The aadA Gene of Plasmid R100 Confers Resistance to Spectinomycin and Streptomycin in Myxococcus xanthus

Plasmids with the aadA gene from plasmid R100, which confers resistance to the aminoglycosides spectinomycin and streptomycin in Escherchia coli, can be introduced into wild-type Myxococcus xanthus, strain DK1622, by electroporation. Recombinant M. xanthus strains with integrated plasmids carrying the aadA gene acquire resistance to high levels of these antibiotics. Selection for aadA in M. xanthus can be carried out independently of, or simultaneously with, selection for resistance to kanamycin. The kinds and frequencies of recombination events observed between integrative plasmids with aadA and the M. xanthus chromosome are similar to those observed after the transformation of yeast. Cleavage of integrative plasmid DNA at a site adjacent to a region of homology between the plasmid and the M. xanthus genome favors the targeted disruption of M. xanthus genes by allele replacement.     

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.     

The genetic organization and evolution of the broad host range mercury resistance plasmid pSB102 isolated from a microbial population residing in the rhizosphere of alfalfa

Employing the biparental exogenous plasmid isolation method, conjugative plasmids conferring mercury resistance were isolated from the microbial community of the rhizosphere of field grown alfalfa plants. Five different plasmids were identified, designated pSB101–pSB105. One of the plasmids, pSB102, displayed broad host range (bhr) properties for plasmid replication and transfer unrelated to the known incompatibility (Inc) groups of bhr plasmids IncP-1, IncW, IncN and IncA/C. Nucleotide sequence analysis of plasmid pSB102 revealed a size of 55 578 bp. The transfer region of pSB102 was predicted on the basis of sequence similarity to those of other plasmids and included a putative mating pair formation apparatus most closely related to the type IV secretion system encoded on the chromosome of the mammalian pathogen Brucella sp. The region encoding replication and maintenance functions comprised genes exhibiting different degrees of similarity to RepA, KorA, IncC and KorB of bhr plasmids pSa (IncW), pM3 (IncP-9), R751 (IncP-1β) and RK2 (IncP-1α), respectively. The mercury resistance determinants were located on a transposable element of the Tn5053 family designated Tn5718. No putative functions could be assigned to a quarter of the coding capacity of pSB102 on the basis of comparisons with database entries. The genetic organization of the pSB102 transfer region revealed striking similarities to plasmid pXF51 of the plant pathogen Xylella fastidiosa.     

Inheritance of biodegradation plasmids in the cells of homo- and heterologous hosts

A systematic analysis of the inheritance of D plasmids of the IncP-9 group (α-, β-, γ-, δ-, ?-, ζ-, η-, and θ-subgroups), IncP-7, as well as of those of undefined systematic affiliation in the cells of homologous (Pseudomonas putida) and heterologous (Escherichia coli) hosts was performed for the first time. For this purpose, mini-Tn5 transposons determining resistance to kanamycin (or streptomycin) were introduced into all the D plasmids under study. It has been established that all IncP-9 plasmids can be transmitted to the cells of a heterologous host E. coli (with the exception of plasmid pSVS15 from gq-subgroup). IncP-7 plasmids and those of undefined systematic affiliation do not possess this property and can be transmitted and stably inherited only in P. putida. The distinctive feature of most IncP-9 plasmids (α-, β-, δ-, ?-, and ζ-subgroups) is strict dependence of their inheritance on the temperature factor. At 37°C, the plasmids of δ-, ζ-, and θ-subgroups are unstable in P. putida cells, while in E. coli nearly all plasmids of this systematic group are unstable. The exceptions are the plasmids of η- and γ-subgroups. Inheritance of these plasmids does not depend on temperature. At 28°C and 37°C, the η plasmid is not maintained stably (inheritance stability is 2%), while the γ-plasmid has almost 100% stability.     

