Plasmids for naphthalene biodegradation incompatible with IncP-2 and IncP-7 group plasmids

Fourteen conjugative naphthalene degradative plasmids have been classified by incompatibility. It is shown that the plasmids of IncP-9 group are characterized by the minor entry exclusion, with respect to the R plasmids belonging to IncP-2 or IncP-7 groups. On the other hand, the naphthalene degradative plasmids of incompatibility group P-7 exhibit a markedly pronounced entry exclusion, with respect to the R plasmids of the same incompatibility groups. Two naphthalene degradative plasmids reveal incompatibility with the reference plasmids of two Inc groups (P-2 and P-7). These plasmids control also resistance of bacterial cells to potassium tellurite, which is characteristic of the IncP-2 plasmids. Two other naphthalene degradative plasmids are capable of stable coexistence with the IncP-2, P-7 or P-9 reference plasmids.     

Nah plasmids of the IncP-9 group in natural Pseudomonas strains

Polymerase chain reaction studies showed that naphthalene-utilizing bacteria isolated from various localities of Belarus most often contained Nah plasmids of the P-9 incompatibility group and plasmids of indefinite systematics. The conventional incompatibility test and restriction enzyme analysis revealed three new IncP-9 subgroups: ζ, η, and IncP-9-like. In addition to the known nucleotide sequences of nahG and nahAc, two novel nahG variants were revealed by a restriction enzyme analysis of amplification products. An amplified rDNA restriction enzyme analysis (ARDRA) demonstrated that the native hosts of IncP-9 Nah plasmids were fluorescent bacteria of the genus Pseudomonas (P. fluorescens, P. putida, P. aeruginosa, and Pseudomonas sp.) and nonfluorescent bacteria of indefinite systematics.     

Organization and maintenance features of IncP-7 naphthalene degradation plasmid pFME5 basic replicon

A basic replicon of the naphthalene degradation plasmid pFME5 (80 kb, IncP-7) has been constructed and sequenced. The nucleotide sequence of pFME5mini is almost identical to replicons of the pND6-1 subgroup, which was separated based on the repA-oriV homology in our previous work. The basic replicon of pFME5 is capable of replication and stable maintenance exclusively in Pseudomonas species. An analysis of the deletion mutation indicated that, in contrast to the parWAB region, the parC gene is not essential for the stability of pFME5mini and this can be a common feature of IncP-7 replicons. We revealed that par-defective mutants of pFME5mini were slowly eliminated from the bacterial population in a nonselective medium compared to their pCAR1-based counterparts. Designed primers specific to the repA and parC genes can be used to detect IncP-7 plasmids, while primers specific to two variants of parA can be used for intragroup classification.     

Oxidation of dibenzofuran by Pseudomonas strains harboring plasmids of naphthalene degradation]

Pseudomonas strains harboring plasmids pBS3, pBS4, NAH7 were shown to carry out initial transformation of dibenzofurane to 4-[2'-(3'-hydroxy)-benzofuranyl]-2-keto-3-butenic acid due to broad substrate specificity of the enzymes of naphthalene catabolism nahA, nahB, nahC and nahD. These strains did not grow on dibenzofurane because of the inability of the enzyme nahE to split pyruvate of 4-[2'-(3' hydroxy)-benzofuranyl]-2-keto-3-butenic acid, which leads to accumulation of the latter. The strains harboring plasmids pBS2 and NPL-1 are not capable of any transformation of dibenzofurane.     

Spread and survival of promiscuous IncP-1 plasmids

Plasmids classified to the IncP-1 incompatibility group belong to the most stably maintained mobile elements among low copy number plasmids known to date. The remarkable persistence is achieved by various tightly controlled stability mechanisms like active partitioning, efficient conjugative transfer system, killing of plasmid-free segregants and multimer resolution. The unique feature of IncP-1 plasmids is the central control operon coding for global regulators which control the expression of genes involved in vegetative replication, stable maintenance and conjugative transfer. The multivalent regulatory network provides means for coordinated expression of all plasmid functions. The current state of knowledge about two fully sequenced plasmids RK2 and R751, representatives of the IncP-1alpha and IncP-1beta subgroups, is presented.     

