ParE toxin encoded by the broad-host-range plasmid RK2 is an inhibitor of Escherichia coli gyrase

Broad-host-range plasmid RK2 encodes a post-segregational killing system, parDE, which contributes to the stable maintenance of this plasmid in Escherichia coli and many distantly related bacteria. The ParE protein is a toxin that inhibits cell growth, causes cell filamentation and eventually cell death. The ParD protein is a specific ParE antitoxin. In this work, the in vitro activities of these two proteins were examined. The ParE protein was found to inhibit DNA synthesis using an E. coli oriC supercoiled template and a replication-proficient E. coli extract. Moreover, ParE inhibited the early stages of both chromosomal and plasmid DNA replication, as measured by the DnaB helicase- and gyrase-dependent formation of FI*, a highly unwound form of supercoiled DNA. The presence of ParD prevented these inhibitory activities of ParE. We also observed that the addition of ParE to supercoiled DNA plus gyrase alone resulted in the formation of a cleavable gyrase-DNA complex that was converted to a linear DNA form upon addition of sodium dodecyl sulphate (SDS). Adding ParD before or after the addition of ParE prevented the formation of this cleavable complex. These results demonstrate that the target of ParE toxin activity in vitro is E. coli gyrase.     

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

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

Crystal Structure of the Antitoxin-Toxin Protein Complex RelB-RelE from Methanococcus jannaschii

Here we present the crystal structure of the Methanococcus jannaschii RelE-RelB (RelBE) toxin-antitoxin (TA) protein complex determined by the MIRAS (multiple isomorphous replacement with anomalous signal) method. The genes encoding this TA system are located in the chromosome of this archaeon and involved in stress response. RelE acts as an endoribonuclease that cleaves mRNA on the ribosome, and we compare the RelBE complex to the known structures of other TA systems belonging to this group and to endoribonucleases. M. jannaschii RelBE forms a heterotetramer with the antitoxin in the centre of the complex, a configuration that differs vastly from the heterotetramer structure of the previously published RelBE from another archaeon, Pyrococcus horikoshii. The long N-terminal α-helix of the tightly bound M. jannaschii antitoxin RelB covers the presumed active site of the toxin RelE that is formed by a central β-sheet, a loop on one side and a C-terminal α-helix on the other side. The active site of the M. jannaschii toxin RelE harbours positive charges that are thought to neutralize the negative charges of the substrate mRNA, including Arg62 that was changed to Ser62 by the Escherichia coli expression system, thereby leading to inactive toxin RelE. Comparative studies suggest that Asp43 and His79 are also involved in the activity of the toxin.     

Toxin-antitoxin pairs in bacteria: killers or stress regulators?

Plasmid toxin-antitoxin systems, which kill daughter cells that fail to inherit the plasmid genome, have chromosomal homologs in eubacteria and archaea. In this issue of Cell, Pederson et al. show that the E. coli RelE toxin cleaves mRNA in the ribosomal A site, potentially allowing it to function as a stress regulator during amino acid starvation.     

Non-cytotoxic variants of the Kid protein that retain their auto-regulatory activity

Kid and Kis are, respectively, the toxin and antitoxin encoded by the parD operon of plasmid R1. The recently solved crystal structure of Kid has revealed that this protein closely resembles the CcdB toxin of plasmid F. In CcdB, the residues involved in toxicity are located at the carboxy-terminal end of the protein. However, an analogous information on the Kid toxin was not available. Here, we have characterized a collection of non-toxic mutants of the Kid protein and identified the residues that affected the toxicity but not the co-regulatory activity of Kid. These are located in two discrete regions of the protein, at the amino and carboxy-terminal ends. Particularly, residues E18 and R85, that are conserved in the Escherichia coli ChpAK and RelE toxins, are affected by amino-acid changes that alter neither the overall structure of the protein nor its state of association, as shown by CD and sedimentation equilibrium analyses. However, thermal denaturation and intrinsic tryptophan fluorescence emission data point to subtle local changes at the N-terminal end of the protein. The implications of these results in the current model on the structure and function of Kid-related bacterial toxins are discussed.     

