A group of proteic toxin-antitoxin (TA) cassettes whose representatives are widely distributed among bacterial genomes has been identified. These cassettes occur in chromosomes, plasmids, bacteriophages, and noncomposite transposons, as well as in the SXT conjugative element of Vibrio cholerae. The following four homologous loci were subjected to detailed comparative studies: (i) tad-ata from plasmid pAMI2 of Paracoccus aminophilus (the prototype of this group), (ii) gp49-gp48 from the linear bacteriophage N15 of Escherichia coli, (iii) s045-s044 from SXT, and (iv) Z3230-Z3231 from the genomic island of enterohemorrhagic Escherichia coli O157:H7 strain EDL933. Functional analysis revealed that all but one of these loci (Z3230-Z3231) are able to stabilize heterologous replicons, although the host ranges varied. The TA cassettes analyzed have the following common features: (i) the toxins are encoded by the first gene of each operon; (ii) the antitoxins contain a predicted helix-turn-helix motif of the XRE family; and (iii) the cassettes have two promoters that are different strengths, one which is located upstream of the toxin gene and one which is located upstream of the antitoxin gene. All four toxins tested are functional in E. coli; overexpression of the toxins (in the absence of antitoxin) results in a bacteriostatic effect manifested by elongation of bacterial cells and growth arrest. The toxins have various effects on cell viability, which suggests that they may recognize different intracellular targets. Preliminary data suggest that different cellular proteases are involved in degradation of antitoxins encoded by the loci analyzed.Bacterial plasmids have modular structures, since it is possible to dissect them into several functional cassettes. The core region of the plasmid backbone is composed of a set of conserved modules, coding for replication and stability functions, which are crucial for plasmid maintenance. Comparative analyses of plasmid genomes have revealed that the same modules or closely related modules can be found in various combinations in different plasmids hosted by phylogenetically distinct bacteria. The plasticity of plasmid genomes is the result of horizontal gene transfer, as well as numerous recombinational events, which take place in diverse bacterial hosts. Recent advances in bacterial genomics have revealed that shuffling of modules is not limited to plasmids but is a much more common phenomenon, occurring in all bacterial mobile genetic elements. These elements may thus be considered combinations of exchangeable functional cassettes (78).Shuffling of modules, initially defined in plasmids, bacteriophages, and transposable elements, has resulted in (i) the generation of novel mobile elements, such as conjugative transposons (containing phage-related recombination modules plus plasmid-borne modules for conjugational transfer) (64), and (ii) the appearance of chimeric elements exhibiting new, unusual properties, including transposable bacteriophage Mu (containing a transposition mod...
The second replicator region of the native plasmid pTAVl of Paracoccus versutus has been identified thus proving the composite nature of this replicon. The minimal replicon designated pTAV320 (43 kb) was cloned and sequenced. pTAV320 encodes three putative proteins -RepA, RepB and RepC.This replicator region shows strong structural and functional similarity t o mpABC-type rep1 icons found in several Agrobacterium and Rhizobium plasmids. The origin of replication appears to be localized within the coding sequence of the repC gene. RepC was shown t o be essential for replication. RepA and RepB were necessary for stable maintenance of the plasmid, which implies a role in active partitioning. The presence of the complete sequence of pTAV320 (in its non-replicative form) could stabilize in cis pTAV202, a rninireplicon derived from the other pTAVl replicator region. Deletions introduced into the mpC gene abolished the 'stabilizing' activity of pTAV320, suggesting that the centromere-like sequence, necessary for partitioning, might be localized within this gene. The two replicator regions of pTAV1 (pTAV320 and pTAV202) expressed incompatibility towards the parental plasmid but were compatible in trans in P. wersutus cells. The pTAV320 replicon can be maintained in several Paracoccus, Agrobacterium, Rhizobium and Rhodohcter strains in addition t o P. versutus.
