Plasmid replication functions: two distinct segments of plasmid R1, RepA and RepD, express incompatibility and are capable of autonomous replication.

The genetic determinants for replication and incompatibility of plasmid R1 were investigated by gene cloning methods, and three types of R1 miniplasmid derivatives were generated. The first, exemplified by plasmid pKT300, consisted of a single BglII endonuclease-generated deoxyribonucleic acid fragment derived from the R1 region that is located between the determinants for conjugal transfer and antibiotic resistance. Two types of miniplasmids could be formed from PstI endonuclease-generated fragments of pKT300. One of these, which is equivalent to miniplasmids previously generated from plasmids R1-19 and R1-19B2, consisted of two adjacent PstI fragments that encode the RepA replication system of plasmid R1. The other type contained a segment of R1, designated the RepD replication region, that is adjacent to the RepA region and that has not been identified previously as having the capacity for autonomous replication. Plasmid R1, therefore, contained two distinct deoxyribonucleic acid segments capable of autonomous replication. The RepA-RepD miniplasmid pKT300 had a copy number about eightfold higher than that of R1 and hence lacked a determinant for the regulation of plasmid copy number. Like R1, it was maintained stably in dividing bacteria. RepA miniplasmids had copy numbers which were two- to fourfold higher than that of R1 (i.e., which were lower than that of pKT300) and were maintained slightly less stably than those of pKT300 and R1. The RepD miniplasmid was not maintained stably in dividing bacteria. Previous experiments have shown that incompatibility of IncFII group plasmids is specified by a plasmid copy control gene. Despite the fact that RepA miniplasmids of R1 were defective in copy control, they nevertheless expressed incompatibility. This suggests that two genes are responsible for plasmid copy control, one that specifies incompatibility and is located on RepA miniplasmids and another that is located outside of, but adjacent to, the RepA replication region. Hybrid plasmids composed of pBR322 and one PstI fragment from the RepA region, P-8, exhibited incompatibility towards R2 and RepA miniplasmids but not the RepD miniplasmid, whereas hybrids composed of pBR322 and the PstI fragment of the RepD region, P-3, exhibited incompatibility towards R1 and the RepD miniplasmid but not RepA miniplasmids. These results indicate that the two replication systems are functionally distinct and that, although the RepA system is the principal replication system of R1, the RepD system also plays a role in the maintenance of this plasmid.     

Evolutionary relationships between catabolic pathways for aromatics: Conservation of gene order and nucleotide sequences of catechol oxidation genes of pWW0 and NAH7 plasmids

Summary TOL plasmid pWW0 and plasmid NAH7 encode catabolic enzymes required for oxidative degradation of toluene and naphthalene, respectively. The gene order of the catabolic operon of NAH7 for salicylate oxidation was determined to be: promoter-nahG (the structural gene for salicylate hydroxylase)-nahH (catechol 2,3-dioxygenase)-nahI (hydroxymuconic semialdehyde dehydrogenase)-nahN (hydroxymuconic semialdehyde hydrolase)-nahL (2-oxopent-4-enoate hydratase). This order is identical to that of the isofunctional genes of TOL plasmid pWW0. The complete nucleotide sequence of nahH was determined and compared with that of xylE, the isofunctional gene of TOL plasmid pWW0. There were 20% and 16% differences in their nucleotide and amino acid sequences, respectively. The homology between the NAH7 and TOL pWW0 plasmids ends upstream of the Shine-Dalgarno sequences of nahH and xylE, but the homology continues downstream of these genes. This observation suggested that genes for the catechol oxidative enzymes of NAH7 and TOL pWW0 were derived from a common ancestral sequence which was transferred as a discrete segment of DNA between plasmids.     