Thermosensitivity of naphthalene biodegradation plasmids

The object of the work was to study the functional expression of naphthalene and salicylic acid catabolism systems and the stability of naphthalene biodegradation plasmids NAH, pBS2, pBS3 and NPL-41 in Pseudomonas aeruginosa PAO. The catabolic systems of the plasmids were shown to be thermosensitive, with a slight variation between one another. The plasmids became unstable at a high temperature; the temperature of effective elimination was 41 degrees C for plasmids NPL-41 and pBS3, and 42 degrees C for plasmids NAH and pBS2. NAH and pBS2 produced a weak inhibiting effect while NPL-41 and pBS3 caused a strong inhibition of the PAO strain growth at 42 degrees C. As a result, many anomalous filamentous cells (partly in the state of lysis) appeared in the cultural broth. Only PAO cells that had lost their plasmid were capable of normal growth in a medium with MPA at an elevated temperature; this creates a convenient system for selection of clones that have lost the plasmids of naphthalene biodegradation. Some of these plasmids can inhibit growth of Pseudomonas strains at an elevated temperature; this fact should be taken into account when the capability of Pseudomonas to grow at a high temperature is used as a taxonomic feature.     

Host-specific factors determine the persistence of IncP-1 plasmids

Conjugative plasmids play a very important role in bacterial adaptation through the dissemination of useful traits. Incompatibility group P-1 (IncP-1) plasmids exhibit an extreme broad-host-range among Gram-negative bacteria and known to be one of the major agents to disseminate various phenotypic traits such as antibiotic resistance and xenobiotic degradation. Although the plasmids are believed to be very stable in most Gram-negative bacteria, little is known about the factors that affect their stability in various hosts, allowing their persistence in bacterial population. Here we show that the stability of the cryptic IncP-1β plasmid pBP136 differed greatly in four different Escherichia coli K12 host backgrounds (MG1655, DH5α, EC100, and JM109), whereas the closely related plasmid pB10 was stable in all four strains. The supply of the kleF gene, which is involved in the stability of IncP-1 plasmids but absent in pBP136, did not improve the stability of the plasmid. Our findings suggest that persistence of IncP-1 plasmids in the absence of selection is affected by strain-specific factors.     

Evidence for past integration of IncP-1 plasmids into bacterial chromosomes

Plasmids of the IncP-1 incompatibility group are self-transmissible between and stably maintained in a very broad range of Gram-negative bacteria. A characteristic feature of IncP-1 genomes is the existence of multiple binding sites (OB) for the KorB protein which plays a dual role in active partitioning of plasmid and coordinate regulation of expression of genes for replication, maintenance and transfer. A search of the available bacterial genome sequences revealed a significant number (70 out of 322) with one or more putative KorB binding sites. Binding of KorB to such a site was demonstrated by chromatin immunoprecipitation (ChIP) for Pseudomonas putida KT2440. While such a site may arise by chance, this is unlikely for Pseudomonas aeruginosa UCBPP-PA14 whose genome sequence contains four clustered OB sites and several regions have more than 80% nucleotide identity to traJ, trbJ and trbL of IncP-1 plasmids. A number of other bacterial genomes also contain integrated partial IncP-1 genomes or their remnants. These data provide evidence for multiple past integration events of IncP-1 plasmids into bacterial chromosomes and provide new evidence for IncP-1 plasmids being important elements in gene mobility.     

Utilization of IncP-1 plasmids as vectors for transposon mutagenesis in myxobacteria

No free plasmid has ever been found in the myxobacterium Myxococcus xanthus, but IncP-1 plasmids are able to integrate into the chromosome of this bacterium. The frequency of integration depends greatly upon the structure of the IncP-1 plasmid used. This property has been used to devise new delivery systems for transposon mutagenesis in this species. Plasmids with low integration efficiencies have proved to be efficient donors of Tn5, while plasmids with very high frequencies of integration could be used directly to generate mutations. These vectors have also proved efficient for Tn5 transfer into other species of myxobacteria, which have not so far been susceptible to genetic analysis.     

Classification of IncP-7 plasmids based on structural diversity of their basic replicons

The structural diversity of basic replicons and repB gene was analyzed for the first time in a large collection of IncP-7 plasmids by PCR, restriction endonuclease analysis, and partial sequencing. It was found that the DNA fragment that contains the gene for UvrD-like helicase RepB is a part of all known P-7 replicons, but often acts as a hot insertion spot for different IS-elements. Based on the detected divergence of the repA-oriV-parWABC nucleotide sequence, the first system of P-7 plasmid classification has been proposed. Most degradation plasmids were classified in the β subgroup; the streptomycin resistance plasmid Rms148 (IncP-7 archetype) was placed into the α subgroup. The γ subgroup included the carbazole degradation plasmid pCAR1 and NAH/SAL-plasmids from the pY line (Yamal oil deposits), and the CAP plasmid pBS270 with a presumably reduced P-7 replicon was classified into a tentative δ subgroup. It was shown that, in most cases, the character of molecular organization of IncP-7 basic replicons did not correlate with particular phenotypic traits; that is, a given P-7 subgroup can include plasmids that encode different phenotypic markers.     

