Bacteriophages F0lac h, SR, SF: phages which adsorb to pili encoded by plasmids of the S-complex

Phage F0lac is an RNA-containing phage which plates only on strains carrying the plasmid EDP208, a pilus derepressed derivative of the unique incompatibility plasmid F0lac. A host range mutant, phage F0lac h, was selected which plated on strains carrying the ungrouped plasmid pPLS::Tn5 and lysed strains carrying another ungrouped plasmid TP224::Tn10 or the Com9 plasmid R71. An RNA-containing phage, SR, was isolated from sewage on bacteria harbouring plasmid pPLS::Tn5. It was antigenically distinct from the above two phages but had the same host range as phage F0lac h. Phages F0lac h and SR adsorbed unevenly to the shafts of the conjugative pili. Another phage, SF, was filamentous and plated or propagated on strains carrying any of the above plasmids as well as on strains harbouring IncD or F-complex plasmids. Plasmids TP224::Tn10 and pPLS::Tn5 were compatible with representative plasmids of all Inc groups also encoding thick flexible pili. The four plasmids EDP208, R71, TP224::Tn10 and pPLS::Tn5 were compatible with one another except for the reaction of TP224::Tn10 in the presence of pPLS::Tn5 which was slightly ambiguous. The host ranges of the bacteriophages, together with the serological relatedness of the thick flexible pili determined by these four compatible plasmids, suggested that they constitute a new complex, here designated S.     

Interspecies transduction of plasmids among Bacillus anthracis, B. cereus, and B. thuringiensis

Bacteriophage CP-51, a generalized transducing phage for Bacillus anthracis, B. cereus, and B. thuringiensis, mediates transduction of plasmid DNA. B. cereus GP7 harbors the 2.8-megadalton multicopy tetracycline resistance plasmid, pBC16. B. thuringiensis 4D11A carries pC194, the 1.8-megadalton multicopy chloramphenicol resistance plasmid. When phage CP-51 was propagated on these strains, it transferred the plasmid-encoded antibiotic resistances to the nonvirulent Weybridge (Sterne) strain of B. anthracis, to B. cereus 569, and to strains of several B. thuringiensis subspecies. The frequency of transfer was as high as 10(-5) transductants per PFU. Tetracycline-resistant and chloramphenicol-resistant transductants contained newly acquired plasmid DNA having the same molecular weight as that contained in the donor strain. Antibiotic-resistant transductants derived from any of the three species were effective donors of plasmids to recipients from all three species.     

Mercury and Organomercurial Resistances Determined by Plasmids in Pseudomonas

Mercury and organomercurial resistance determined by genes on ten Pseudomonas aeruginosa plasmids and one Pseudomonas putida plasmid have been studied with regard to the range of substrates and the range of inducers. The plasmidless strains were sensitive to growth inhibition by Hg(2+) and did not volatilize Hg(0) from Hg(2+). A strain with plasmid RP1 (which does not confer resistance to Hg(2+)) similarly did not volatilize mercury. All 10 plasmids determine mercury resistance by way of an inducible enzyme system. Hg(2+) was reduced to Hg(0), which is insoluble in water and rapidly volatilizes from the growth medium. Plasmids pMG1, pMG2, R26, R933, R93-1, and pVS1 in P. aeruginosa and MER in P. putida conferred resistance to and the ability to volatilize mercury from Hg(2+), but strains with these plasmids were sensitive to and could not volatilize mercury from the organomercurials methylmercury, ethylmercury, phenylmercury, and thimerosal. These plasmids, in addition, conferred resistance to the organomercurials merbromin, p-hydroxymercuribenzoate, and fluorescein mercuric acetate. The other plasmids, FP2, R38, R3108, and pVS2, determined resistance to and decomposition of a range of organomercurials, including methylmercury, ethylmercury, phenylmercury, and thimerosal. These plasmids also conferred resistance to the organomercurials merbromin, p-hydroxymercuribenzoate, and fluorescein mercuric acetate by a mechanism not involving degradation. In all cases, organomercurial decomposition and mercury volatilization were induced by exposure to Hg(2+) or organomercurials. The plasmids differed in the relative efficacy of inducers. Hg(2+) resistance with strains that are organomercurial sensitive appeared to be induced preferentially by Hg(2+) and only poorly by organomercurials to which the cells are sensitive. However, the organomercurials p-hydroxymercuribenzoate, merbromin, and fluorescein mercuric acetate were strong gratuitous inducers but not substrates for the Hg(2+) volatilization system. With strains resistant to phenylmercury and thimerosal, these organomercurials were both inducers and substrates.     

Plasmid pC present in Salmonella enterica serovar Enteritidis PT14b strains encodes a restriction modification system

Salmonella enterica serovar Enteritidis (S. Enteritidis) possesses plasmids of different sizes and roles. Besides the serovar-specific virulence plasmid present in most field strains, S. Enteritidis can harbour plasmids of low molecular mass whose biological role is poorly understood. We therefore sequenced plasmid pC present in S. Enteritidis strains belonging to phage type PT14b. The size of plasmid was determined to be 5,269 bp and it was predicted to encode four open reading frames (ORFs). The first two ORFs were found (initial 3,230 bp) to be highly homologous to rom and mbeA genes of ColE1 plasmid of Escherichia coli. Proteins encoded by the other two ORFs were 99% homologous to a restriction methylase and restriction endonuclease encoded by plasmid pECO29 of a field strain of E. coli. Using insertional mutagenesis we confirmed experimentally that the plasmid pC-encoded restriction modification system was functional and could explain the high resistance of S. Enteritidis PT14b strains to phage infection.     