Characterization of the replication, maintenance, and transfer features of the IncP-7 plasmid pCAR1, which carries genes involved in carbazole and dioxin degradation

Isolated from Pseudomonas resinovorans CA10, pCAR1 is a 199-kb plasmid that carries genes involved in the degradation of carbazole and dioxin. The nucleotide sequence of pCAR1 has been determined previously. In this study, we characterized pCAR1 in terms of its replication, maintenance, and conjugation. By constructing miniplasmids of pCAR1 and testing their establishment in Pseudomonas putida DS1, we show that pCAR1 replication is due to the repA gene and its upstream DNA region. The repA gene and putative oriV region could be separated in P. putida DS1, and the oriV region was determined to be located within the 345-bp region between the repA and parW genes. Incompatibility testing using the minireplicon of pCAR1 and IncP plasmids indicated that pCAR1 belongs to the IncP-7 group. Monitoring of the maintenance properties of serial miniplasmids in nonselective medium, and mutation and complementation analyses of the parWABC genes, showed that the stability of pCAR1 is attributable to the products of the parWAB genes. In mating assays, the transfer of pCAR1 from CA10 was detected in a CA10 derivative that was cured of pCAR1 (CA10dm4) and in P. putida KT2440 at frequencies of 3 x 10(-1) and 3 x 10(-3) per donor strain, respectively. This is the first report of the characterization of this completely sequenced IncP-7 plasmid.     

Copy number control and incompatibility of plasmid R1: Identification of a protein that seems to be involved in both processes

Summary Investigations into the genetic determinants for incompatibility of miniplasmids and hybrid replicons constructed from wild type and mutant R1 revealed the presence of an incompatibility function at the junction of two small PstI fragments. These two fragments were not distinguished in earlier experiments since they have the same mobility on agarose gels. This incompatibility function is distinct from other inc-determinants of R1 (Kollek and Goebel 1979; Molin and Nordström, 1980) and independent of R1-type replication. By means of specific deletions and subcloning of DNA fragments, the location of this new inc-determinant could be determined further. After deletion of this inc-determinant from miniplasmids, a 5-fold increase in copy number was observed which could then be reduced to a copy number of about 1 plasmid per cell by complementation with hybrid plasmids having this function. Incompatibility of miniplasmids deleted in this determinant is not reduced, whereas analogous deletions introduced into recombinant plasmids nearly abolish their incompatibility. This determinant seems to exert strong incompatibility only when cloned on pBR322. Therefore, its main function in plasmid R1 is probably restricted to copy control. The appearance of low copy numbers of miniplasmids carrying this determinant and of trans-acting copy control and strong incompatibility exerted by hybrid plasmids is consistently correlated with the presence of a protein of 11,000 molecular weight, synthesized in relatively large amounts in Escherichia coli minicells.     

Characterization of the Replication, Maintenance, and Transfer Features of the IncP-7 Plasmid pCAR1, Which Carries Genes Involved in Carbazole and Dioxin Degradation

Isolated from Pseudomonas resinovorans CA10, pCAR1 is a 199-kb plasmid that carries genes involved in the degradation of carbazole and dioxin. The nucleotide sequence of pCAR1 has been determined previously. In this study, we characterized pCAR1 in terms of its replication, maintenance, and conjugation. By constructing miniplasmids of pCAR1 and testing their establishment in Pseudomonas putida DS1, we show that pCAR1 replication is due to the repA gene and its upstream DNA region. The repA gene and putative oriV region could be separated in P. putida DS1, and the oriV region was determined to be located within the 345-bp region between the repA and parW genes. Incompatibility testing using the minireplicon of pCAR1 and IncP plasmids indicated that pCAR1 belongs to the IncP-7 group. Monitoring of the maintenance properties of serial miniplasmids in nonselective medium, and mutation and complementation analyses of the parWABC genes, showed that the stability of pCAR1 is attributable to the products of the parWAB genes. In mating assays, the transfer of pCAR1 from CA10 was detected in a CA10 derivative that was cured of pCAR1 (CA10dm4) and in P. putida KT2440 at frequencies of 3 × 10⁻¹ and 3 × 10⁻³ per donor strain, respectively. This is the first report of the characterization of this completely sequenced IncP-7 plasmid.     

