Non-random distribution of transduction termini in transductants from the integrated R plasmid, R100-1

Summary Tra ⁺and tra ^–derivatives of drug resistance plasmid, R100-1, were isolated by phage P1 from an Hfr donor with integrated R100-1 and then analyzed by complementation tests with tra ^–point mutants of Flac. Tra ⁺derivatives of R100-1 carrying tetracycline resistance alone and those carrying all six drug-resistance genes could support transfer of tra ^–point mutants of Flac except Flac traJ, whereas all of tra ^–derivatives of R100-1 failed to complement any one of tra ^–point mutants of Flac. This suggests that these tra ^–derivatives of R100-1 carrying tetracycline resistance gene are deleted for all the transfer genes impaired in the Flac point mutants tested. We assume a hot point, probably a specific base sequence similar to an IS element, at the left of the tetracycline gene (Fig. 1) becomes a transduction terminus in transduction of the integrated R100-1 by phage P1. Complementation analysis of tra ^–derivatives carrying five resistance genes except the tetracycline gene led us to a supposition that a gene(s), probably analogous to traJ of the F plasmid, is located on R100-1 near the tetracycline gene which plays an important regulatory role for self-transfer as well as for the complementation of tra ^–Flac mutants.     

Development of a Tn10 Vehicle for Insertion Mutagenesis in Rhizobium

A transposon Tn10 vehicle was developed using a self transmissible (Tra⁺) plasmid pRK2013 having narrow host range ori of replication (ColEl). The construct pSA10-3 carrying Tn10 was useful in efficiently transferring transposon Tn10 from E. coli into various rhizobia. The ColEl replicon conferred suicidal property to vector in Rhizobium background where it falls to replicate stably. Thus this plasmid can be employed to cause independent insertion mutations in rhizobia by Tn10 transposition. The frequency of tetracycline resistant colonies of Rhizobium (Tn10 mutants) was approximately 10⁵ folds higher than the spontaneous Tet^R mutants. Reversion frequency of these mutants was less than 10^?8 indicating adequate stability of Tn10 mutations.     

Generation and Characterization of Tn5 Insertion Mutations in Pseudomonas syringae pv. tomato

Tn5-induced insertion mutations were generated in the Pseudomonas syringae pv. tomato genome by mating this plant pathogen with an Escherichia coli strain carrying the suicide plasmid vector for Tn5, pGS9. Km^r transconjugants occurred at frequencies ranging from 2 × 10⁻⁷ to 9 × 10⁻⁶; approximately 5.5% of these transconjugants were also Cm^r, indicating the presence of additional pGS9 DNA sequences. Approximately 1% of the Km^r Cm^s mutants were auxotrophic. Southern blot analysis revealed that the Tn5 element had inserted into one unique site on the chromosome for each Km^r Cm^s transconjugant examined. Physical and genetic tests of Tn5-induced auxotrophs showed that Tn5 mutations in P. syringae pv. tomato were very stable and that secondary transposition of Tn5 or its insertion sequence IS50 was a rare event. Nine of 920 Km^r Cm^s transconjugants screened on tomato seedlings either were avirulent or produced very mild symptoms. Each of the virulence mutants was the result of a unique single-site Tn5 insertion. Five mutants also failed to induce a hypersensitivity reaction on tobacco.     

Complementation analysis in Pseudomonas aeruginosa of the transfer genes of the wide host range R plasmid R18

A method of transductional complementation was developed in Pseudomonas aeruginosa to identify the cistrons involved in the conjugal transfer of the wide host range R plasmid R18. This used the P. aeruginosa bacteriophage E79tv-2 and has led to the identification of eight tra cistrons encoded by this plasmid. Plasmids mutant in six cistrons, traA, traB, traC, traD, traE, and traG were resistant to donor-specific phage (Dps^?) while traF and traH mutant plasmids retained phage sensitivity. Some traB mutants were unable to inhibit the replication of phage G101 (Phi(G101)^?) while some were also deficient in entry exclusion (Eex^?). Two traB mutants which were also Eex^? were suppressible by an amber suppressor. Three tra mutants selected directly as being Phi(G101)^? were found to be also Dps^?Eex^? and mutant in traB. These data suggest a relationship between traB, Eex, and Phi(G101). In order to facilitate future genetic comparison of the tra genes of R18 and other wide host range plasmids and the role of the host in conjugation, R18 DNA was compared with that of RP4, by restriction enzyme fragment patterns and found to be identical.     