Broad-host-range plasmids from agricultural soils have IncP-1 backbones with diverse accessory genes

Broad-host-range plasmids are known to spread genes between distinct phylogenetic groups of bacteria. These genes often code for resistances to antibiotics and heavy metals or degradation of pollutants. Although some broad-host-range plasmids have been extensively studied, their evolutionary history and genetic diversity remain largely unknown. The goal of this study was to analyze and compare the genomes of 12 broad-host-range plasmids that were previously isolated from Norwegian soils by exogenous plasmid isolation and that encode mercury resistance. Complete nucleotide sequencing followed by phylogenetic analyses based on the relaxase gene traI showed that all the plasmids belong to one of two subgroups (β and ε) of the well-studied incompatibility group IncP-1. A diverse array of accessory genes was found to be involved in resistance to antimicrobials (streptomycin, spectinomycin, and sulfonamides), degradation of herbicides (2,4-dichlorophenoxyacetic acid and 2,4-dichlorophenoxypropionic acid), and a putative new catabolic pathway. Intramolecular transposition of insertion sequences followed by deletion was found to contribute to the diversity of some of these plasmids. The previous observation that the insertion sites of a Tn501-related element are identical in four IncP-1β plasmids (pJP4, pB10, R906, and R772) was further extended to three more IncP-1β plasmids (pAKD15, pAKD18, and pAKD29). We proposed a hypothesis for the evolution of these Tn501-bearing IncP-1β plasmids that predicts recent diversification followed by worldwide spread. Our study increases the available collection of complete IncP-1 plasmid genome sequences by 50% and will aid future studies to enhance our understanding of the evolution and function of this important plasmid family.     

Inheritance of IncP-9 Catabolic Plasmids in Pseudomonas Bacteria

Russian Journal of Genetics - This work investigated the capability of the conjugative transfer of epsilon-caprolactam biodegradation (CAP) plasmids, belonging to incompatibility (Inc) groups P-2,...     

IncP-1 R plasmids decrease the serum resistance and the virulence of Pseudomonas aeruginosa

Pseudomonas aeruginosa strain PAO1 was compared to PAO1 strains containing an IncP-1 R plasmid (RP1, R68, or R68.45) in an experimental mouse burn infection model. All R plasmids tested caused a 10- to 400-fold increase in mean lethal dose (LD50). The decrease in virulence produced by plasmids R68 and R68.45 was significantly greater than the decrease caused by the closely related plasmid RP1. All plasmids also led to an increased sensitivity of strain PAO1 to human serum bactericidal activity. Virulence and serum resistance of strain PAO1 were restored by curing of the entire plasmid R68.45 but not by deletions in the plasmid's transfer gene regions.     

Nah-plasmids of IncP-9 group from natural strains of Pseudomonas

Use of polymerase chain reaction helped to establish that the most frequent among naphthalene utilizing bacteria, isolated on the territory of Belarus, are Nah-plasmids of IncP-9 incompatibility group and those with indefinite systematic belonging. With the help of classical test of incompatibility, restriction and sequence analyses three new subgroups within the IncP-9 group were discovered (zeta, eta and IncP-9-like replicons). Conducting of restriction analysis for amplification products of nahG and nahAc genes allowed us to reveal, in addition to known sequences of stated determinants, two new types of nahG gene. Restriction analysis performed on amplification products of 16S RNA genes (ARDRA method) showed that native hosts of Nah-plasmids of IncP-9 group are not only fluorescent bacteria from genus Pseudomonas (P. fluorescens, P. putida, P. aeruginosa, P. species), but also non-fluorescent bacteria with indefinite specific belonging.     