Genomic and functional analysis of the IncP-9 naphthalene-catabolic plasmid NAH7 and its transposon Tn4655 suggests catabolic gene spread by a tyrosine recombinase

The naphthalene-catabolic (nah) genes on the incompatibility group P-9 (IncP-9) self-transmissible plasmid NAH7 from Pseudomonas putida G7 are some of the most extensively characterized genetic determinants for bacterial aerobic catabolism of aromatic hydrocarbons. In contrast to the detailed studies of its catabolic cascade and enzymatic functions, the biological characteristics of plasmid NAH7 have remained unclear. Our sequence determination in this study together with the previously deposited sequences revealed the entire structure of NAH7 (82,232 bp). Comparison of NAH7 with two other completely sequenced IncP-9 catabolic plasmids, pDTG1 and pWW0, revealed that the three plasmids share very high nucleotide similarities in a 39-kb region encoding the basic plasmid functions (the IncP-9 backbone). The backbone of NAH7 is phylogenetically more related to that of pDTG1 than that of pWW0. These three plasmids carry their catabolic gene clusters at different positions on the IncP-9 backbone. All of the NAH7-specified nah genes are located on a class II transposon, Tn4655. Our analysis of the Tn4655-encoded site-specific recombination system revealed that (i) a novel tyrosine recombinase, TnpI, catalyzed both the intra- and intermolecular recombination between two copies of the attI site, (ii) the functional attI site was located within a 119-bp segment, and (iii) the site-specific strand exchange occurred within a 30-bp segment in the 41-bp CORE site. Our results and the sequence data of other naphthalene-catabolic plasmids, pDTG1 and pND6-1, suggest a potential role of the TnpI-attI recombination system in the establishment of these catabolic plasmids.     

Global transcriptional response of solvent‐sensitive and solvent‐tolerant Pseudomonas putida strains exposed to toluene

Pseudomonas putida strains are generally recognized as solvent tolerant, exhibiting varied sensitivity to organic solvents. Pan‐genome analysis has revealed that 30% of genes belong to the core‐genome of Pseudomonas. Accessory and unique genes confer high degree of adaptability and capabilities for the degradation and synthesis of a wide range of chemicals. For the use of these microbes in bioremediation and biocatalysis, it is critical to understand the mechanisms underlying these phenotypic differences. In this study, RNA‐seq analysis compared the short‐ and long‐term responses of the toluene‐sensitive KT2440 strain and the highly tolerant DOT‐T1E strain. The sensitive strain activates a larger number of genes in a higher magnitude than DOT‐T1E. This is expected because KT2440 bears one toluene tolerant pump, while DOT‐T1E encodes three of these pumps. Both strains activate membrane modifications to reduce toluene membrane permeability. The KT2440 strain activates the TCA cycle to generate energy, while avoiding energy‐intensive processes such as flagellar biosynthesis. This suggests that KT2440 responds to toluene by focusing on survival mechanisms. The DOT‐T1E strain activates toluene degradation pathways, using toluene as source of energy. Among the unique genes encoded by DOT‐T1E is a 70 kb island composed of genes of unknown function induced in response to toluene.     

A new extant respirometric assay to estimate intrinsic growth parameters applied to study plasmid metabolic burden

Start‐up phenomena in microbial biokinetic assays are not captured by the most commonly used growth‐related equations. In this study we propose a new respirometric experimental design to estimate intrinsic growth parameters that allow us to avoid these limitations without data omission, separate mathematical treatment, or wake‐up pulses prior to the analysis. Identifiability and sensitivity analysis were performed to confirm the robustness of the new approach for obtaining unique and accurate estimates of growth kinetic parameters. The new experimental design was applied to establish the metabolic burden caused by the carriage of a pWW0 TOL plasmid in the model organism Pseudomonas putida KT2440. The metabolic burden associated was manifested as a reduction in the yield and the specific growth rate of the host, with both plasmid maintenance and the over‐expression of recombinant proteins from the plasmid contributing equally to the overall effect. Biotechnol. Bioeng. 2010;105: 141–149. © 2009 Wiley Periodicals, Inc.     