R factor-mediated tetracycline resistance in Escherichia coli K12 dominance of some tetracycline sensitive mutants and relief of dominance by deletion

Summary Strains of Escherichia coli K12 heterozygous for the R100-1 tetracycline resistance region were constructed. They carried the wild-type Tet^r genes in the chromosome and single site Tet^s mutations on plasmids. Some heterozygotes could not express tetracycline resistance fully after induction. The mutant tet allele was thus partially dominant.When heterozygotes carrying the dominant tet mutant were plated on agar containing 50 g/ml tetracycline, mutants which grew normally occurred at a frequency of 1–4×10^-4. Analysis of these dominance relief mutants showed that in 53/56 isolates the dominant tet allele was lost forming either Tra⁺ or Tra^- deletion mutants of the plasmid. The mutation frequency was not affected either by the host chromosomal recA mutation or by the temperature of growth of the culture.     

Isolation and characterisation of deletion mutants involving the transfer genes of P-group plasmids in Pseudomonas aeruginosa

Summary The P-group plasmids RP1 and R26 are recovered at low frequency following conjugal transfer to B3-lysogens of P. aeruginosa PAO. The rare carbenicillin-resistant transcipients that do arise are usually transfer-defective (Tra^-) and may show the loss of other plasmid borne functions, namely kanamycin-resistance (Km^r) and reduced plating of phage GlOl (Spp⁺). The four phenotypic classes that occur among the Tra^- derivatives are respectively, Tra^- (69–81%), Tra^- Spp^- (12–30%), Tra^- Km^s and Tra^- Km^s Spp^- (0.2–1%), of which the latter three are due to plasmid deletions. This is seen from the sizes of the plasmids carried by these bacteria and from the transductional analysis of the R26-derivatives. Thus, although R26 (MW=52×10⁶ daltons) is too large to be transduced by phage F116L (MW=40×10⁶), this is possible for its Tra^- Km^s and Tra^- Km^s Spp^- derivatives. The phenotypes and frequencies of the various transcipient classes suggests that the gene order Km..Tra..Spp occurs in both RP1 and R26, and that Spp is more closely linked to Tra than is Km. These conclusions are supported by the sizes of the plasmid mutants since deletions spanning the loci Km Tra Spp, Km Tra, and Tra Spp involve the loss of DNA of MW 8-17×10⁶, 5-13×10⁶ and 1-9×10⁶ daltons respectively.Whilst all the transcipients displayed the incompatibility properties of the parent plasmids (Inc⁺), only some retained plasmid surface exclusion (Sfx⁺). Moreover, a strict correlation existed between the Sfx and Spp phenotypes such that the transcipients were either wild type, Sfx^- Spp^-, or displayed an intermediate phenotype for both characters. This suggests that these phenotypes are controlled by closely linked genes or are different manifestations of the same gene function. The deletion map of these various markers in both RP1 and R26 therefore seems to be Km..Tra..Sfx/Spp..Inc.     

Transpositional Mutagenesis of Thiobacillus novellus and Thiobacillus versutus

Transpositional mutagenesis of Thiobacillus novellus by Tn501 was achieved by means of the incompatibility of IncP plasmids. Tn501 insertion caused three types of mutant phenotypes: isoleucine auxotrophy, lysine auxotrophy, and a reduced ability to oxidize reduced sulfur compounds and to fix CO₂. Oxidation rates for elemental sulfur (S⁰), thiosulfate (S₂O₃²⁻), and tetrathionate (S₄O₆²⁻) in mutants of the latter type were reduced relative to those of the nonmutant control strain. Incorporation of labeled bicarbonate (H¹⁴CO₃⁻) was also significantly impaired. Although suicide vehicles were not useful for the introduction of transposons into T. novellus, this method was effective for the Tn1721-induced mutagenesis of Thiobacillus versutus. Tn1721 insertions resulted in the loss of the natural resistance of T. versutus to arsenate and gentamicin and in auxotrophies for isoleucine-valine, arginine, phenylalanine, valine, and panthothenate. Transpositional mutagenesis by either method should prove to be a useful tool for further study of these and other members of the genus Thiobacillus.     

