Advertisement
Research Article

Design and Synthesis of a Quintessential Self-Transmissible IncX1 Plasmid, pX1.0

  • Lars H. Hansen equal contributor mail,

    equal contributor Contributed equally to this work with: Lars H. Hansen, Mikkel Bentzon-Tilia

    hestbjerg@bio.ku.dk

    Affiliation: Department of Biology, University of Copenhagen, Copenhagen, Denmark

    X
  • Mikkel Bentzon-Tilia equal contributor,

    equal contributor Contributed equally to this work with: Lars H. Hansen, Mikkel Bentzon-Tilia

    Affiliation: Department of Biology, University of Copenhagen, Copenhagen, Denmark

    X
  • Sara Bentzon-Tilia,

    Affiliation: Department of Biology, University of Copenhagen, Copenhagen, Denmark

    X
  • Anders Norman,

    Affiliation: Department of Biology, University of Copenhagen, Copenhagen, Denmark

    X
  • Louise Rafty,

    Affiliation: DNA2.0, Menlo Park, California, United States of America

    X
  • Søren J. Sørensen

    Affiliation: Department of Biology, University of Copenhagen, Copenhagen, Denmark

    X
  • Published: May 18, 2011
  • DOI: 10.1371/journal.pone.0019912
  • Published in PLOS ONE

Abstract

DNA exchange in bacteria via conjugative plasmids is believed to be among the most important contributing factors to the rapid evolution- and diversification rates observed in bacterial species. The IncX1 plasmids are particularly interesting in relation to enteric bacteria, and typically carry genetic loads like antibiotic resistance genes and virulence factors. So far, however, a “pure” version of these molecular parasites, without genetic loads, has yet to be isolated from the environment. Here we report the construction of pX1.0, a fully synthesized IncX1 plasmid capable of horizontal transfer between different enteric bacteria. The designed pX1.0 sequence was derived from the consensus gene content of five IncX1 plasmids and three other, more divergent, members of the same phylogenetic group. The pX1.0 plasmid was shown to replicate stably in E. coli with a plasmid DNA per total DNA ratio corresponding to approximately 3–9 plasmids per chromosome depending on the growth phase of the host. Through conjugation, pX1.0 was able to self-transfer horizontally into an isogenic strain of E. coli as well as into two additional species belonging to the family Enterobacteriaceae. Our results demonstrate the immediate applicability of recent advances made within the field of synthetic biology for designing and constructing DNA systems, previously existing only in silica.

Introduction

The term “synthetic biology,” in its present context, covers the creation of specific self-replicating DNA sequences that encode novel functional biological components, or replicas of existing natural systems, based on extensive preexisting knowledge about gene conservation, function and synteny.

The ability to utilize this new technique has, in large part, been facilitated through recent dramatic advances made within the areas of genome sequencing, and now also genome synthesis [1]. Thus, the ground has been laid for a new era in which the design and creation of functional, synthetic self-replicating genomes of increasing size and complexity has been made possible [1][10]. In no other field than microbiology are these advances so timely or relevant.

Most bacteria carry extrachromosomal self-replicating elements that aid in adaptation to local conditions in their environment. In enteric bacteria, some of the more interesting of these extrachromsomal elements belong to the relatively unknown IncX1 group of mostly conjugative plasmids. They propagate almost solely within the family Enterobacteriaceae, and typically carry genetic loads promoting antibiotic resistance or virulence mostly in the form of cell adhesion factors. The IncX1 plasmids have thus far been reported to confer resistance towards a wide array of antimicrobial compounds, such as the sulfonamides, the ß-lactams, the quinoxaline olaquindox, fluoroquinolones, and chloramphenicol [11][13].

The ability of IncX1 plasmids to spread infectiously through bacterial communities puts them, along with bacteriophages and other viruses, into a broader family of molecular parasites that are able to spread between host cells horizontally. The gene content of conjugative plasmids can typically be divided into plasmid-selfish genes that maintain the integrity and propagation of the plasmids themselves, and genes that benefit the host cell in adapting to local conditions (the genetic load). Cryptic plasmids are examples of extrachromosomal parasitic elements that only encode genes essential for plasmid replication and stable maintenance, and are commonly found within the Enterobacteriaceae [14]. Some members of the IncP family of relatively large plasmids have been shown to exist without any apparent accessory mobile elements [15][17], however, the occurrence of “pure” versions of IncX1 plasmids (i.e. lacking genetic loads) has yet to be elucidated. We therefore embarked on an attempt to recreate such a minimal incX1 plasmid, employing a bottom-up design strategy that would easily accommodate future experimental work and manipulations. Although molecular parasites have been constructed previously from smaller synthesized oligonucleotides [5][7], [18], pX1.0 is the first synthetic DNA molecule able to maintain itself in- and spread to several different species of bacteria. Furthermore, it represents the first synthetic DNA construct designed in silica as a consensus construct derived from several different members of a discrete phylogenetic group, thus it arguably represents the archetypical IncX1 backbone.