Complete sequence determination combined with analysis of transposition/site-specific recombination events to explain genetic organization of IncP-7 TOL plasmid pWW53 and related mobile genetic elements

Recent studies have indicated that the evolutionarily common catabolic gene clusters are loaded on structurally diverse toluene-catabolic (TOL) plasmids and their residing transposons. To elucidate the mechanisms supporting the diversification of catabolic plasmids and transposons, we determined here the complete 107,929 bp sequence of pWW53, a TOL plasmid from Pseudomonas putida MT53. pWW53 was found to belong to the IncP-7 incompatibility group that play important roles in the catabolism of several xenobiotics. pWW53 carried two distinct transposase-resolvase gene clusters (tnpAR modules), five short terminal inverted repeats (IRs), and three site-specific resolution (res) sites that are all typical of class II transposons. This organization of pWW53 suggested the four possible transposable regions, Tn4657 to Tn4660. The largest 86 kb region (Tn4657) spanned the three other regions, and Tn4657 and Tn4660 (62 kb) covered all of the 36 xyl genes for toluene catabolism. Our subsequent transposition experiments clarified that the three transposons, Tn4657 to Tn4659, indeed exhibit their transposability, and that pWW53 also generated another 37 kb toluene-catabolic transposon, Tn4656, which carried the two separated and inversely oriented segments of pWW53: the tnpRA-IR module of Tn4658 and a part of xyl gene clusters on Tn4657. The Tn4658 transposase was able to mediate the transposition of Tn4658, Tn4657, and Tn4656, while the Tn4659 transposase catalyzed only the transposition of Tn4659. Tn4656 was formed by the Tn4658 resolvase-mediated site-specific inversion between the two inversely oriented res sites on pWW53. These findings and comparison with other catabolic plasmids clearly indicate multiple copies of transposition-related genes and sites on one plasmid and their recombination activities contribute greatly to the diversification of plasmid structures as well as wide dissemination of the evolutionary common gene clusters in various plasmids.     

The rulB gene of plasmid pWW0 is a hotspot for the site‐specific insertion of integron‐like elements found in the chromosomes of environmental Pseudomonas fluorescens group bacteria

The rulAB operon of Pseudomonas spp. confers fitness traits on the host and has been suggested to be a hotspot for insertion of mobile elements that carry avirulence genes. Here, for the first time, we show that rulB on plasmid pWW0 is a hotspot for the active site‐specific integration of related integron‐like elements (ILEs) found in six environmental pseudomonads (strains FH1–FH6). Integration into rulB on pWW0 occurred at position 6488 generating a 3 bp direct repeat. ILEs from FH1 and FH5 were 9403 bp in length and contained eight open reading frames (ORFs), while the ILE from FH4 was 16 233 bp in length and contained 16 ORFs. In all three ILEs, the first 5.1 kb (containing ORFs 1–4) were structurally conserved and contained three predicted site‐specific recombinases/integrases and a tetR homologue. Downstream of these resided ORFs of the ‘variable side’ with structural and sequence similarity to those encoding survival traits on the fitness enhancing plasmid pGRT1 (ILE_FH1 and ILE_FH5) and the NR‐II virulence region of genomic island PAGI‐5 (ILE_FH4). Collectively, these ILEs share features with the previously described type III protein secretion system effector ILEs and are considered important to host survival and transfer of fitness enhancing and (a)virulence genes between bacteria.     

Comparative genetic organization of incompatibility group P degradative plasmids.

Plasmids that encode genes for the degradation of recalcitrant compounds are often examined only for characteristics of the degradative pathways and ignore regions that are necessary for plasmid replication, incompatibility, and conjugation. If these characteristics were known, then the mobility of the catabolic genes between species could be predicted and different catabolic pathways might be combined to alter substrate range. Two catabolic plasmids, pSS50 and pSS60, isolated from chlorobiphenyl-degrading strains and a 3-chlorobenzoate-degrading plasmid, pBR60, were compared with the previously described IncP group (Pseudomonas group P-1) plasmids pJP4 and R751. All three of the former plasmids were also members of the IncP group, although pBR60 is apparently more distantly related. DNA probes specific for known genetic loci were used to determine the order of homologous loci on the plasmids. In all of these plasmids the order is invariant, demonstrating the conservation of this "backbone" region. In addition, all five plasmids display at least some homology with the mercury resistance transposon, Tn501, which has been suggested to be characteristic of the beta subgroup of the IncP plasmids. Plasmids pSS50 and pSS60 have been mapped in detail, and repeat sequences that surround the suspected degradation genes are described.     

Generation of miniplasmids from copy number mutants of the R plasmid NR1.