Transposon Mutagenesis and Excision of R′ Plasmids by Conjugative, Chimeric Plasmid pUW942 in Extra-Slow-Growing Rhizobium japonicum Strains

Transposons Tn501 (specifying mercury resistance) and Tn7 (specifying resistance to trimethoprim and streptomycin) were introduced into extra-slow-growing Rhizobium japonicum by conjugal transfer of the 82 kilobase chimeric plasmid pUW942. Mercury-resistant transconjugants were obtained at a frequency of 10⁻⁷ to 10⁻⁹. The transfer frequency of streptomycin resistance was lower than that of mercury resistance, and Tn7 was relatively unstable. pUW942 was not maintained as an autonomously replicating plasmid in R. japonicum strains. However, some of the Hg^r transconjugants from the RJ19FY, RJ17W, and RJ12S strains acquired antibiotic markers of the vector plasmid pUW942. Southern hybridization of plasmid and chromosomal DNA of R. japonicum strains with ³²P-labeled pUW942 and pAS8Rep-1, the same plasmid as pUW942 except that it does not contain Tn501, revealed the formation of cointegrates between pUW942 and the chromosome of R. japonicum. More transconjugants with only Tn501 insertions in plasmids or the chromosome were obtained in crosses with strains RJ19FY and RJ17W than with RJ12S. These retained stable Hg^r both in plant nodules and under nonselective in vitro growth conditions. One of the RJ19FY and two of the RJ12S Hg^r transconjugants with vector plasmid-chromosome cointegrates conjugally transferred plasmids of 82, 84 or 86, and 90 kilobases, respectively, into plasmidless Escherichia coli C. These plasmids strongly hybridized to pUW942 and EcoRI digests of total DNA of each respective R. japonicum strain but not to indigenous plasmid DNA of the R. japonicum strains. These R′ plasmids consisted of pUW942-specific EcoRI fragments and an additional one or two new fragments derived from the R. japonicum chromosome.     

Tn5-Induced Mutations in the Enterobacterial Phytopathogen Erwinia chrysanthemi

Escherichia coli (2492/pJB4JI) matings with Erwinia chrysanthemi produced kanamycin resistant (Km^r) transconjugants, a majority of which were gentamicin sensitive (Gm^s). A small proportion (about 0.8%) of the Km^r Gm^s clones were either auxotrophic or failed to catabolize galacturonate (Gtu⁻). The R plasmid (pJB4JI) DNA was detected in the parent E. coli strain and in a Km^r Gm^r transconjugant, but not in Km^r Gm^sE. chrysanthemi strains carrying Tn5-induced mutations. In Hfr crosses, Km^r (Tn5) was found linked with most mutations. A majority (>95%) of prototrophic recombinants were Km^s, except for Leu⁺ and Arg⁺ recombinants which were 30 to 50% Km^s. Spontaneous revertants were obtained for all markers except car, gtu, lys, thr, and trp. Prototrophic revertants, with the exception of Met⁺, Leu⁺, or His⁺ clones, were Km^s. We conclude from both genetic and physical data that Tn5 transposed from pJB4JI into different sites on the chromosome of E. chrysanthemi.     

Genetic complementation of rhizobial nod mutants with Frankia DNA: artifact or reality?