Construction of a pTOC-T vector using GST-ParE toxin for direct cloning and selection of PCR products

Using linker insertion mutations, we determined the most stable region of the parE gene which encodes a toxic protein (ParE) that inhibits growth of Escherichia coli. The toxicity of ParE was sustained until a 144bp linker was inserted into this region. We have developed a 3 T-overhang vector based on these characteristics of the GST-ParE toxin, and named pTOC-T. Because pTOC-T uses a post-segregational killing system, all transformants grown up on the plates can be considered as recombinants containing foreign DNA. pTOC-T not require X-Gal, IPTG or other substrates for selection. This T-vector using a positive selection system can be applied to various E. coli strains such as XL1-Blue, BL21, DH5, JM109, and JM110.Revisions requested 28 July 2004; Revisions received 7 September 2004     

Contribution of different segments of the par region to stable maintenance of the broad-host-range plasmid RK2.

A 3.2-kb region of the broad-host-range plasmid RK2 has been shown to encode a highly efficient plasmid maintenance system that functions in a vector-independent manner. This region, designated par, consists of two divergently arranged operons: parCBA and parDE. The 0.7-kb parDE operon promotes plasmid stability by a postsegregational killing mechanism that ensures that plasmid-free daughter cells do not survive after cell division. The 2.3-kb parCBA operon encodes a site-specific resolvase protein (ParA) and its multimer resolution site (res) and two proteins (ParB and ParC) whose functions are as yet unknown. It has been proposed that the parCBA operon encodes a plasmid partitioning system (M. Gerlitz, O. Hrabak, and H. Schwabb, J. Bacteriol. 172:6194-6203, 1990; R. C. Roberts, R. Burioni, and D. R. Helinski, J. Bacteriol. 172:6204-6216, 1990). To further define the role of this region in promoting the stable maintenance of plasmid RK2, the parCBA and parDE operons separately and the intact (parCBA/DE) par region (3.2 kb) were reintroduced into an RK2 plasmid deleted for par and assayed for plasmid stability in two Escherichia coli strains (MC1061K and MV10delta lac). The intact 3.2-kb region provided the highest degree of stability in the two strains tested. The ability of the parCBA or parDE region alone to promote stable maintenance in the E. coli strains was dependent on the particular strain and the growth temperature. Furthermore, the insertion of the ColE1 cer site into the RK2 plasmid deleted for the par region failed to stabilize the plasmid in the MC1061K strain, indicating that the multimer resolution activity encoded by parCBA is not by itself responsible for the stabilization activity observed for this operon. To examine the relative contributions of postsegregational cell killing and a possible partitioning function encoded by the intact 3.2-kb par region, stability assays were carried out with ParD provided in trans by a compatible (R6K) minireplicon to prevent postsegregational killing. In E. coli MV10delta lac, postsegregational killing appeared to be the predominant mechanism for stabilization since the presence of ParD substantially reduced the stability of plasmids carrying either the 3.2- or 0.7-kb region. However, in the case of E. coli MC1061K, the presence of ParD in trans did not result in a significant loss of stabilization by the 3.2-kb region, indicating that the putative partitioning function was largely responsible for RK2 maintenance. To examine the basis for the apparent differences in postsegregational killing between the two E. coli strains, transformation assays were carried out to determine the relative sensitivities of the strains to the ParE toxin protein. Consistent with the relatively small contribution of the postsegregational killing to plasmid stabilization in MC1061K, we found that this strain was substantially more resistant to killing by ParE in comparison to E. coli MV10delta lac. A transfer-deficient mutant of thepar-deleted plasmid was constructed for the stable maintenance studies. This plasmid was found to be lost from E. coli MV10delta lac at a rate three times greater than the rate for the transfer-proficient plasmid, suggesting that conjugation can also play a significant role in the maintenance of plasmid RK2.     