Small, closed circular deoxyribonucleic acid molecules, called miniplasmids, were observed in Escherichia coli harboring copy number mutants of the R plasmid NR1 after growth in medium containing tetracycline. The level of tetracycline resistance conferred by the copy mutant plasmids was lower (3 to 6 microgram/ml) than that conferred by NR1 (100 MICROGRAM/ML). The presence of the miniplasmid enhanced the level of tetracycline resistance conferred by the copy mutant. Miniplasmids of molecular weights 4 X 10(6) to 13 X 10(6) were found. They carried no antibiotic resistance markers and could be eliminated by growth in the presence of chloramphenicol and/or streptomycin-spectinomycin. Studies with the restriction endonucleases EcoRI and Sal I indicated that the miniplasmids are derived from the region of the copy mutant plasmids that contains the origin for replication of the resistance transfer factor. There were approximately 12 copies of the miniplasmid per chromosome, compared with 3 and 6 copies of the copy mutants of NR1. The miniplasmids appeared to be incompatible with the copy mutant plasmids.     

Predicting Plasmid Promiscuity Based on Genomic Signature

Despite the important contribution of self-transmissible plasmids to bacterial evolution, little is understood about the range of hosts in which these plasmids have evolved. Our goal was to infer this so-called evolutionary host range. The nucleotide composition, or genomic signature, of plasmids is often similar to that of the chromosome of their current host, suggesting that plasmids acquire their hosts’ signature over time. Therefore, we examined whether the evolutionary host range of plasmids could be inferred by comparing their trinucleotide composition to that of all completely sequenced bacterial chromosomes. The diversity of candidate hosts was determined using taxonomic classification and genetic distance. The method was first tested using plasmids from six incompatibility (Inc) groups whose host ranges are generally thought to be narrow (IncF, IncH, and IncI) or broad (IncN, IncP, and IncW) and then applied to other plasmid groups. The evolutionary host range was found to be broad for IncP plasmids, narrow for IncF and IncI plasmids, and intermediate for IncH and IncN plasmids, which corresponds with their known host range. The IncW plasmids as well as several plasmids from the IncA/C, IncP, IncQ, IncU, and PromA groups have signatures that were not similar to any of the chromosomal signatures, raising the hypothesis that these plasmids have not been ameliorated in any host due to their promiscuous nature. The inferred evolutionary host range of IncA/C, IncP-9, and IncL/M plasmids requires further investigation. In this era of high-throughput sequencing, this genomic signature method is a useful tool for predicting the host range of novel mobile elements.Comparative genomics has clearly shown that bacterial evolution occurs not only through genetic changes that are vertically inherited but also by extensive horizontal gene transfer between closely and distantly related bacteria (9). Mobile genetic elements such as plasmids and phages serve as important agents of horizontal gene transfer that can exchange genetic material between chromosomes (26). Plasmids also play a critical role in rapid bacterial adaptation to local environmental changes, as best exemplified by the alarmingly rapid spread of plasmid-encoded multidrug resistance in human pathogens (44, 66). In spite of this, very little is understood about the range of bacterial hosts in which these plasmids may have resided and evolved in natural or clinical environments over time, i.e., their potential “evolutionary host range.” Understanding the evolutionary history of virulence, catabolic, and other plasmids may help us to reconstruct the plasmid transfer network among microorganisms and track the pathways of gene dissemination.A plasmid''s host range can be defined in different ways, but it is typically understood as the range of hosts in which a plasmid can replicate (replication host range, or from here on simply called “host range”). This host range is often narrower than the range of hosts to which the plasmid can transfer by conjugation (transfer host range) (32, 72) but wider than the range in which it can be stably maintained (long-term host range) (16). The host range of a plasmid is often determined by mating assays, wherein that plasmid is transferred into a set of recipient strains followed by selection for transconjugant clones that can express one of the traits encoded by the plasmid (40, 47). Ideally, the physical presence of the plasmids is then verified to confirm independent replication. Sometimes the host range is also inferred from the