Several trap plasmids (enabling positive selection of transposition events) were used to identify a pool of functional transposable elements (TEs) residing in bacteria of the genus Paracoccus (Alphaproteobacteria). Complex analysis of 25 strains representing 20 species of this genus led to the capture and characterization of (i) 37 insertion sequences (ISs) representing 9 IS families (IS3, IS5, IS6, IS21, IS66, IS256, IS1182, IS1380 and IS1634), (ii) a composite transposon Tn6097 generated by two copies of the ISPfe2 (IS1634 family) containing two predicted genetic modules, involved in the arginine deiminase pathway and daunorubicin/doxorubicin resistance, (iii) 3 non-composite transposons of the Tn3 family, including Tn5393 carrying streptomycin resistance and (iv) a transposable genomic island TnPpa1 (45 kb). Some of the elements (e.g. Tn5393, Tn6097 and ISs of the IS903 group of the IS5 family) were shown to contain strong promoters able to drive transcription of genes placed downstream of the target site of transposition. Through the application of trap plasmid pCM132TC, containing a promoterless tetracycline resistance reporter gene, we identified five ways in which transposition can supply promoters to transcriptionally silent genes. Besides highlighting the diversity and specific features of several TEs, the analyses performed in this study have provided novel and interesting information on (i) the dynamics of the process of transposition (e.g. the unusually high frequency of transposition of TnPpa1) and (ii) structural changes in DNA mediated by transposition (e.g. the generation of large deletions in the recipient molecule upon transposition of ISPve1 of the IS21 family). We also demonstrated the great potential of TEs and transposition in the generation of diverse phenotypes as well as in the natural amplification and dissemination of genetic information (of adaptative value) by horizontal gene transfer, which is considered the driving force of bacterial evolution.
N,N-Dimethylformamide (DMF), a toxic solvent used in the chemical industry, is frequently present in industrial wastes. Plasmid pAMI2 (18.6 kb) of Paracoccus aminophilus JCM 7686 carries genetic information which is crucial for methylotrophic growth of this bacterium, using DMF as the sole source of carbon and energy. Besides a conserved backbone related to pAgK84 of Agrobacterium radiobacter K84, pAMI2 carries a three-gene cluster coding for the protein DmfR, which has sequence similarities to members of the LuxR family of transcription regulators, and two subunits (DmfA1 and DmfA2) of N,N-dimethylformamidase, an enzyme of high substrate specificity that catalyzes the first step in the degradation of DMF. Genetic analysis revealed that these genes, which are all placed in the same orientation, constitute an inducible operon whose expression is activated in the presence of DMF by the positive transcription regulator DmfR. This operon was used to construct a strain able to degrade DMF at high concentrations that might be used in the biotreatment of DMF-containing industrial wastewaters. To our knowledge, this is the first study to provide insights into the genetic organization and regulation as well as the dissemination in bacteria of genes involved in the enzymatic breakdown of DMF.
We studied diversity and distribution of transposable elements residing in different strains (DSM 11072, DSM 11073, DSM 65, and LMD 82.5) of a soil bacterium Paracoccus pantotrophus (␣-Proteobacteria). With application of a shuttle entrapment vector pMEC1, several novel insertion sequences (ISs) and transposons (Tns) have been identified. They were sequenced and subjected to detailed comparative analysis, which allowed their characterization (i.e., identification of transposase genes, terminal inverted repeats, as well as target sequences) and classification into the appropriate IS or Tn families. The frequency of transposition of these elements varied and ranged from 10 ؊6 to 10 ؊3 depending on the strain. The copy number, localization (plasmid or chromosome), and distribution of these elements in the Paracoccus species P. pantotrophus, P. denitrificans, P. methylutens, P. solventivorans, and P. versutus were analyzed. This allowed us to distinguish elements that are common in paracocci (ISPpa2, ISPpa3-both of the IS5 family-and ISPpa5 of IS66 family) as well as strain-specific ones (ISPpa1 of the IS256 family, ISPpa4 of the IS5 family, and Tn3434 and Tn5393 of the Tn3 family), acquired by lateral transfer events. These elements will be of a great value in the design of new genetic tools for paracocci, since only one element (IS1248 of P. denitrificans) has been described so far in this genus.