The design of the 30.2 kilobase (kb) pX1.0 plasmid was initiated by first selecting the components for a minimal IncX1 sequence. The core sequence is based on a consensus of gene content derived from five publicly available IncX1 plasmid sequences, each consisting of a mostly conserved plasmid backbone, alongside accessory genetic loads of varying sizes (fig. 1). Apart from the consensus IncX1 gene content, pOLA52 carries a genetic load of approximately 22 kb. The load is comprised of the ß-lactamase gene bla, an operon encoding a multidrux efflux pump, and a mrk operon encoding type III fimbriae [19]. In addition to the putative IncX1 backbone, 4 kb of the 33 kb plasmid pSE34 encodes a series of un-conserved hypothetical proteins. 5 kb of the 35 kb pOU1114 plasmid, and 5 kb of the 34 kb plasmid p2ESCUM encodes a series of un-conserved hypothetical proteins as well. The Salmonella enterica serotype Dublin virulence plasmid pOU1115 consists, apart from the consensus IncX1 gene content, of 46 kb of additional DNA including loci encoding K88 fimbriae and proteins involved in proliferation of the bacteria in intestinal and extraintestinal tissues [20].

thumbnail

Figure 1. Genetic maps of p2ESCUM, pOU1114, pSE34, pOLA52, and pOU1115.

The GC-content is depicted in the central part of the maps. Open reading frames (ORFs) proven to be conserved within the IncX1 plasmids constitute the putative IncX1 backbone and are presented as green boxes, whereas red boxes represent ORFs comprising the genetic load.

doi:10.1371/journal.pone.0019912.g001

At the heart of the pX1.0 construct is an archetypical IncX1 replicon which encodes the replication initiation protein π, initiator of plasmid replication through a Cairns type (Θ type) mechanism at three discrete origins of replication (α, ß and γ), along with the Bis protein, required for replication initiation at the ß-origin. Furthermore, the entire conjugational system associated with IncX1 plasmids was included, along with two cognate origins of transfer, to enable horizontal transfer of the construct. The 15.8 kb mob/tra-locus is comprised of 19 ORFs, 16 encoding a type IV secretion system essential for mate-pair formation, and 3 ORF's encoding functions concerned with DNA transfer and post-conjugal replication [19]. To ensure maximum stability, common plasmid stability determinants associated with IncX1 plasmids, such as the ParFG active partitioning system related to the archetypical ParA ATPase/ParB mechanism [21] and the post segregational StbDE toxin/antitoxin killing system were also retained in the base sequence.

During the next phase of the design process, emphasis was put on retaining much of the intrinsic modularity of plasmid genomes by surrounding each functional backbone module with unique restriction sites. Restriction sites were carefully chosen based on a normalized frequency index comparing relative restriction-site occurrences in the plasmid database and selected bacterial genomes. Restriction sites chosen to adjoin modules all had maximum digestion efficiencies in the same buffer. Any chosen restriction site re-occurring in the coding regions were removed by silent mutations in accordance with Gene Designer's E. coli codon-bias table [22], [23], and restriction sites leaving blunt ends were placed between modules flanked by restriction sites leaving overhangs. Furthermore, a multiple cloning site (MCS) was inserted at a neutral position (29.3 kb–30.2 kb) along with a removable, moderately expressed chloramphenicol acetyltransferase selection marker (cat) enabling the application of selective pressure in plasmid transfer- and maintenance experiments. The potential ease, with which future studies on plasmid host range, conjugational efficiency, and other properties of pX1.0 can be carried out, is thus greatly enhanced by the ability to perform discrete manipulations (i.e. removing or replacing modules) with simple molecular techniques such as restriction endonuclease- and ligase reactions. A graphical overview of the entire pX1.0 plasmid sequence is depicted in figure 2.

thumbnail

Figure 2. Genetic map of pX1.0.