Structural and thermodynamic characterization of the Escherichia coli RelBE toxin-antitoxin system: indication for a functional role of differential stability

The RelE and RelB proteins constitute the RNA interferase (toxin) and its cognate inhibitor (antitoxin) components of the Escherichia coli relBE toxin-antitoxin system. Despite the well-described functionality and physiological activity of this system in E. coli, no structural study was performed on the folding and stability of the protein pair in solution. Here we structurally and thermodynamically characterize the RelBE system components from E. coli in solution, both separately and in their complexed state. The RelB antitoxin, an alpha-helical protein according to circular dichroism and infrared spectroscopy, forms oligomers in solution, exhibits high thermostability with a TM of 58.5 degrees C, has a considerable heat resistance, and has high unfolding reversibility. In contrast, the RelE toxin includes a large portion of antiparallel beta-sheets, displays lower thermostability with a TM of 52.5 degrees C, and exhibits exceptional sensitivity to heat. Complex formation, accompanied by a structural transition, leads to a 12 degrees C increase in the TM and substantial heat resistance. Moreover, in vivo interaction and protein footprint experiments indicate that the C-terminal part of RelB is responsible for RelB-RelE interaction, being protease sensitive in its free state, while it becomes protected from proteolysis when complexed with RelE. Overall, our findings support the notion that RelB lacks a well-organized hydrophobic core in solution whereas RelE is a well-folded protein. Furthermore, our results support that RelB protein from E. coli is similar to ParD and CcdA antitoxins in both fold and thermodynamic properties. The differential folding state of the proteins is discussed in the context of their physiological activities.     

细菌毒素-抗毒素系统的研究进展

毒素-抗毒素系统(toxin-antitoxin system,TA)由两个共表达的基因组成,其中一个基因编码不稳定的抗毒素蛋白(antitoxin),另一个基因编码稳定的毒素蛋白(toxin).毒素-抗毒素系统最早发现于一些低拷贝的质粒,用来维持低拷贝质粒在菌群中的稳定存在.随后的研究表明,毒素-抗毒素系统广泛存在于细菌,包括一些致病菌的染色体上.在营养缺乏等不良生长条件下,由于基因表达的抑制和蛋白酶的降解作用,不稳定的抗毒素蛋白减少,从而产生游离的毒素蛋白,导致细菌的生长抑制和死亡.毒素-抗毒素系统的生理功能目前还存在争议,有学者认为细茼染色体上的毒素-抗毒素系统可以在不良生长状况下介导细菌的死亡,即细茼程序性细胞死亡(baeterial programmedcell death).但也有证据显示,毒素-抗毒素系统的功能更偏向于应激状态下的生理调节方面,即只起应激状态下的抑菌作用而不是杀菌作用.对细菌生长调控中毒素-抗毒素系统的作用机理进行综述,并探讨毒素-抗毒素系统研究的理论和应用价值.     

Novel Escherichia coli RF1 mutants with decreased translation termination activity and increased sensitivity to the cytotoxic effect of the bacterial toxins Kid and RelE

Novel mutations in prfA , the gene for the polypeptide release factor RF1 of Escherichia coli , were isolated using a positive genetic screen based on the parD ( kis , kid ) toxin–antitoxin system. This original approach allowed the direct selection of mutants with altered translational termination efficiency at UAG codons. The isolated prfA mutants displayed a ∼10-fold decrease in UAG termination efficiency with no significant changes in RF1 stability in vivo . All three mutations, G121S, G301S and R303H, were situated close to the nonsense codon recognition site in RF1:ribosome complexes. The prfA mutants displayed increased sensitivity to the RelE toxin encoded by the relBE system of E. coli , thus providing in vivo support for the functional interaction between RF1 and RelE. The prfA mutants also showed increased sensitivity to the Kid toxin. Since this toxin can cleave RNA in a ribosome-independent manner, this result was not anticipated and provided first evidence for the involvement of RF1 in the pathway of Kid toxicity. The sensitivity of the prfA mutants to RelE and Kid was restored to normal levels upon overproduction of the wild-type RF1 protein. We discuss these results and their utility for the design of novel antibacterial strategies in the light of the recently reported structure of ribosome-bound RF1.     

Construction of a pTOC-T vector using GST-ParE toxin for direct cloning and selection of PCR products

Using linker insertion mutations, we determined the most stable region of the parE gene which encodes a toxic protein (ParE) that inhibits growth of Escherichia coli. The toxicity of ParE was sustained until a 144 bp linker was inserted into this region. We have developed a 3' T-overhang vector based on these characteristics of the GST-ParE toxin, and named pTOC-T. Because pTOC-T uses a post-segregational killing system, all transformants grown up on the plates can be considered as recombinants containing foreign DNA. pTOC-T not require X-Gal, IPTG or other substrates for selection. This T-vector using a positive selection system can be applied to various E. coli strains such as XL1-Blue, BL21, DH5alpha, JM109, and JM110.     

