PLASMIDS AND EVOLUTIONARY RESCUE BY DRUG RESISTANCE

Antibiotic resistance provides evolutionary rescue for bacterial populations under the threat of extinction through antibiotics. It can arise de novo through mutation in the population, or be obtained from other bacterial populations via the transfer of a resistance‐conferring plasmid. We use stochastic modeling methods to establish whether the most likely source of rescue is via a plasmid or via the chromosome, and show that contrary to what is assumed plasmids are not necessarily beneficial locations for resistance genes. Competition at the plasmid level of selection is of great importance—the spread of a resistant plasmid in the population can be slowed or entirely stopped by a nonresistant version of the same plasmid. We suggest that future studies on antibiotic‐resistant plasmids should explicitly consider competition at this level of selection.     

Incorporation of the ampicillin resistance transposon into the Escherichia coli K-12 chromosome and into plasmids]

The mutant pEG1 of R-factor RP4 with temperature-sensitive defect in replication, carrying a transposable ampicillin resistance element Tn1 was used to define the frequency of insertion of this element into Escherichia coli K-12 chromosome and some other plasmids. Our results indicate that the frequency of colony forming by bacteria with pEG1-factor on ampicillin medium in non-permissive conditions corresponds to the frequency of Tn1 insertion into bacterial chromosome or some other plasmid (in case when the strains are carrying a second plasmid). The frequency of Tn1 insertion into the chromosome is about 4.10(-4). The defect in recA gene produce no serious change in the frequency of Tn1 insertion into the bacterial chromosome. The translocation of Tn1 element from pEG1-factor to R483, R6 and ColE1 plasmids occurs at 10 to 100-fold-higher frequency than from the plasmid to the chromosome. The insertion of Tn1 into the F'-factor KLF10 and R-factor R64-11 occurs at far lower frequency than that to plasmids R6, R483, or ColE1.     

Plasmids captured in <Emphasis Type="Italic">C</Emphasis>. <Emphasis Type="Italic">metallidurans</Emphasis> CH34: defining the PromA family of broad-host-range plasmids

The self-transmissible, broad-host-range (BHR) plasmid pMOL98 was previously isolated from polluted soil using a triparental plasmid capture approach and shown to possess a replicon similar to that of the BHR plasmids pSB102 and pIPO2. Here, complete sequence analysis and comparative genomics reveal that the 55.5 kb nucleotide sequence of pMOL98 shows extensive sequence similarity and synteny with the BHR plasmid family that now includes pIPO2, pSB102, pTER331, and pMRAD02. They share a plasmid backbone comprising replication, partitioning and conjugative transfer functions. Comparison of the variable accessory regions of these plasmids shows that the majority of natural transposons, as well as the mini-transposon used to mark the plasmids, are inserted in the parA locus. The transposon unique to pMOL98 appears to have inserted from the chromosome of the recipient strain used in the plasmid capture procedure. This demonstrates the necessity for careful screening of plasmids and host chromosomes to avoid mis-interpretation of plasmid genome content. The presence of very similar BHR plasmids with different accessory genes in geographically distinct locations suggests an important role in horizontal gene exchange and bacterial adaptation for this recently defined plasmid group, which we propose to name “PromA”. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Positive epistasis between co-infecting plasmids promotes plasmid survival in bacterial populations

Plasmids have a key role in the horizontal transfer of genes among bacteria. Although plasmids are catalysts for bacterial evolution, it is challenging to understand how they can persist in bacterial populations over the long term because of the burden they impose on their hosts (the ‘plasmid paradox''). This paradox is especially perplexing in the case of ‘small'' plasmids, which are unable to self-transfer by conjugation. Here, for the first time, we investigate how interactions between co-infecting plasmids influence plasmid persistence. Using an experimental model system based on interactions between a diverse assemblage of ‘large'' plasmids and a single small plasmid, pNI105, in the pathogenic bacterium Pseudomonas aeruginosa, we demonstrate that positive epistasis minimizes the cost associated with carrying multiple plasmids over the short term and increases the stability of the small plasmid over a longer time scale. In support of these experimental data, bioinformatic analysis showed that associations between small and large plasmids are more common than would be expected owing to chance alone across a range of families of bacteria; more generally, we find that co-infection with multiple plasmids is more common than would be expected owing to chance across a wide range of bacterial phyla. Collectively, these results suggest that positive epistasis promotes plasmid stability in bacterial populations. These findings pave the way for future mechanistic studies aimed at elucidating the molecular mechanisms of plasmid–plasmid interaction, and evolutionary studies aimed at understanding how the coevolution of plasmids drives the spread of plasmid-encoded traits.     

Development of broad-host-range vectors and gene banks: self-cloning of the Pseudomonas aeruginosa PAO chromosome.