Sequencing and comparative analysis of IncP-1α antibiotic resistance plasmids reveal a highly conserved backbone and differences within accessory regions

Although IncP-1 plasmids are important for horizontal gene transfer among bacteria, in particular antibiotic resistance spread, so far only three plasmids from the subgroup IncP-1α have been completely sequenced. In this study we doubled this number. The three IncP-1α plasmids pB5, pB11 and pSP21 were isolated from bacteria of two different sewage treatment plants and sequenced by a combination of next-generation and capillary sequencing technologies. A comparative analysis including the previously analysed IncP-1α plasmids RK2, pTB11 and pBS228 revealed a highly conserved plasmid backbone (at least 99.9% DNA sequence identity) comprising 54 core genes. The accessory elements of the plasmid pB5 constitute a class 1 integron interrupting the parC gene and an IS6100 copy inserted into the integron. In addition, the tetracycline resistance genes tetAR and the ISTB11-like element are located between the klc operon and the trfA-ssb operon. Plasmid pB11 is loaded with a Tn5053-like mercury resistance transposon between the parCBA and parDE operons and contains tetAR that are identical to those identified in plasmid pB5 and the insertion sequence ISSP21. Plasmid pSP21 harbours an ISPa7 element in a Tn402 transposon including a class 1 integron between the partitioning genes parCBA and parDE. The IS-element ISSP21 (99.89% DNA sequence identity to ISSP21 from pB11), inserted downstream of the tetR gene and a copy of ISTB11 (identical to ISTB11 on pTB11) inserted between the genes pncA and pinR. On all three plasmids the accessory genes are almost always located between the backbone modules confirming the importance of the backbone functions for plasmid maintenance. The striking backbone conservation among the six completely sequenced IncP-1α plasmids is in contrast to the much higher diversity within the IncP-1β subgroup.     

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.     

Mechanism of integration of the broad-host-range plasmid RP4 into the chromosome of Myxococcus xanthus

The site-specific recombination mechanism through which the plasmid RP4 has been previously shown to integrate into the chromosome of Myxococcus xanthus has been investigated further. Once integrated in one of the numerous chromosomal sites from two different strains, through a precise site on the plasmid, the latter can be excised either precisely or after a definite 14.5-kb deletion. In some cases, the integration is followed by different DNA rearrangements that yield a higher rate of excision and integration. A model for the site-specific integration and excision of the plasmid is proposed.     

Conjugative Transfer Facilitates Stable Maintenance of IncP-1 Plasmid pKJK5 in Escherichia coli Cells Colonizing the Gastrointestinal Tract of the Germfree Rat

Quantitative determination of IncP-1 plasmid loss from Escherichia coli cells colonizing the gastrointestinal tracts of germfree rats was achieved by flow cytometry. Results show that the plasmid's ability to conjugate counteracts plasmid loss and is thus an important mechanism for the stable maintenance of IncP-1 plasmids within the gastrointestinal environment.     

Shifts in Abundance and Diversity of Mobile Genetic Elements after the Introduction of Diverse Pesticides into an On-Farm Biopurification System over the Course of a Year

Biopurification systems (BPS) are used on farms to control pollution by treating pesticide-contaminated water. It is assumed that mobile genetic elements (MGEs) carrying genes coding for enzymes involved in degradation might contribute to the degradation of pesticides. Therefore, the composition and shifts of MGEs, in particular, of IncP-1 plasmids carried by BPS bacterial communities exposed to various pesticides, were monitored over the course of an agricultural season. PCR amplification of total community DNA using primers targeting genes specific to different plasmid groups combined with Southern blot hybridization indicated a high abundance of plasmids belonging to IncP-1, IncP-7, IncP-9, IncQ, and IncW, while IncU and IncN plasmids were less abundant or not detected. Furthermore, the integrase genes of class 1 and 2 integrons (intI1, intI2) and genes encoding resistance to sulfonamides (sul1, sul2) and streptomycin (aadA) were detected and seasonality was revealed. Amplicon pyrosequencing of the IncP-1 trfA gene coding for the replication initiation protein revealed high IncP-1 plasmid diversity and an increase in the abundance of IncP-1β and a decrease in the abundance of IncP-1ε over time. The data of the chemical analysis showed increasing concentrations of various pesticides over the course of the agricultural season. As an increase in the relative abundances of bacteria carrying IncP-1β plasmids also occurred, this might point to a role of these plasmids in the degradation of many different pesticides.     