The GC-content is depicted in the central part of the map. Open reading frames are shown as colour coded arrows, indicating their function and transcribed direction. The ORFs are divided into the following modules: gem (gene expression modulation), tra (conjugal transfer), mob1 (mobilization 1), rep/stb (replication initiation/toxin-antitoxin plasmid addiction), mob2 (mobilization 2), par (plasmid partitioning) and res (resistance marker). Unique restriction sites are shown at the module junctions. MCS represents the restriction sites PmeI, AbsI, MreI, KpnI, SwaI, NotI and SgrDI.

doi:10.1371/journal.pone.0019912.g002

The synthesis stage involved dividing the entire pX1.0 sequence into three cassettes of approximately 10 kb in length that were then individually synthesized at DNA 2.0, essentially as previously described [10]. Break points were chosen so that neither the central replicon, nor the chloramphenicol resistance marker would be functional prior to a complete assembly of the sequence. Fragments were verified with double-stranded DNA sequencing and joined together at designed restriction sites. Fragment assembly was concluded with a full re-verification (by DNA sequencing) of the plasmid to confirm that no bases differed from the original designed sequence. This was done before any functional experiments were carried out.

During the subsequent verification steps, the construct was demonstrated to replicate with a copy number comparable to most other low-copy number plasmids. In exponentially growing batches of E. coli GeneHogs®, pX1.0 replicated at a ratio equivalent to 0.6 plasmid copies per fg total DNA as determined by quantitative PCR (qPCR). During stationary phase the plasmid were found to replicate at a ratio equivalent to 1.8 plasmids per fg total DNA. Assuming that the average molar mass of the 4.7 Mb E. coli chromosome is 650 g mol−1, pX1.0 is estimated to replicate at a copy number of 3–9 copies per E. coli chromosome. The similar IncX1 plasmid R485 has previously been reported to replicate at an average copy number of 3–5 plasmid copies per E. coli cell [24] indicating that the pX1.0 replicon operates at levels comparable to its natural equivalents.

To verify functionality of the combined 15,827 bp region containing the tra- and mob modules, conjugation frequencies of pX1.0 from E. coli GeneHogs® donors into different members of Enterobacteriaceae family, were determined. Conjugation from E. coli GeneHogs® into an isogenic strain of E. coli was observed in di-parental filtermatings at a mean frequency of 5.5·10−3±1.7·10−3 (s.d) transconjugants per donor. Compared to the previously reported conjugation frequency of 9.0·10−2 transconjugants per donor in the plasmid pOLA52 [25], the observed transfer frequencies of this study suggest that the conjugation apparatus of pX1.0 functions similar to that of pOLA52. Any decrease in conjugal transfer frequencies of pX1.0 compared to pOLA52 may owe to the fact that pOLA52 encodes type III fimbriae, influencing cell proximity, and consequently the frequency of plasmid transfer [25]. In a similar fashion, pX1.0 successfully transferred itself horizontally from E. coli GeneHogs® to Salmonella typhimurium and Enterobacter aerogenes with mean conjugation frequencies of 3.7·10−4±2.7·10−4 (s.d.) and 4.7·10−3±1.8·10−3 (s.d.) transconjugants per donor, respectively.

To establish the functionality of the included plasmid maintenance modules, cells harboring the pX1.0 plasmid were propagated in LB medium at 37°C for 50 generations without antibiotic selection. Based on 11 replicas, each representing 96 isolates, the frequency of loss was determined to be 0.004% generation−1, as compared to 0.01% generation−1 for the naturally occurring IncX1 plasmid pOLA52. A two-tailed, unpaired students t-test showed that the observed difference was not statistically significant, with a 95% confidence interval (P = 0.083, n = 11). Despite the finding of plasmid free cells, these results show stable inheritance without selective pressure and indicate a parasitic lifestyle of the plasmids.

Incompatibility tests were done as previously described [19], and confirmed that the pX1.0 plasmid was unable to propagate in the presence of the IncX1 plasmid, pOLA52. However, 100% compatibility was observed with the IncX2 plasmid, R6K.