A host-vector system for Pseudomonas aeruginosa PAO was developed. Scattered regions of the strain PAO chromosome were cloned by direct selection for complementation of auxotrophs or from a DNA gene bank which contains over 1,000 independently isolated chromosome-vector recombinant plasmids. The use of partially digested chromosomal DNA facilitated the selection of a variety of strain PAO chromosomal markers. The progenitor of the vector was a small, multicopy plasmid, pRO1600, found in a PAO strain which had acquired RP1 in a mating experiment. The bacterial host range that could be determined by transformation of vectors produced from pRO1600 resembles that for plasmid RP1. Two derivative plasmids were formed: pRO1613, for cloning DNA cleaved with restriction endonuclease PstI, and pRO1614, which was formed by deleting part of pRO1613 and fusion with plasmid pBR322. Plasmid pRO1614 utilizes known cloning sites within the tetracycline resistance region of pBR322.     

Genetic system for reversible integration of DNA constructs and lacZ gene fusions into the Escherichia coli chromosome

A plasmid system for site-specific integration into and excision and recovery of gene constructs and lacZ gene fusions from the Escherichia coli chromosome was developed. Plasmid suicide vectors utilizing the origin of replication of R6K plasmids and containing the attP sequence of bacteriophage lambda, multiple cloning site, and antibiotic resistance markers facilitate reversible integration into the E. coli chromosome by site-specific recombination. Additional vectors permit construction of lacZ gene fusions in three possible reading frames for recombination with the bacterial chromosome. These suicide vectors can be propagated in newly constructed E. coli strains that harbor different pir alleles. Two helper plasmids that encode the necessary gene products for integration (Int) and excision (Int and Xis) were also constructed. This plasmid system was shown to be a reliable and efficient means to integrate and subsequently recover plasmids from the E. coli attB site.     

Exploring the evolutionary dynamics of plasmids: the <Emphasis Type="Italic">Acinetobacter</Emphasis> pan-plasmidome

Background  

Prokaryotic plasmids have a dual importance in the microbial world: first they have a great impact on the metabolic functions of the host cell, providing additional traits that can be accumulated in the cell without altering the gene content of the bacterial chromosome. Additionally and/or alternatively, from a genome perspective, plasmids can provide a basis for genomic rearrangements via homologous recombination and so they can facilitate the loss or acquisition of genes during these events, which eventually may lead to horizontal gene transfer (HGT). Given their importance for conferring adaptive traits to the host organisms, the interest in plasmid sequencing is growing and now many complete plasmid sequences are available online.     

Rhizobial plasmids — replication,structure and biological role

Soil bacteria, collectively named rhizobia, can establish mutualistic relationships with legume plants. Rhizobia often have multipartite genome architecture with a chromosome and several extrachromosomal replicons making these bacteria a perfect candidate for plasmid biology studies. Rhizobial plasmids are maintained in the cells using a tightly controlled and uniquely organized replication system. Completion of several rhizobial genome-sequencing projects has changed the view that their genomes are simply composed of the chromosome and cryptic plasmids. The genetic content of plasmids and the presence of some important (or even essential) genes contribute to the capability of environmental adaptation and competitiveness with other bacteria. On the other hand, their mosaic structure results in the plasticity of the genome and demonstrates a complex evolutionary history of plasmids. In this review, a genomic perspective was employed for discussion of several aspects regarding rhizobial plasmids comprising structure, replication, genetic content, and biological role. A special emphasis was placed on current post-genomic knowledge concerning plasmids, which has enriched the view of the entire bacterial genome organization by the discovery of plasmids with a potential chromosome-like role.     

Integration and amplification of plasmid DNA in the Bacillus subtilis chromosome

Some Bacillus subtilis strains demonstrate a high degree of pHV14 and pP1251 plasmid integration into the chromosome (1.10(-1]. According to the data of genetical analysis the plasmids are integrated into several regions of the same chromosome. A significant plasmid amplification in the composition of chromosome is observed when breeding on an increasing chloramphenicol concentration (20-300 micrograms/ml). Both tandem repetitions and single plasmid DNA copies and their fragments are found in the bacterial chromosomal DNA.     