Increased abundance of IncP-1beta plasmids and mercury resistance genes in mercury-polluted river sediments: first discovery of IncP-1beta plasmids with a complex mer transposon as the sole accessory element

Although it is generally assumed that mobile genetic elements facilitate the adaptation of microbial communities to environmental stresses, environmental data supporting this assumption are rare. In this study, river sediment samples taken from two mercury-polluted (A and B) and two nonpolluted or less-polluted (C and D) areas of the river Nura (Kazakhstan) were analyzed by PCR for the presence and abundance of mercury resistance genes and of broad-host-range plasmids. PCR-based detection revealed that mercury pollution corresponded to an increased abundance of mercury resistance genes and of IncP-1beta replicon-specific sequences detected in total community DNA. The isolation of IncP-1beta plasmids from contaminated sediments was attempted in order to determine whether they carry mercury resistance genes and thus contribute to an adaptation of bacterial populations to Hg pollution. We failed to detect IncP-1beta plasmids in the genomic DNA of the cultured Hg-resistant bacterial isolates. However, without selection for mercury resistance, three different IncP-1beta plasmids (pTP6, pTP7, and pTP8) were captured directly from contaminated sediment slurry in Cupriavidus necator JMP228 based on their ability to mobilize the IncQ plasmid pIE723. These plasmids hybridized with the merRTDeltaP probe and conferred Hg resistance to their host. A broad host range and high stability under conditions of nonselective growth were observed for pTP6 and pTP7. The full sequence of plasmid pTP6 was determined and revealed a backbone almost identical to that of the IncP-1beta plasmids R751 and pB8. However, this is the first example of an IncP-1beta plasmid which had acquired only a mercury resistance transposon but no antibiotic resistance or biodegradation genes. This transposon carries a rather complex set of mer genes and is inserted between Tra1 and Tra2.     

Roles of long and short replication initiation proteins in the fate of IncP-1 plasmids

Broad-host-range IncP-1 plasmids generally encode two replication initiation proteins, TrfA1 and TrfA2. TrfA2 is produced from an internal translational start site within trfA1. While TrfA1 was previously shown to be essential for replication in Pseudomonas aeruginosa, its role in other bacteria within its broad host range has not been established. To address the role of TrfA1 and TrfA2 in other hosts, efficiency of transformation, plasmid copy number (PCN), and plasmid stability were first compared between a mini-IncP-1β plasmid and its trfA1 frameshift variant in four phylogenetically distant hosts: Escherichia coli, Pseudomonas putida, Sphingobium japonicum, and Cupriavidus necator. TrfA2 was sufficient for replication in these hosts, but the presence of TrfA1 enhanced transformation efficiency and PCN. However, TrfA1 did not contribute to, and even negatively affected, long-term plasmid persistence. When trfA genes were cloned under a constitutive promoter in the chromosomes of the four hosts, strains expressing either both TrfA1 and TrfA2 or TrfA1 alone, again, generally elicited a higher PCN of an IncP1-β replicon than strains expressing TrfA2 alone. When a single species of TrfA was produced at different concentrations in E. coli cells, TrfA1 maintained a 3- to 4-fold higher PCN than TrfA2 at the same TrfA concentrations, indicating that replication mediated by TrfA1 is more efficient than that by TrfA2. These results suggest that the broad-host-range properties of IncP-1 plasmids are essentially conferred by TrfA2 and the intact replication origin alone but that TrfA1 is nonetheless important to efficiently establish plasmid replication upon transfer into a broad range of hosts.     

Molecular structure of bacterial plasmids

[This corrects the article on p. 369 in vol. 36.].     

DNA recognition by the KorA proteins of IncP-1 plasmids RK2 and R751

The KorA repressor proteins of IncP-1 plasmids belong to a growing family of plasmid-encoded repressors that regulate partitioning genes, and in the IncP-1 plasmids coordinate these with expression of replication and transfer genes as well. Both KorA(RK2) (IncP-1 alpha) and KorA(R751) (IncP-1 beta) recognise the 5'-GTTTAGCTAAAC-3' palindrome. Reporter gene assays showed that KorA proteins from these two main subgroups of IncP-1 plasmids show specificity for their own promoter/operators and this preference was confirmed with in vitro binding studies using gel mobility shift assays on one representative promoter. Class I (high affinity) operators for KorA(RK2) are flanked by an A-A-A/T sequence in the upstream half; the T base was shown to greatly influence strong repression. A C-A-G triplet was present in the same region in the R751 O(A) sequences and the G base was accordingly found to be important for strong KorA(R751) repression. An obvious difference between the two KorA proteins is a histidine to serine change at the C-proximal end of the putative recognition helix of the HTH motif (aa 56). An IncP-1 alpha KorAH56S mutant protein had higher affinity for all operators but had improved more on R751 operators than on RK2 operators. This indicates that KorA of RK2 is not maximised for DNA binding activity and that the aa difference at position 56 may play a role in differentiation between alpha and beta KorA operators.