Two divergent reports have been published on the genetic complementation of rhizobial nod mutants using Frankia DNA. In 1991 putative Frankia cosmid library clones were reported to restore normal nodulation properties to Rhizobium leguminosarum biovar viciaenodD::Tn5, but no supporting sequence data were published. In 1992 a second group reported a failure to find any evidence of functional complementation of various rhizobial nod mutants by Frankia DNA (nodA, nodB and nodC). Complementation tests of nine Nod^? R. leguminosarum bv. viciae or Sinorhizobium meliloti Tn5 mutants (nodA ^? , nodB ^? , nodC ^? , nodD ^? , nodF? ^? , nodL ^? , nodH ^? ) were thus performed using a Frankia gene library in pLAFR3 to clarify this situation. Rhizobial transconjugants obtained by tri-parental matings were screened for restoration of the nodulation phenotype on their host plants, Vicia sativa subsp. nigra or Medicago sativa. Nodulation was observed on plants inoculated with transconjugants of the R. leguminosarum bv. viciaenodC::Tn5 mutant. The Nod⁺ rhizobial transconjugants were isolated and analysed. The Nod⁺ phenotype of these transconjugants was found to be due to Tn5 excision/transposition. No functional complementation was found with any of the mutants used, suggesting that rhizobial complementation of nod mutants with Frankia DNA is unlikely to occur.     

Two aberrant mercury resistance transposons in the Pseudomonas stutzeri plasmid pPB

The two mer operons of the Pseudomonas stutzeri OX plasmid pPB and their flanking regions have been sequenced and found to be part of two aberrant transposons. The narrow spectrum mer operon is almost identical to that of Tn501, but is associated with the remnants of Tn5053 tni genes rather than the Tn501 transposition module. The broad spectrum mer operon shows an overall homology with that of Tn5053, but differs from it in the presence of a merB gene, absent in Tn5053, and a merC gene instead of a merF. The pPB broad spectrum mer operon is associated with an incomplete Tn5053-like transposition module and with the Tn501 tnp genes, which are proximal, respectively, to the end and to the beginning of the mer operon. A hypothesis about pPB evolution is presented.     

Transposition of a DNA fragment flanked by two inverted Tn1 sequences

The 32 Md fragment (derived from plasmid RP4::Tn1) carrying the Km^r gene and flanked by two inverted Tn1 elements is capable of recA-independent translocation to other plasmids. We designated this new transposon Tn1755. In various crosses, frequencies of Tn1755 transposition to plasmids Co1B-R3, R15 and F′ColVBtrp varied from 2.5 to 90% of the frequencies of Tn1 transposition. Tn1755 can integrate into various sites of the recipient plasmids. We failed to observe transposition of another RP4::Tn1 fragment flanked by two opposingly oriented Tn1 transposons and harboring the Tc^r gene. Presumably, to form a new transposable structure, other features must also be of importance.     

Tn501 insertion mutagenesis in Pseudomonas aeruginosa PAO

Summary Transposon insertion mutagenesis of the Pseudomonas aeruginosa PAO chromosome with Tn1 and Tn501 was carried out using a mutant plasmid of R68::Tn501 temperature-sensitive for replication and maintenance. This method consists of three steps. Firstly, the temperature-independent, drug-resistant clones were selected from the strain carrying this plasmid. In the temperature-indepent clones, the plasmid was integrated into the chromosome by Tn1- or Tn501-mediated cointegrate formation. Secondly, such clones were cultivated at a permissive temperature to provoke the excision of the integrated plasmid from the chromosome. Excision occurred by the reciprocal recombination between the two copies of Tn1 or Tn501 flanking the integrated plasmid, leaving one Tn1 or Tn501 insertion on the chromosome. Thirdly, the excised plasmid was cured by cultivating these isolates at a non-permissive temperature without selection for the drug resistance. Using this method, we isolated 1 Tn1-induced and 43 Tn501-induced auxotropic mutations in this organism. Genetic mapping allowed us to identify two new genes, pur-8001 and met-8003. The Tn501-induced auxotrophic mutations were distributed non-randomly among auxotrophic genes, and the reversion of the mutations by precise excision of the Tn501 insertion occurred very rarely.     