A plasmid vector allowing positive selection of recombinant plasmids in Streptococcus pneumoniae

A new plasmid, pSP2, was constructed as a cloning vector for use in Streptococcus pneumoniae. It allows direct selection of recombinant plasmids, even for DNA fragments not homologous to the S. pneumoniae chromosome, as based on the failure to maintain long inverted repeats (LIRs) hyphen-free in bacterial plasmids. Plasmid pSP2 contains a 1.4-kb BamHI fragment ("hyphen") flanked by 1.9-kb LIRs. The removal of the 1.4-kb BamHI fragment followed by ligation creates a plasmid containing a 1.9-kb insert-free LIR; plasmids with such non-hyphenated LIRs were not established when transferred into S. pneumoniae. Replacement of the original 1.4-kb insert by other restriction fragments restored plasmid viability. Investigation of plasmid transfer by transformation suggests that intrastrand synapsis between the LIRs could occur, thus facilitating plasmid establishment (a process we call self-facilitation). Such an intrastrand synapsis could also account for rare occurrences of insert-inversion noticed upon transfer as well as for the formation of palindrome-deleted derivatives at low frequency. Plasmid pSP2 carries two selectable genes, tet and ermC, and can be used for cloning of fragments produced by a variety of restriction enzymes (BamHI, Bg/II, Bc/I or Sau3A, and Sa/I or XhoI).     

Infectious plasmid resistance and efflux pump mediated resistance

Various bacterial plasmids can be eliminated from bacterial species cultured as pure or mixed bacterial cultures by non-mutagenic heterocyclic compounds at subinhibitory concentrations. For plasmid curing, the replication should be inhibited at three different levels simultaneously: the intracellular replication of plasmid DNA, partition and intercellular transconjugal transfer. The antiplasmid action of the compounds depends on the chemical structure. The targets for antiplasmid compounds were analysed in detail. It was found that amplified extrachromosomal DNA in the superhelical state binds more drug molecules than does the linear or open-circular form of the plasmid or the chromosome, without stereospecificity which leads to functional inactivation of the extrachromosomal genetic code. Plasmid elimination also occurs in ecosystems containing numerous bacterial species simultaneously, but the elimination of antibiotic resistance-encoding plasmids from all individual cells of the population is never complete. The medical significance of plasmid elimination in vitro is, it provides a method to isolate plasmid-free bacteria for biotechnology without any risk of mutations, and it opens up a new perspective in rational drug design against bacterial plasmids. Hypothetically, the combination of antiplasmid drugs and antibiotics may improve the effectivity of antibiotics against resistant bacteria; therefore, the results cannot be exploited until the curing efficiency reaches 100%. Inhibition of the conjugational transfer of antibiotic resistance plasmids can be exploited to reduce the spreading of these plasmids in ecosystems.     

Construction of plasmids integrating into the Bacillus subtilis chromosome through homologous recombination and their use as integration vectors

We constructed a number of plasmids which integrate into the chromosome of Bacillus subtilis through homology recombination. Plasmids consist of pBR322 replicon, different fragments of Bac. subtilis chromosomal DNA, Cm resistance marker from pBD64 plasmid. Frequency of transformation was 10(-4) per bacterial cell. Foreign DNA (genes for tryptophan metabolism of Bac. mesentericus) was introduced into the chromosome of Bac. subtilis with the help of these plasmids.     

Isolation of large bacterial plasmids and characterization of the P2 incompatibility group plasmids pMG1 and pMG5.

Large plasmids from Agrobacterium tumefaciens, Salmonella typhimurium, Escherichia coli, Pseudomonas putida, and Pseudomonas aeruginosa were routinely and consistently isolated using a procedure which does not require ultracentrifugation but includes steps designed to separate large-plasmid DNA from the bacterial folded chromosome. It also selectively removes fragments of broken chromosome. A variety of large plasmids was readily visualized with agarose gel electorphoresis, including five between 70 and 85 megadaltons (Mdal) in size, six between 90 and 143 Mdal, one that was larger than 200 Mdal, and one that was larger than 300 Mdal. This isolation procedure allowed initial estimation of the molecular sizes of the two IncP2 plasmids, pMG1 and pMG5, which were 312 and 280 Mdal, respectively. A standard curve for size determination by gel electrophoresis including plasmids between 23 and 143 Mdal in size did not extrapolate linearly for plasmids of the 300-Mdal size range. Unique response of different plasmids to the isolation procedure included sensitivity of IncP1 plasmids to high pH and the co-isolation of a 20-Mdal "cryptic" plasmid in conjunction.     

'Cells' and 'organisms' as a habitat for DNA.

