and expressing lambda repressor (to prevent phage lytic growth) are killed by lambda pklaA-1. Cell death is dependent on the klaA structural gene, independent of the SOS system of the host, and is prevented by the presence of korA and korB. lambda pklaA-1 was used to synchronously infect cells lacking korA and korB to determine the effects of klaA on the cells over time. The earliest effects, visible at two hours post-infection, are inhibition of growth of the culture, formation of elongated cells, and striking changes in the appearance of the outer membrane. After four to five hours, the viability of the culture declined sharply and macromolecular synthesis ceased. The distinct class of early events is consistent with the hypothesis that the KlaA polypeptide interacts with a specific target in the host cell.

Structural, molecular, and genetic analysis of the kilA operon of broad-host-range plasmid RK2

The kil loci (kilA, kilB, kilC, and kilE) of incompatibility group P (IncP), broad-host-range plasmid RK2 were originally detected by their potential lethality to Escherichia coli host cells. Expression of the kil determinants is controlled by different combinations of kor functions (korA, korB, korC, and korE). This system of regulated genes, known as the kil-kor regulon, includes trfA, which encodes the RK2 replication initiator. The functions of the kil loci are unknown, but their coregulation with an essential replication function suggests that they have a role in the maintenance or host range of RK2. In this study, we have determined the nucleotide sequence of a 3-kb segment of RK2 that encodes the entire kilA locus. The region encodes three genes, designated klaA, klaB, and klaC. The phage T7 RNA polymerase-dependent expression system was use to identify three polypeptide products. The estimated masses of klaA and klaB products were in reasonable agreement with the calculated molecular masses of 28,407 and 42,156 Da, respectively. The klaC product is calculated to be 32,380 Da, but the observed polypeptide exhibited an apparent mass of 28 kDa on sodium dodecyl sulfate-polyacrylamide gels. Mutants of klaC were used to confirm that initiation of translation of the observed product occurs at the first ATG in the klaC open reading frame. Hydrophobicity analysis indicated that the KlaA and KlaB polypeptides are likely to be soluble, whereas the KlaC polypeptide was predicted to have four potential membrane-spanning domains. The only recognizable promoter sequences in the kilA region were those of the kilA promoter located upstream of klaA and the promoter for the korA-korB operon located just downstream of a rho-independent terminatorlike sequence following klaC. The transcriptional start sites for these promoters were determined by primer extension. Using isogenic sets of plasmids with nonpolar mutations, we found that klaA, klaB, and klaC are each able to express a host-lethal (Kil+) phenotype in the absence of kor functions. Inactivation of the kilA promoter causes loss of the lethal phenotype, demonstrating that all three genes are expressed from the kilA promoter as a multicistronic operon. We investigated two other phenotypes that have been mapped to the kilA region of RK2 or the closely related IncP plasmids RP1 and RP4: inhibition of conjugal transfer of IncW plasmids (fwB) and resistance to potassium tellurite. The cloned kilA operon was found to express both phenotypes, even in the presence of korA and korB, whose functions are known to regulate the kilA promoter. In addition, mutant and complementation analyses showed that the kilA promoter and the products of all three kla genes are necessary for expression of both phenotypes. Therefore, host lethality, fertility inhibition, and tellurite resistance are all properties of the kilA operon. We discuss the possible role of the kilA operon for RK2.

The 41 carboxy-terminal residues of the miniF plasmid CcdA protein are sufficient to antagonize the killer activity of the CcdB protein

The ccd operon of plasmid F encodes two genes, ccdA and ccdB, which contribute to the high stability of the plasmid by post-segregational killing of plasmid-free bacteria. The CcdB protein is lethal to bacteria and the CcdA protein is an antagonist of this lethal action. A 520 bp fragment containing the terminal part of the ccdA gene and the entire ccdB gene of plasmid F was cloned downstream of the tac promoter. Although the CcdB protein was expressed from this fragment, no killing of host bacteria was observed. We found that the absence of killing was due to the presence of a small polypeptide, CcdA41, composed of the 41 C-terminal residues of the CcdA protein. This polypeptide has retained the ability to regulate negatively the lethal activity of the CcdB protein.

Introduction of a UV-damaged replicon into a recipient cell is not a sufficient condition to produce an SOS-inducing signal

Three models have been proposed for the nature of the SOS-inducing signal in E. coli. One model postulates that degradation products of damaged DNA generate an SOS-inducing signal; another model surmises that the very lesions produced by UV damage constitute the SOS-inducing signal in vivo; a third model proposes that DNA damage is processed upon DNA replication to form single-stranded DNA (the SOS signal) that activates RecA protein. We tested the models by measuring SOS induction produced by introducing into recipient cells the UV-damaged DNA of 2 constructed phagemids. We used phagemids since they transferred DNA to the recipients with 100% efficiency. The origin of replication of the phagemids was either oriC from the E. coli chromosome, or oriF from F plasmid. Replication of the oriC phagemid was dependent on methylation. A UV-damaged oriC phagemid failed to induce SOS functions in a recipient cell whereas an oriF phagemid did induce them. Our results disprove the first and the second model proposed for the nature of the SOS-inducing signal. The failure of a UV-damaged oriC replicon to induce SOS can be explained by the third model if one assumes that replication of a UV-damaged oriC plasmid does not generate single-stranded DNA as does the E. coli chromosome after UV damage.