This study presents the first synthetic DNA construct able to replicate within a living organism as well as spread to several different species. We believe that pX1.0 represents the minimal IncX1 backbone, and that this in conjunction with the approach employed in the design process of pX1.0 facilitates further experimental work to a degree that substantiates that pX1.0 becomes a reference plasmid for future studies on the biology of IncX1 plasmids. More importantly, by bringing the hitherto undiscovered quintessential IncX1 plasmid to life, this study illustrates the potential of synthetic biology as a means of reconstructing not only synthetic copies of already existing DNA systems, but also DNA systems existing only in silica. It is in this respect it is of utmost importance to emphasize the fact that pX1.0 represents a hypothetical, minimal, non-virulent version of already known incX1 plasmids.

Materials and Methods

The design of pX1.0

Based on the consensus gene content of IncX1 plasmids pOLA52, pSE34, pOU1114, pOU1115 and p2ESCUM (GenBank accessions EU370913, EU219533, DQ115387, DQ115388 and CU928149, respectively) a scaffold-sequence representing a putative minimal IncX1 plasmid was designed by removing non-recurring regions of the pOLA52 sequence. Other, more divergent, members of the IncX plasmids (pHI4320, R6K, and pBS512_33) were also used as universal reference points for gene content in the construction of the scaffold. A region of the consensus sequence (19.6 kb–20.7 kb) containing 8 small ORFs were included in the scaffold-sequence because they were found to be universally conserved among the reference plasmids, although their functions remain to be elucidated. Although the active plasmid segregation mechanism (parFGH), and the plasmid addiction system (stbDE) varied between some of the reference plasmids, the parFGH and stbDE gene cassettes of pOLA52 were included in the pX1.0 sequence as this required the least amount of sequence manipulations. The essential IncX1 backbone was subsequently modified using the Gene Designer (GD) software from DNA2.0 as follows: All open reading frames (ORFs) and non-coding regions (promoters, origins of replication, and origins of transfer) were reconstructed as discrete DNA elements separated by endonuclease restriction sites. The GD's E. coli codon-bias table [22], [23] was used to choose optimal codons for expression in E. coli in any situation that required changes to, or addition of, coding regions within the sequence. An artificial chloramphenicol resistance operon, consisting of a lac-promoter, a ribosomal binding region containing a Shine-Dalgarno sequence followed by a 7 bp spacer, an E. coli optimized version of the chloramphenicol acetyl transferase gene (cat), followed by an rrnB terminator, was subsequently included. Finally, a multiple cloning site region was included as the last element of the plasmid sequence (see below). A normalized frequency index of all known restriction sites was made, and 20 restriction sites found to be rare in both the plasmid database and in selected bacterial genomes, as well as in non-coding regions of the construct, were selected for further use in the design process. Restriction sites were added in GD as DNA sequence elements, separating the construct into a replication/plasmid addiction module (rep/stb), two mobilization modules (mob1/2), a conjugation module (tra), the segregation module (par), the gene expression modulation module (gem), and the resistance marker module (res). Any restriction sites leading to blunt ends were situated between modules flanked by restriction sites that left overhangs. Any of the 20 restriction site sequences existing naturally in the coding regions were removed by silent mutations. Restriction enzymes with 100% activity in NEB buffer 4 (BamHI, AfeI, PacI, ApaI, AscI, AvrII, FseI, SacII, SbfI, SpeI, SphI and PmeI) were specifically chosen as module-cutters, so that any module/modules could be excised in a single restriction reaction. The remaining sites (AbsI, MreI, KpnI, NotI, SgrDI and SwaI) were used either in the MCS region, or as restriction site sequences used for adapting fragments to be cloned into the MCS (MauBI and XbaI). The full sequence was submitted to GenBank where it was given the accession number HM114226.

Estimation of the pX1.0 copy number

The pX1.0 copy number was estimated by qPCR. Genomic DNA extractions were made on an overnight (ON) culture of Invitrogen's E. coli GeneHogs® harboring the pX1.0 plasmid, and on a similar culture in exponential growth phase. The concentration of total DNA in the two samples was measured using Invitrogen's Qubit™ fluorometer. In order to make a qPCR standard equally complex to the two samples, chromosomal E. coli GeneHogs® DNA was added to pX1.0 DNA in the approximate ratio of five plasmids per chromosome. A serial ten-fold dilution of the complex standard was used to make the standard curve. A hundred-fold dilution of sample DNA was used as template in the sample qPCRs. All reactions were carried out using 1 µl of template DNA, and 1 µl of each of the two primers, pX1.0Fw: 5′-CCGTAGCTTGCTCATACATC-3′, and pX1.0Rev: 5′-GTCGTGGTATTCACTCCAGA-3, (10 pmol µl−1) in Stratagene's Brilliant® II SYBR®Green qPCR master mix. Finally, the number of plasmids per fg of total DNA in the two samples was calculated and used to estimate the approximate number of plasmids per chromosome.