Although the bulk of the hereditary information in bacteria is organized as a single chromosome, it has been known for some years now that bacteria may also carry pieces of self-replicating extrachromosomal DNA. These units are known as plasmids. Sometimes such plasmids carry the information necessary to give rise to mature bacterial viruses under appropriate conditions, but in other cases they specify the production of enzymes and other proteins which alter the bacterial phenotype. Plasmids are often inessential for survival of bacteria, although they may widen the range of environmental conditions under which they flourish. Thus plasmids may be thought of as adventitious additions to the genetic content of bacterial cells. Recently it has become clear that furthur organizational units of DNA are to be found in bacterial cells. These units are called insertion sequences and transposons. Unlike plasmids and the chromosome, however, these DNA units do not carry enough genetic information to specify their own independent replication: they must rely on plasmids or the chromosome for that purpose. Nevertheless they behave in many respects as independent functional units. Although it is possible to think of the chromosome, plasmids and transposons/insertion sequences as three distinct hierarchies of bacterial DNA, genes may move from one hierarchy to another; and such transitions have important implications for the evolution of bacterial populations. Moreover, their study in bacteria may throw much light on the type of DNA interactions occurring in higher cells.     

Development of a method for heterologous gene expression in Enterobacter amnigenus, a potential host for the biological control of mosquito larvi

An integrative plasmid containing a 1.3 kb fragment of chromosomal DNA from Enterobacter amnigenus was constructed. The Omega fragment encoding spectinomycin/streptomycin resistance was cloned into the unique BglII site of the resulting plasmid, and the interrupted fragment was transferred via plasmid pMAK705 by electroporation into E. amnigenus with a selection for spectinomycin resistance. Cointegrants were resolved to generate an E. amnigenus strain that expressed spectinomycin resistance, but grew as rapidly as the parental strain. The cloned fragment encodes a putative homologue of the proW gene of Escherichia coli that is not essential for E. amnigenus growth. The integrative plasmid is now available to introduce any heterologous DNA into the E. amnigenus chromosome, for the construction of promoter-probe vectors for the studies of gene regulation, or to construct plasmids suitable for the isolation of secretion signals. Immediate applications of this system will include the expression and secretion of crystal toxins from bacilli for the biological control of mosquito larvae infected with the bacterial host.     

Cloning of the cyo locus encoding the cytochrome o terminal oxidase complex of Escherichia coli.

The structural genes encoding the cytochrome o terminal oxidase complex (cyo) of Escherichia coli have been subcloned into the multicopy plasmid pBR322 after the Mu-mediated transposition of the gene locus from the bacterial chromosome onto the conjugative R plasmid RP4. Introduction of cyo plasmids into strains (cyo cyd) lacking both terminal oxidases restored the ability of the strains to grow aerobically on nonfermentable substrates. Strains carrying the cyo plasmids produced 5 to 10 times more cytochrome o oxidase than did control strains. The gene products encoded by the cyo plasmids could be immunoprecipitated with monospecific antibodies raised against cytochrome o. The cloned genes will be valuable for studying the structure, function, and regulation of the cytochrome o terminal oxidase complex.     

Method to integrate multiple plasmids into the mycobacterial chromosome

In order to create a system in which two independent plasmids can be integrated into a mycobacterial chromosome, a mycobacterial plasmid was constructed containing the phage attachment site attP from the mycobacteriophage L5 genome and additionally containing the bacterial attachment site, attB. This plasmid will integrate into the mycobacterial chromosome via recombination of the plasmid-borne attP site with the chromosomal attB site in the presence of a mycobacterial vector carrying the L5 integrase (int) gene. The integrated plasmid has a plasmid-borne attB site that is preserved and will accept the integration of additional mycobacterial plasmids containing the L5 attP site. This system should be useful in the construction of novel mycobacterial strains. In particular, this system provides a method by which several recombinant antigens or reporter constructs can be sequentially inserted into a mycobacterial strain and subsequently tested.     

Replication defective RP4 plasmids recovered after chromosomal integration

pHH6000 is a composite replicon made by the in vitro ligation of the IncP plasmid RP4 to a fragment of bacteriophage lambda capable of autonomous replication. Derivatives were selected in which it had integrated into the Escherichia coli chromosome by homologous recombination with the resident lambda prophage, and plasmids were subsequently regenerated from the integrated molecules. Although of the same molecular size as pHH6000, all had altered properties: those recovered from the chromosome of cells simultaneously carrying a distinguishable autonomous IncP plasmid showed a 100- to 1000-fold reduction in their ability to become established in a lambda lysogen; those regenerated from cells with no autonomous IncP plasmid were no longer RP4 replicons, now being dependent on replication functions encoded by the lambda DNA they carry and therefore unable to form a plasmid in a lambda lysogen. This second class of plasmids still exhibited normal RP4 incompatibility and stability even though neither property is encoded by the lambda replicator DNA. It was concluded that expression of RP4 incompatibility and partitioning control do not require an intact RP4 replicon. The data also suggest that the presence in the chromosome of a normal RP4 molecule may be deleterious to the host, although the manner in which the integrated molecules were obtained allows other explanations. The composite plasmids replicating from cloned lambda genes should be useful in analysis of the regulated distribution of RP4 molecules at cell division.