Structural instability of IncP-1 plasmids in Pseudomonas aeruginosa PAT involves interaction with plasmid pVS1

The structural instability exhibited by IncP-1 plasmids in Pseudomonas aeruginosa strain PAT was shown to be Rec+ dependent and involved interaction with the resident plasmid pVS1. Structural instability resulted from deletion of plasmid deoxyribonucleic acid at a frequency of ca. 10(-2)/cell per generation. Deletants could be stabilized by transduction into P. aeruginosa strain PAO, but in strain PAT deletants had only a transient existence, as continued deletion led eventually to the loss of the entire plasmid. The patterns of markers lost in PAT were used to demonstrate a marker order for R68 similar to that published elsewhere for RP4 (Barth and Grinter, J. Mol. Biol. 113:455-474, 1977), except that only one Tra region was found. R68 also exhibited Rec+-dependent structural instability in PAO(pVS1) derivatives but, unlike the case in PAT, instability was not accompanied by chromosome mobilization. We isolated deletants of pVS1 which were unable to promote structural instability.     

IS21 insertion in the trfA replication control gene of chromosomally integrated plasmid RP1: a property of stable Pseudomonas aeruginosa Hfr strains

Summary Broad host range IncP-1 plasmids are able to integrate into the chromosome of gram-negative bacteria. Strains carrying an integrated plasmid can be obtained when the markers of a temperature-sensitive (ts) plasmid derivative are selected at non-permissive temperature; in this way Hfr (high frequency) donor strains can be formed. The integrated plasmids, however, tend to be unstable in the absence of continuous selective pressure. In order to obtain stable Hfr donor strains of Pseudomonas aeruginosa PAO, we constructed a derivative of an RP1 (ts) plasmid, pME134, which was defective in the resolvase gene (tnpR) of transposon Tn801. Chromosomal integration of pME134 was selected in a recombination-deficient (rec-102) PAO strain at 43°C. Plasmid integration occurred at different sites resulting in a useful set of Hfr strains that transferred chromosomal markers unidirectionally. The tnpR and rec-102 mutations prevented plasmid excision from the chromosome. In several (but not all) Hfr strains that grew well and retained the integrated plasmid at temperatures below 43°C, the insertion element IS21 of RP1 was found to be inserted into the trfA locus (specifying an essential trans-acting replication funtion) of the integrated plasmid. One such Hfr strain was rendered rec ⁺; from its chromosome the pME134::IS21 plasmid (=pME14) was excised and transferred by conjugation to Escherichia coli where pME14 could replicate autonomously only when a helper plasmid provided the trfA ⁺ function in trans. Thus, it appears that trfA inactivation favours the stability of chromosomally integrated RP1 in P. aeruginosa.     

Mode of insertion of the broad-host-range plasmid RP4 and its derivatives into the chromosome of Myxococcus xanthus

The mode of insertion of the broad-host-range plasmid RP4 into the chromosome of Myxococcus xanthus strain DZ1 has been analyzed. The plasmid integrated in numerous sites of the chromosome and generated insertional mutations. There is a hot spot of integration located between 31.5 and 34.5 kb clockwise from the EcoRI site of the plasmid. In the absence of this segment the insertion can, however, take place, but much less efficiently. The presence of transposable elements on the plasmid decreases severely the insertion frequency. Once integrated, RP4 could be transferred back to Escherichia coli, either by precise excision or with a segment of the Myxococcus chromosome. The role of site-specific recombination in RP4 integration is discussed.     