observed natural range of hosts in which a plasmid is found in various habitats (24, 72). The plasmid host range is known to be highly variable among plasmids, and the terms “narrow host range” and “broad host range” are used as qualitative indicators (18, 49, 62). For example, it has been generally considered that incompatibility (Inc) groups IncF, IncH, and IncI contain self-transmissible narrow-host-range plasmids, while IncN, IncP, and IncW plasmids transfer and replicate in a broad range of hosts (13, 49, 62). This oldest system of plasmid classification into Inc groups is based on the inability of plasmids from the same group to be maintained in the same host due to similarity in replication or partitioning systems (11, 53). We note that IncP plasmids are also called IncP-1 in the Pseudomonas classification system, but they are here referred to as IncP. The entire range of hosts, including ancestral forms and extant bacteria, in which a plasmid has replicated at some point during its evolutionary history is of course unknown but expected to be narrower than its replication range. Here, we designate this range the “evolutionary host range.”To understand the contributions of plasmids to horizontal gene transfer and bacterial evolution, it is not sufficient to know the hosts in which plasmids can potentially replicate and be maintained when tested in the laboratory or the field. While very valid, such experiments (13, 17, 40, 47, 56, 72) do not allow us to evaluate which plasmids have in fact spread among the widest range of hosts in the past and therefore contributed most so far to horizontal gene transfer across distantly related bacteria. We also need to gain insight into the range of hosts in which they have actually resided over evolutionary time—their evolutionary host range. This insight into the evolutionary history of plasmids will also shed light on the reservoirs of the many unwanted drug resistance and virulence plasmids (65). Previous studies have shown that the dinucleotide composition (2-mer genomic signatures) of plasmids tend to be similar to those of the chromosomes of their known host, suggesting that the plasmids acquire the host''s genomic signature (7, 67). It has previously been suggested that host-specific mutational biases homogenize the nucleotide compositions of genetic elements that are being replicated in the same host (plasmids, phages, and DNA fragments inserted in the chromosome); this phenomenon has been designated “genome amelioration” (7, 43). In addition, due to the potential DNA exchange between chromosomes and plasmids by recombination and transposition (8, 42), acquisition of large sections of chromosomal DNA by plasmids may also result in similar signatures between plasmids and their evolutionary hosts. It thus follows that a similar genomic signature between a plasmid and a host''s chromosome may indicate residence of the plasmid in that or a closely related host during its evolutionary history. Therefore, it should be possible to infer the evolutionary host range for plasmids whose genome sequences have been determined, based on the similarity in genomic signature with that of completely sequenced bacterial chromosomes.The goal of this study was to infer the evolutionary host range of various plasmids based on their genomic signatures. Specifically, we postulate (i) that known broad-host-range plasmids from Proteobacteria have evolved in a wider range of hosts than narrow-host-range plasmids and (ii) that our genomic signature approach can be used to assess the promiscuity of sequenced but uncharacterized plasmids and other mobile elements. To develop our approach, we chose self-transmissible plasmids belonging to six incompatibility groups, whose host ranges have been studied intensively and are thought to be narrow (IncF, IncH, and IncI) or broad (IncN, IncP, and IncW). To propose candidate evolutionary hosts of these plasmids, we compared the genomic signature of each plasmid with those of 817 chromosomes of prokaryotes for which complete sequences were available. Our results suggest that the evolutionary host range is broad for IncP plasmids, narrow for IncF and IncI plasmids, and intermediate for IncH and IncN plasmids. The lack of hosts with signatures similar to the IncW plasmids raises the hypothesis that they have not been ameliorated for any host due to their promiscuity. We then used the same method to infer the evolutionary host range of additional plasmid groups, such as IncA/C (also called IncP-3), IncL/M, IncP-9, IncQ (IncP-4), IncU, and PromA and plasmids Ri and Ti from Agrobacterium sp. (designated Ri/Ti). The similarities and discrepancies between our findings and previous knowledge on plasmid host range are discussed.     