We demonstrated that a single copy of insertion sequence ISPme1 can mobilize adjacent segments of genomic DNA of Paracoccus methylutens DM12, which leads to the generation of diverse transposable elements of various size and DNA contents. All elements (named transposable modules [TMos]) contain ISPme1 (placed at the 5 ends of the elements) and have variable 3-end regions of between 0.5 and 5 kb. ISPme1 was shown to encode an outwardly oriented promoter, which may activate the transcription of genes transposed within TMos in evolutionarily distinct hosts. TMos may therefore be considered to be natural systems enabling gene capture, expression, and spread. However, unless these elements have been inserted into a highly conserved genetic context to enable a precise definition of their termini, it is extremely difficult or even impossible to identify them in bacterial genomes by in silico sequence analysis. We showed that TMos are present in the chromosome and plasmids of strain DM12. Sequence analysis of plasmid pMTH1 (32 kb) revealed that four TMos, previously identified with a trap vector, pMEC1, comprise 87% of its genome. Repeated TMos within pMTH1 may stimulate other structural rearrangements resulting from homologous recombination between long repeat sequences. This illustrates that TMos may play a significant role in shaping the structure of natural plasmids, which consequently may have a great impact on the evolution of plasmid genomes.Sequencing projects have revealed that bacterial genomes are not static, monolithic structures. They can contain a number of different kinds of integrated mobile genetic elements (e.g., transposable elements, plasmids, bacteriophages, and integrative and conjugative elements) acquired by lateral gene transfer.Insertion sequences (ISs), which are the simplest forms of transposable elements (TEs), are components of nearly all bacterial genomes. To date, more than 1,500 ISs have been identified in over 295 bacterial and archaeal species (21). The transposition of ISs promotes structural changes in DNA that lead to the formation of various mutations (insertions, deletions, inversions, translocations, and replicon fusion). These elements are therefore considered to be the major recombinogenic factors in bacterial genomes. Their activity results in the shuffling of genetic information among various replicons present in a bacterial cell (chromosomes, plasmids, and bacteriophages), which may ultimately enable its spread by lateral gene transfer. These elements thus play the role of a factor that significantly enhances variability and, consequently, the adaptive and evolutionary capacities of their hosts.ISs have a very simple structure, since they carry only the genetic information necessary for their own transposition.
The replicon of the pTAV3 megaplasmid (approx. 400 kb) of Paracoccus versutus has been localized to a 4 3 kb EcoRI restriction fragment and its entire nucleotide sequence determined. The GMC content of the entire sequence is 66 mol %, which is within the range (62-66 mol %) previously determined for P. versutus total DNA. ORF1 encodes a replication initiation protein Rep (47 2 kDa), which shares substantial similarity with putative proteins of the Coxiella burnetii plasmids QpH1 and QpDV, and the replication protein of Pseudomonas syringae plasmid pPS10. ORF2, located in the opposite transcriptional orientation to ORF1, encodes a putative protein that shares similarity to a subfamily of ATPases involved in plasmid partitioning. The highest similarity was observed with homologous proteins (RepA) encoded by the repABC family of replicons found in several plasmids of Agrobacterium, Rhizobium and Paracoccus spp. The predicted product of ORF3 was similar to AcoR, Nif and NtrC transcriptional activators. A strong incompatibility determinant (inc) was localized between ORF1 (rep) and ORF2 (parA). The origin of replication of pTAV400 contains a short AMT-rich region and several imperfect palindromic sequences. Curing experiments demonstrated that the megaplasmid bears genes required for growth in minimal media and can therefore be referred to as a mini-chromosome. Megaplasmids pTAV3 of P. versutus UW1 and pKLW2 of Paracoccus pantotrophus DSM 11073 were found to carry closely related, incompatible replicons. It has been shown that plasmid pORI6 (containing oriV of pTAV3 cloned into plasmid pABW1, which does not replicate in Paracoccus spp.) can be trans activated not only by pTAV3, but also by pKLW2. Using pORI6, it was demonstrated that replication systems related to pTAV3 are also present in the replicons of Paracoccus alcaliphilus JCM 7364, Paracoccus thiocyanatus IAM 12816 and Paracoccus methylutens DM 12.
The complete nucleotide sequence of the small, cryptic plasmid pWKS1 (2697 bp) of Paracoccus pantotrophus DSM 11072 was determined. The GMC content of the sequence of this plasmid was 62 mol %. Analysis revealed that over 80 % of the plasmid genome was covered by two ORFs, ORF1 and ORF2, which were capable of encoding putative peptides of 441 and 378 kDa, respectively. Mutational analysis showed that ORF2 was crucial for plasmid replication.
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