Region-specific insertion of transposons in combination with selection for high plasmid transferability and stability accounts for the structural similarity of IncP-1 plasmids

The overall architecture of IncP-1 plasmids is very conserved in that the accessory genes are typically located in one or two specific regions: between oriV and trfA and between the tra and trb operons. Various hypotheses have been formulated to explain this, but none have been tested experimentally. We investigated whether this structural similarity is due to region-specific transposition alone or also is reliant on selection for plasmids with insertions limited to these two regions. We first examined the transposition of Tn21Km into IncP-1beta plasmid pBP136 and found that most Tn21Km insertions (67%) were located around oriV. A similar experiment using the oriV region of IncP-1beta plasmid pUO1 confirmed these results. We then tested the transferability, stability, and fitness cost of different pBP136 derivatives to determine if impairment of these key plasmid characters explained the conserved plasmid architecture. Most of the pBP136 derivatives with insertions in transfer genes were no longer transferable. The plasmids with insertions in the oriV-trfA and tra-trb regions were more stable than other plasmid variants, and one of these also showed a significantly lower fitness cost. In addition, our detailed sequence analysis of IncP-1 plasmids showed that Tn402/5053-like transposons are situated predominantly between the tra and trb operons and close to the putative resolution site for the ParA resolvase, a potential hot spot for those transposons. Our study presents the first empirical evidence that region-specific insertion of transposons in combination with selection for transferable and stable plasmids explains the structural similarity of IncP-1 plasmids.     

The multiple antibiotic resistance IncP-1 plasmid pKJK5 isolated from a soil environment is phylogenetically divergent from members of the previously established alpha, beta and delta sub-groups

The 54,383bp plasmid pKJK5 was recovered from a soil environment by exogenous plasmid isolation and conveys resistance towards tetracycline and trimethoprim. Sequencing and annotation revealed a high level of structural similarity of the backbone genes to other IncP-1 plasmids containing a Tra1 and Tra2 region, a central control module and a replication initiation module. A considerable degree of divergence was associated with the backbone genes of pKJK5 as compared to homologous genes in the alpha, beta and delta subgroups, which indicates that pKJK5 may belong to a novel subgroup of IncP-1 plasmids, which may also accommodate the partially sequenced non-subgroup classified plasmid pEMT3. Individual backbone genes in pKJK5 have a GC-content, which is consistently lower (average 6.3%) than the homologous genes from the archetype IncP-1beta plasmid R751 indicating homogenous amelioration of IncP-1 plasmid backbone genes. Two discrete accessory elements of 2145bp (load 1) and 11678bp (load 2) respectively are situated between the Tra1 and Tra2 regions of pKJK5, both bounded by inverted repeats and direct flanking repeats indicative of transposon-mediated insertion. Load 1 consists of an insertion sequence ISPa17 and load 2 is a Tn402-derivative containing a class 1 integron, IS1326 and a fragment identical to a region of plasmid pTB11 harboring a tetracycline resistance determinant and part of an IncP-1alphaoriV region.     

Increased Abundance of IncP-1β Plasmids and Mercury Resistance Genes in Mercury-Polluted River Sediments: First Discovery of IncP-1β 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-1β replicon-specific sequences detected in total community DNA. The isolation of IncP-1β 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-1β plasmids in the genomic DNA of the cultured Hg-resistant bacterial isolates. However, without selection for mercury resistance, three different IncP-1β 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 merRTΔP 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-1β plasmids R751 and pB8. However, this is the first example of an IncP-1β 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.     

Genetics of gliding motility in Myxococcus xanthus: Molecular cloning of the mgl locus

Summary Wild-type Myxococcus xanthus cells move across solid surfaces by gliding. However no locomotory organelles for gliding have as yet been identified. Two sets of genes are required for gliding in M. xanthus: Gene System A is necessary for the gliding of isolated cells and Gene System S comes into play when cells are close together. The product of the mgl locus is required for both types of gliding and therefore may be a structural component of the gliding organelle. To begin to investigate the function of mgl in gliding a 12 kb segment of M. xanthus DNA containing the locus was cloned in Escherichia coli and returned to Myxococcus by specialized transduction with coliphage P1. In M. xanthus the chimeric plasmid integrates into the chromosome by recombination between the cloned segment and its homolog in the recipient chromosome forming a tandem duplication of the cloned segment with the vector sequences at the novel joint. The construction of partial diploids in this manner facilitated dominance tests and interallelic crosses with ten mgl alleles. We also describe a method for the analysis of tandem duplications that precisely maps alleles to a specific copy of the duplicated sequences. This method provides evidence for the dominance of mgl ⁺ over the mgl ^- alleles. It also reveals what appears to be gene conversion at this locus during recombination between a cloned mgl sequence and its homolog in the chromosome.     