Genetic analysis of the mobilization of the non-conjugative plasmid Clo DF13

Summary Insertion of the transposon Tn901 within a region of almost one third of the Clo DF13 genome is compared with the loss of its transfer (indicated as Mob^-) by a conjugative plasmid. By use of both insertion and deletion mutants of Clo DF13, this region was located on the Clo DF13 physical map. Studies with transfer mutants of the F plasmid showed that, in contrast with the traG gene product, the gene products of traI, traD and traM do not play an essential role in the transfer process of Clo DF13. Because Clo DF13 can be transferred under conditions in which the coningative plasmid is not transferred at all, it is obvious that normally Clo DF13 is not transferred to recipient cells as a cointegrate of the conjugative plasmid and Clo DF13. Characterization of the Mob^- Clo DF13:: Tn901 plasmids showed that the absence or alteration of the Clo DF13 specified polypeptide B (molecular weight 61,000 daltons) is correlated with the transfer deficiency of these plasmids. The existence of transfer deficient Clo DF13:: Tn901 plasmids, which direct the synthesis of polypeptide B, showed that other Clo DF13 genetic information is also involved in the transfer of this plasmid. On basis of the site of the mutation in the genome, the synthesis of polypeptide B in the minicell system and the behaviour of the Mob^- mutants in complementation studies, we preliminarily divide the Mob^- Clo DF13:: Tn901 plasmids into three different classes. The possible role of Clo DF13 genetic information involved in the transfer process of this plasmid is discussed.     

Killing of Klebsiella pneumoniae mediated by conjugation with bacteria carrying antibiotic-resistance plasmids of the group N

Escherichia coli K-12 strains carrying any one of a number of different plasmids of the incompatibility group N have been found to kill Klebsiella pneumoniae, M5a1. A simple spot test is described that could be of value in diagnosing the presence of these plasmids. Killing is closely associated with the ability of the N⁺ strains to mate with M5a1 and all conjugation-deficient (Tra^?) mutants were also unable to kill M5a1 (Kil^?1). At a low frequency, some Kil^? mutants could be isolated that showed little or no transfer deficiency. Plasmids of the groups P and W which have been suspected (on other grounds) to specify conjugative systems interrelated in some manner to that specified by N plasmids, also kill M5a1 but to a lesser degree.     

Genetic analysis of mutations in the transfer genes of pDU202 tra::Tn10 plasmids, caused by the excision of Tn10.

Summary Transfer-deficient derivatives of pDU202 (a Tc^s deletion mutant of R100-1) caused by the insertion of Tn10 into the R factor's transfer genes have been described previously. Tetracyline-sensitive mutants of four of these were selected. In the majority of cases the Tc^s mutation was caused by a deletion of the Tc^r genes which was often accompanied either by a deletion of some of the flanking transfer genes or by a secondary mutation which was probably an inversion. A number of preferred end points for the deletions and inversions occur in the transfer operon of pDU202. Analysis of the mutants by complementation tests with Flac tra elements confirmed that the order of genes in the promoter distal part of the tra region of pDU202 is traKBCFHGSD and traI.     

A Tn21 terminal sequence within Tn501: complementation of tnpA gene function and transposon evolution

Summary The prokaryotic mercury-resistance transposon Tn501 contains a sequence, 80 nucleotides from one end, which is identical with an inverted terminal repeat (IR) of Tn21. This Tn21 IR sequence is used when Tn21 complements a TnpA^- derivative of Tn501, but not when Tn501 is used for the complementation. Complementation by Tn1721 shows a preference for the normal Tn501 IRs. The element (Tn820) transposed when Tn21 is used to complement a Hg^- TnpR^- TnpA^- Res^- deletion mutant of Tn501 contains the Tn21 IR sequence at one terminus and a Tn501 IR at the other. Transposition of Tn820 can be complemented by Tn501 and Tn1721, but at a much lower frequency than transposition of the parental element (Tn819) which has two Tn501 IRs. The relationship between the transposition functions of Tn501, Tn21 and Tn1721, and available nucleotide sequence data suggest that Tn501 evolved by the transposition of a Tn21-like element into another transposable element (similar to that found within Tn1721) followed by deletion of the Tn21-like transposition functions.Abbreviations used (IR) Inverted repeat - (Cb) carbenicillin - (Cm) chloramphenicol - (Sm) streptomycin - (Su) sulphonamide - (Tc) tetracycline - (Tp) trimethoprim     