Dual targeting DNA gyrase B (GyrB) and topoisomerse IV (ParE) inhibitors: A review

GyrB and ParE are type IIA topoisomerases and found in most bacteria. Its function is vital for DNA replication, repair and decatenation. The highly conserved ATP-binding subunits of DNA GyrB and ParE are structurally related and have been recognized as prime candidates for the development of dual-targeting antibacterial agents with broad-spectrum potential. However, no natural product or small molecule inhibitors targeting ATPase catalytic domain of both GyrB and ParE enzymes have succeeded in the clinic. Moreover, no inhibitors of these enzymes with broad-spectrum antibacterial activity against Gram-negative pathogens have been reported. Availability of high resolution crystal structures of GyrB and ParE made it possible for the design of many different classes of inhibitors with dual mechanism of action. Among them benzimidazoles, benzothiazoles, thiazolopyridines, imidiazopyridazoles, pyridines, indazoles, pyrazoles, imidazopyridines, triazolopyridines, pyrrolopyrimidines, pyrimidoindoles as well as related structures are disclosed in literatures. Unfortunately most of these inhibitors are found to be active against Gram-positive pathogens. In the present review we discuss about studies on novel dual targeting ATPase inhibitors.     

Crystal structure of archaeal toxin-antitoxin RelE-RelB complex with implications for toxin activity and antitoxin effects

The Escherichia coli chromosome encodes toxin-antitoxin pairs. The toxin RelE cleaves mRNA positioned at the A-site in ribosomes, whereas the antitoxin RelB relieves the effect of RelE. The hyperthermophilic archaeon Pyrococcus horikoshii OT3 has the archaeal homologs aRelE and aRelB. Here we report the crystal structure of aRelE in complex with aRelB determined at a resolution of 2.3 A. aRelE folds into an alpha/beta structure, whereas aRelB lacks a distinct hydrophobic core and extensively wraps around the molecular surface of aRelE. Neither component shows structural homology to known ribonucleases or their inhibitors. Site-directed mutagenesis suggests that Arg85, in the C-terminal region, is strongly involved in the functional activity of aRelE, whereas Arg40, Leu48, Arg58 and Arg65 play a modest role in the toxin's activity.     

Functional interactions between coexisting toxin-antitoxin systems of the ccd family in Escherichia coli O157:H7

Toxin-antitoxin (TA) systems are widely represented on mobile genetic elements as well as in bacterial chromosomes. TA systems encode a toxin and an antitoxin neutralizing it. We have characterized a homolog of the ccd TA system of the F plasmid (ccd(F)) located in the chromosomal backbone of the pathogenic O157:H7 Escherichia coli strain (ccd(O157)). The ccd(F) and the ccd(O157) systems coexist in O157:H7 isolates, as these pathogenic strains contain an F-related virulence plasmid carrying the ccd(F) system. We have shown that the chromosomal ccd(O157) system encodes functional toxin and antitoxin proteins that share properties with their plasmidic homologs: the CcdB(O157) toxin targets the DNA gyrase, and the CcdA(O157) antitoxin is degraded by the Lon protease. The ccd(O157) chromosomal system is expressed in its natural context, although promoter activity analyses revealed that its expression is weaker than that of ccd(F). ccd(O157) is unable to mediate postsegregational killing when cloned in an unstable plasmid, supporting the idea that chromosomal TA systems play a role(s) other than stabilization in bacterial physiology. Our cross-interaction experiments revealed that the chromosomal toxin is neutralized by the plasmidic antitoxin while the plasmidic toxin is not neutralized by the chromosomal antitoxin, whether expressed ectopically or from its natural context. Moreover, the ccd(F) system is able to mediate postsegregational killing in an E. coli strain harboring the ccd(O157) system in its chromosome. This shows that the plasmidic ccd(F) system is functional in the presence of its chromosomal counterpart.