Sequence of the 68,869 bp IncP-1α plasmid pTB11 from a waste-water treatment plant reveals a highly conserved backbone, a Tn402-like integron and other transposable elements

To analyse the significance of conjugative broad-host-range IncP-1α plasmids for the spread of antibiotic resistance determinants in waste-water treatment plants we isolated and characterised five different IncP-1α plasmids from bacteria of activated sludge and the final effluents of a municipal waste-water treatment plant. These plasmids mediate resistance to ampicillin, cefaclor, cefuroxime, gentamicin, kanamycin, spectinomycin, streptomycin, tetracycline, tobramycin, and trimethoprim. The complete 68,869 bp DNA-sequence of the IncP-1α plasmid pTB11 was determined. The pTB11 backbone modules for replication (Rep), mating pair formation (Trb), multimer resolution (Mrs), post-segregational killing (Psk), conjugative DNA-transfer (Tra), plasmid control (Ctl), and stable maintenance and inheritance (KilA, KilE, and KilC) are highly conserved as compared to the ‘Birmingham’ IncP-1α plasmids. In contrast to the ‘Birmingham’ plasmids pTB11 carries an insert of a Tn402-derivative integrating a class 1 integron in the intergenic region between the multimer resolution operon parCBA and the post-segregational killing operon parDE. The integron comprises the resistance gene cassettes oxa2 (β-lactamase), aacA4 (aminoglycoside-6′N-acetyltransferase), and aadA1 (aminoglycoside-3′-adenylyltransferase) and a complete tniABQR transposition module. Integron-specific sequences were also identified on other IncP-1α plasmids analysed in this work. In contrast to the ‘Birmingham’ plasmids the pTB11 tetracycline resistance module carries a pecM- and a pncA-like gene downstream of the tetracycline resistance gene tetA and contains an insertion of the new insertion sequence element ISTB11. The transposable elements IS21 and Tn1 which disrupted, respectively, orf7 and klcB on the ‘Birmingham’ plasmids are not present on pTB11. Identification of IncP-1α plasmids in bacteria of the waste-water treatment plant’s final effluents indicates that bacteria carrying these kind of plasmids are released into the environment.     

Plasmids that mobilize bacterial chromosome

Cma can now be accepted as a common property of plasmids rather than one limited to a few, intensively studied examples. The mechanisms by which plasmids mobilize chromosome, in particular the role of plasmid integration into the bacterial chromosome and the part played by insertion sequences, are areas to which future interest should be directed. Solutions to these problems will be instructive in our understanding of plasmid and bacterial chromosome structure and function. The role of the IncP-1 plasmids can be expected to be central to this future work.The wide variety of bacterial genera for which conjugational analysis, mapping, and recombinant isolation are now available has extended microbial genetics into new areas. These advances are promising for the solution of a variety of practical problems in medicine, agriculture, and environmental science in the foreseeable future.     

Selection of initiation replication system mutants of IncP-9 plasmid pBS267

A minireplicon containing the rep gene and oriV site of the γ subgroup of the IncP-9 caprolactam pBS267 biodegradation plasmid was cloned for the first time. It was established that a minimized variant of pBS267 plasmid cannot be sustained in E. coli and is inherited in an unstable way in bacteria Pseudomonas. Using in vitro mutagenesis, mutant variants of the minireplicon were produced, characterized by an increased number of copies in cells, the ability to replicate in E. coli, and relatively stable inheritance in P. putida cells. The obtained constructs are the basis for a study of the replication mechanisms of IncP-9 group plasmids, as well as use as vectors for molecular cloning in a wide range of gram-negative bacteria.     

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.