The transposable elements resident on the plasmids of Pseudomonas putida strain H, Tn5501 and Tn5502, are cryptic transposons of the Tn3 family

Genes for (methyl)phenol degradation in Pseudomonas putida strain H (phl genes) are located on the plasmid pPGH1. Adjacent to the phl catabolic operon we identified a cryptic transposon, Tn5501, of the Tn3 family (class II transposons). The genes encoding the resolvase and the transposase are transcribed in the same direction, as is common for the Tn501 subfamily. The enzymes encoded by Tn5501, however, show only the overall homology characteristic for resolvases/integrases and transposases of Tn3-type transposons. Therefore it is likely that Tn5501 is not a member of one of the previously defined subfamilies. Inactivation of the conditional lethal sacB gene was used to detect transposition of Tn5501. While screening for transposition events we found another transposon integrated into sacB in one of the sucrose-resistant survivors. This element, Tn5502, is a composite transposon consisting of Tn5501 and an additional DNA fragment. It is flanked by inverted repeats identical to those of Tn5501 and the additional fragment is separated from the Tn5501 portion by an internal repeat (identical to the left terminal repeat). Transposition of phenol degradation genes could not be detected. Analysis of sequence data revealed that the phl genes are not located on a Tn5501-like transposon.     

Use of Transposon-Transposase Complexes To Create Stable Insertion Mutant Strains of Francisella tularensis LVS

Francisella tularensis is a highly virulent zoonotic bacterial pathogen capable of infecting numerous different mammalian species, including humans. Elucidation of the pathogenic mechanisms of F. tularensis has been hampered by a lack of tools to genetically manipulate this organism. Herein we describe the use of transposome complexes to create insertion mutations in the chromosome of the F. tularensis live vaccine strain (LVS). A Tn5-derived transposon encoding kanamycin resistance and lacking a transposase gene was complexed with transposase enzyme and transformed directly into F. tularensis LVS by electroporation. An insertion frequency of 2.6 × 10⁻⁸ ± 0.87 × 10⁻⁸ per cell was consistently achieved using this method. There are 178 described Tn5 consensus target sites distributed throughout the F. tularensis genome. Twenty-two of 26 transposon insertions analyzed were within known or predicted open reading frames, but none of these insertions was associated with the Tn5 target site. Analysis of the insertions of sequentially passed strains indicated that the transposons were maintained stably at the initial insertion site after more than 270 generations. Therefore, transformation by electroporation of Tn5-based transposon-transposase complexes provided an efficient mechanism for generating random, stable chromosomal insertion mutations in F. tularensis.     

Establishment of Tn5096-Based Transposon Mutagenesis in Gordonia polyisoprenivorans

The transposons Tn5, Tn10, Tn611, and Tn5096 were characterized regarding transposition in Gordonia polyisoprenivorans strain VH2. No insertional mutants were obtained employing Tn5 or Tn10. The thermosensitive plasmid pCG79 harboring Tn611 integrated into the chromosome of G. polyisoprenivorans; however, the insertional mutants were fairly unstable und reverted frequently to the wild-type phenotype. In contrast, various stable mutants were obtained employing Tn5096-mediated transposon mutagenesis. Auxotrophic mutants, mutants defective or deregulated in carotenoid biosynthesis, and mutants defective in utilization of rubber and/or highly branched isoprenoid hydrocarbons were obtained by integration of plasmid pMA5096 harboring Tn5096 as a whole into the genome. From about 25,000 isolated mutants, the insertion loci of pMA5096 were subsequently mapped in 20 independent mutants in genes which could be related to the above-mentioned metabolic pathways or to putative regulation proteins. Analyses of the genotypes of pMA5096-mediated mutants defective in biodegradation of poly(cis-1,4-isoprene) did not reveal homologues to recently identified genes coding for enzymes catalyzing the initial cleavage of poly(cis-1,4-isoprene). One rubber-negative mutant was disrupted in mcr, encoding an α-methylacyl-coenzyme A racemase. This mutant was defective in degradation of poly(cis-1,4-isoprene) and also of highly branched isoprenoid hydrocarbons.