ParA‐mediated plasmid partition driven by protein pattern self‐organization

DNA segregation ensures the stable inheritance of genetic material prior to cell division. Many bacterial chromosomes and low‐copy plasmids, such as the plasmids P1 and F, employ a three‐component system to partition replicated genomes: a partition site on the DNA target, typically called parS, a partition site binding protein, typically called ParB, and a Walker‐type ATPase, typically called ParA, which also binds non‐specific DNA. In vivo, the ParA family of ATPases forms dynamic patterns over the nucleoid, but how ATP‐driven patterning is involved in partition is unknown. We reconstituted and visualized ParA‐mediated plasmid partition inside a DNA‐carpeted flowcell, which acts as an artificial nucleoid. ParA and ParB transiently bridged plasmid to the DNA carpet. ParB‐stimulated ATP hydrolysis by ParA resulted in ParA disassembly from the bridging complex and from the surrounding DNA carpet, which led to plasmid detachment. Our results support a diffusion‐ratchet model, where ParB on the plasmid chases and redistributes the ParA gradient on the nucleoid, which in turn mobilizes the plasmid.     

Complete sequence of the IncP-9 TOL plasmid pWW0 from Pseudomonas putida

The TOL plasmid pWW0 (117 kb) is the best studied catabolic plasmid and the archetype of the IncP-9 plasmid incompatibility group from Pseudomonas. It carries the degradative (xyl) genes for toluenes and xylenes within catabolic transposons Tn4651 and Tn4653. Analysis of the complete pWW0 nucleotide sequence revealed 148 putative open reading frames. Of these, 77 showed similarity to published sequences in the available databases predicting functions for: plasmid replication, stable maintenance and transfer; phenotypic determinants; gene regulation and expression; and transposition. All identifiable transposition functions lay within the boundaries of the 70 kb transposon Tn4653, leaving a 46 kb sector containing all the IncP-9 core functions. The replicon and stable inheritance region was very similar to the mini-replicon from IncP-9 antibiotic resistance plasmid pM3, with their Rep proteins forming a novel group of initiation proteins. pWW0 transfer functions exist as two blocks encoding putative DNA processing and mating pair formation genes, with organizational and sequence similarity to IncW plasmids. In addition to the known Tn4651 and IS1246 elements, two additional transposable elements were identified as well as several putative transposition functions, which are probably genetic remnants from previous transposition events. Genes likely to be responsible for known resistance to ultraviolet light and free radicals were identified. Other putative phenotypic functions identified included resistance to mercury and other metal ions, as well as to quaternary ammonium compounds. The complexity and size of pWW0 is largely the result of the mosaic organization of the transposable elements that it carries, rather than the backbone functions of IncP-9 plasmids.     

Molecular diversity of plasmids bearing genes that encode toluene and xylene metabolism in Pseudomonas strains isolated from different contaminated sites in Belarus

Twenty different Pseudomonas strains utilizing m-toluate were isolated from oil-contaminated soil samples near Minsk, Belarus. Seventeen of these isolates carried plasmids ranging in size from 78 to about 200 kb (assigned pSVS plasmids) and encoding the meta cleavage pathway for toluene metabolism. Most plasmids were conjugative but of unknown incompatibility groups, except for one, which belonged to the IncP9 group. The organization of the genes for toluene catabolism was determined by restriction analysis and hybridization with xyl gene probes of pWW0. The majority of the plasmids carried xyl-type genes highly homologous to those of pWW53 and organized in a similar manner (M. T. Gallegos, P. A. Williams, and J. L. Ramos, J. Bacteriol. 179:5024-5029, 1997), with two distinguishable meta pathway operons, one upper pathway operon, and three xylS-homologous regions. All of these plasmids also possessed large areas of homologous DNA outside the catabolic genes, suggesting a common ancestry. Two other pSVS plasmids carried only one meta pathway operon, one upper pathway operon, and one copy each of xylS and xylR. The backbones of these two plasmids differed greatly from those of the others. Whereas these parts of the plasmids, carrying the xyl genes, were mostly conserved between plasmids of each group, the noncatabolic parts had undergone intensive DNA rearrangements. DNA sequencing of specific regions near and within the xylTE and xylA genes of the pSVS plasmids confirmed the strong homologies to the xyl genes of pWW53 and pWW0. However, several recombinations were discovered within the upper pathway operons of the pSVS plasmids and pWW0. The main genetic mechanisms which are thought to have resulted in the present-day configuration of the xyl operons are discussed in light of the diversity analysis carried out on the pSVS plasmids.