Estimating the conjugational abilities of pX1.0

The ability of pX1.0 to conjugate from E. coli GeneHogs® to selected enteric bacteria (E. coli GeneHogs®::npt, Salmonella typhimurium DT27 [26], and Enterobacter aerogenes DSM30053 (Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH) was determined by adding 8 µl of donor overnight culture, and 8 µl of recipient overnight culture onto ADVANTEC©'s mixed cellulose/ester membrane filters placed on LB-agar plates. Filter matings were carried out for two hours at 37°C, and the filters were subsequently washed by vortexing the filter in a 0.9% NaCl solution for 3 minutes. A serial ten-fold dilution was made on the wash solution, and droplet assays were carried out on minimal medium containing 0.2% glucose and 5 µg ml−1 chloramphenicol for the E. coli GeneHogs®+Salmonella typhimurium DT27 mating and for the E. coli GeneHogs®+Enterobacter aerogenes DSM30053 mating. The droplet assay was carried out on LB-agar supplemented with 50 µg kanamycin and 5 µg chloramphenicol ml−1 for the E. coli GeneHogs®+E. coli GeneHogs®::npt mating. Donor enumeration was carried out on LB plates containing 5 µg ml−1 chloramphenicol. The frequency of conjugation was estimated as transconjugants donor−1. Control filter matings with only the donor or recipient strains were carried out to verify the selectivity of the transconjugant plates.

Verification of the pX1.0 maintenance genes

In order to determine the stability of pX1.0, E. coli GeneHogs® cells harboring either pOLA52 or pX1.0 were propagated for 50 generations by periodic dilutions in tubes containing 5 ml LB-broth. Subsequently 96 colonies of each were isolated on LB-agar and replica plated onto LB-agar plates supplemented with either chloramphenicol or ampicillin, depending on which plasmid was tested. 11 replicas were done for each plasmid. A two-tailed, unpaired students t-test were used to determine the significance of the differences in the frequencies of plasmid loss observed between the two plasmids.

The incompatibility testing was carried out as described earlier [19].

Author Contributions

Conceived and designed the experiments: LHH MB-T SB-T SJS. Performed the experiments: MB-T SB-T. Analyzed the data: LHH MB-T SB-T. Contributed reagents/materials/analysis tools: AN LR. Wrote the paper: LHH MB-T AN.

References

  1. 1. Gibson DG, Glass JI, Lartigue C, Noskov VN, Chuang RY, et al. (2010) Creation of a Bacterial Cell Controlled by a Chemically Synthesized Genome. Science 329: 52–56.
  2. 2. Itakura K, Hirose T, Crea R, Riggs AD, Heyneker HL, et al. (1977) Expression in Escherichia coli of a chemically synthesized gene for the hormone somatostatin. Science 198: 1056–1063.
  3. 3. Ryan MJ, Brown EL, Sekiya T, Küpper H, Khorana HG (1979) Total Synthesis of a tyrosine suppressor tRNA gene. J Biol Chem 254: 5817–5826.
  4. 4. Dillon PJ, Rosen CA (1990) A Rapid method for the construction of synthetic genes using the polymerase chain-reaction. Bio Techniques 9: 298–300.
  5. 5. Stemmer WP, Crameri A, Ha KD, Brennan TM, Heyneker HL (1995) Single-step assembly of a gene and entire plasmid from large numbers of oligodeoxyribonucleotides. Gene 164: 49–53.
  6. 6. Smith HO, Hutchison CA III, Pfannkoch C, Venter JC (2003) Generating a synthetic genome by whole genome assembly: φX174 bacteriophage from synthetic oligonucleotides. Proc Natl Acad Sci U S A 100: 15440–15445 (2003).
  7. 7. Cello J, Paul AV, Wimmer E (2002) Chemical synthesis of poliovirus cDNA: Generation of infectious virus in the absence of natural template. Science 297: 1016–1018.
  8. 8. Kodumal SJ, Patel KG, Reid R, Menzella HG, Welch M, et al. (2004) Total synthesis of long DNA sequences: Synthesis of a contiguous 32-kb polyketide synthase gene cluster. Proc Natl Acad Sci U S A 101: 15573–15578.
  9. 9. Gibson DG, Benders GA, Andrews-Pfannkoch C, Denisova EA, Baden-Tillson H, et al. (2008) Complete chemical synthesis, assembly, and cloning of a Mycoplasma genitalium genome. Science 319: 1215–1220.
  10. 10. Dillon PJ, Lentz J, Rosen CA (1991) Construction of a replication- competent murine retrovirus vector expressing the human immunodeficiency-virus type-1 tat transactivator protein. J Virol 65: 4490–4493.
  11. 11. Bradley DE (1978) Determination of very thin pili by the bacterial drug resistance plasmid R485. Plasmid 1: 376–387.
  12. 12. Hansen LH, Johannesen E, Burmølle M, Sørensen AH, Sørensen SJ (2004) Plasmid-encoded multidrug efflux pump conferring resistance to olaquindox in Escherichia coli. Antimicrob Agents Chemother 48: 3332–3337.
  13. 13. Sørensen AH, Hansen LH, Johannesen E, Sørensen SJ (2003) Conjugative plasmid conferring resistance to olaquindox. Antimicrob Agents Chemother 47: 798–799.
  14. 14. Burian J, Guller L, Macor M, Kay WW (1997) Small cryptic plasmids of multiplasmid, clinical Escherichia coli. Plasmid 37: 2–14.
  15. 15. Kamachi K, Sota M, Tamai Y, Nagata N, Konda T, et al. (2006) Plasmid pBP136 from Bordetella pertussis represents an ancestral form of IncP-1β plasmids without accessory mobile elements. Microbiology 152: 3477–3484.
  16. 16. Harada KM, Aso Y, Hashimoto W, Mikami B, Murata K (2006) Sequence and analysis of the 46.6-kb plasmid pA1 from Sphingomonas sp. A1 that corresponds to the typical IncP-1beta plasmid backbone without any accessory gene. Plasmid 56: 11–23.
  17. 17. Bahl MI, Hansen LH, Goesmann A, Sørensen SJ (2007) 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
  18. 18. Wimmer E, Mueller S, Tumpey TM, Taubenberger JK (2009) Synthetic viruses: A new opportunity to understand and prevent viral disease. Nat Biotechnol 27: 1163–1172.
  19. 19. Norman A, Hansen LH, She Q, Sørensen SJ (2008) Nucleotide sequence of pOLA52: A conjugative IncX1 plasmid from Eschericia coli which enables biofilm formation and multidrug efflux. Plasmid 60: 59–74.
  20. 20. Libby SJ, Adams LG, Ficht TA, Allen C, Whitford HA, et al. (1993) The spv genes on the Salmonella dublin virulence plasmid are required for severe enteritis and systemic infection in the natural host. Infect Immun 65: 1786–1792.
  21. 21. Hayes F, Barilla D (2006) The bacterial segrosome: A dynamic nucleoprotein machine for DNA trafficking and segregation. Nature Rev Microbiol 4: 133–143.
  22. 22. Villalobos A, Ness JE, Gustafsson C, Minshull J, Goyindarian S (2006) Gene Designer: A Synthetic Biology Tool for Constructing Artificial DNA Segments. BMC Bioinformatics. available: doi: 10.1186/1471-2105-7-285 Accessed 18 January 2011.
  23. 23. Welch M, Govindarajan S, Ness JE, Villalobos A, Gurney A, et al. (2009) Design Parameters to Control Synthetic Gene Expression in Escherichia coli. PLoS ONE. Available: doi: 10.1371/journal.pone.0007002 Accessed 18 January 2011.
  24. 24. Stalker DM, Helsinki DR (1985) DNA Segments of the IncX Plasmid R485 Determining Replication and Incompatibility with Plasmid R6K. Plasmid 14: 245–254.
  25. 25. Burmølle M, Bahl MI, Jensen LB, Sørensen SJ, Hansen LH (2008) Type 3 fimbriae, encoded by the conjugative plasmid pOLA52, enhance biofilm formation and transfer frequencies in Enterobacteriaceae strains. Microbiology 154: 187–195.
  26. 26. Olsen JE, Brown DJ, Thomsen LE, Platt DJ, Chadfield MS (2004) Differences in the Carriage and the Ability to Utilize the Serotype Associated Virulence Plasmid in Strains of Salmonella enterica Serotype Typhimurium Investigated by use of a Self-Transferable Virulence Plasmid, pOG669. Microb Pathog 36: 337–347.