Genetic and physical characterization of trimethoprim resistance plasmids from Shigella sonnei and Shigella flexneri

Analysis of six Shigella flexneri and four S. sonnei isolates with trimethoprim (Tp) resistance from clinical cases in Ontario has shown that, in all isolates, the Tp resistance is mediated by gene(s) on conjugative, multiple antibiotic-resistance plasmids. The physical and genetic characterization of these plasmids revealed that there are three different Tp resistance plasmids. One group, composed of all six S. flexneri plasmids, consists of plasmids which are about 70 megadaltons (MDa) and inhibit the fertility of an Escherichia coli Hfr strain (Fi+). A representative member of this group, pPT4, demonstrates a weak incompatibility reaction with IncFl plasmid R455-2. Another group, three of the four S. sonnei plasmids, contains plasmids which are about 43 MDa, Fi-, and mediate propagation of phage PRD1. The third group, the remaining S. sonnei plasmid, is 53 MDa, fi+, mediates propagation of phages fd and MS2, and is incompatible with IncFII plasmid R100. These plasmids also have been differentiated by restriction endonuclease fragment profiles. Analysis of pPT4 has revealed that the Tp resistance of this plasmid is transposable. The transposon, Tn536, is different from previously described Tp resistance transposons; it is 16 MDa, and in addition to Tp, it encodes resistance to mercuric chloride ions, spectinomycin, streptomycin, and sulfonamides.     

Phage t: a group T plasmid-dependent bacteriophage

Phage t was isolated from sewage from Pretoria. It formed plaques only on Escherichia coli and Salmonella typhimurium strains that carried plasmids belonging to incompatibility group T. Five of six group T plasmids permitted visible lysis of R+ host strains. There was no visible lysis of E. coli J53-2 or S. typhimurium LT2trpA8 carrying the T plasmid Rts1 although the strains supported phage growth as indicated by at least a 10-fold increase in phage titre. The latter strains transferred the plasmid at high frequency to E. coli strain CSH2 and the resulting transconjugants plated the phage. Proteus mirabilis strain PM5006(R402) failed to support phage growth although it transferred the plasmid and concomitant phage sensitivity to E. coli J53-2. The phage was hexagonal in outline, RNA-containing, resistant to chloroform and adsorbed to the shafts of pili determined by T plasmids.     

The cotransduction of pET system plasmids by mutants of T4 and RB43 bacteriophages

The study of the cotransduction of the plasmid pairs pET-3a-pLysE and pET-3a-pLysS by the mutant phage T4alc7 showed that the antibiotic resistance markers of the plasmids were cotransduced with a high frequency. The analysis of the plasmid DNA of cotransductants and cotransformants showed that the mutant phage T4alc7 can be used for obtaining the monomeric and oligomeric forms of plasmids and for the cotransduction of two-plasmid overproduction systems into E. coli strains. The plaque mutants RB43-03 and RB43-13 derived from bacteriophage RB43 were found to be able to cotransduce the antibiotic resistance markers of pET-3a and pLysE plasmids.     

Serological characteristics of pili determined by the plasmids R711b and F0lac.

The plasmids R711b (at present IncX) and F0lac (IncFV) both determine pili morphologically like those of F (IncFI), and confer sensitivity to the F-specific filamentous bacteriophages, but not to the F-specific isometric RNA phages. Detailed serological studies show that the two pilus types are unrelated, and that neither is related to any of the previously defined F pilus serotypes. Adsorption of the isometric RNA phage MS2 to R711b pili occurs in the presence but not in the absence of formalin, which presumably prevents elution of reversibly adsorbed virions. No adsorption occurs with F0lac pili. MS2 multiplication, as measured by titre increase tests in liquid medium, is found with neither plasmid. The two plasmids are not incompatible. These observations indicate that R744b and F0lac are different both from one another and from the plasmids belonging to the incompatibility groups IncFI--IV.     

Application of agarose gel electrophoresis to the characterization of plasmid DNA in drug-resistant enterobacteria.

A simple gel electrophoresis method has been described for the detection of plasmid DNA in bacteria (Meyers et al., 1976). We investigated further the problems encountered in using this method for the analysis of plasmids in wild enterobacterial strains. The migration of open circular and linear plasmid DNA was examined, since these forms sometimes caused difficulty in the interpretation of the plasmid content of uncharacterized strains. Electrophoresis at different agarose concentrations was employed to resolve clearly plasmid DNA from the chromosomal DNA fragments in the crude preparations. Dissociation of some plasmids occurs in Salmonella typhimurium, and this was detected by electrophoresis. The technique was applied to the study of drug-resistant strains of S. typhimurium phage type 208 from several Middle Eastern countries. The cultures carry a drug resistance plasmid of the FIme compatibility group, and at least two other plasmids which were detected and identified by gel electrophoresis. The studies supported and extended the genetic findings and provided information on the distribution of particular plasmids.     

Transfer and stability of drug resistance plasmids inEscherichia coli K12

Mating experiments between pairs of strains ofEscherichia coli containing either the compatible plasmids TP120 (Inc N) and R1 (Inc FII) or the incompatible plasmids TP125 (Inc B) and TP113 (Inc B) were undertaken in mixed continuous-flow cultures and in dialysis sacs suspended in pond water. Plasmid transfer was readily demonstrated between strains carrying compatible plasmids TP120 and R1 in both continuous-flow culture and pond water. In mixed cultures of strains carrying plasmids TP125 and TP113, transfer was only observed in continuous-flow culture systems. Strains ofE. coli containing aggregates of plasmids TP120 and R1 were shown to be stable over 5 months continuous cultivation under carbon limited conditions at a growth rate of 0.1 hours^–1 in the presence of drugs which select for the maintenance of both plasmids. In the strains containing plasmid aggregates, a gene dosage effect was observed with respect to the levels of resistance to drugs whose resistance was encoded by both plasmids. Chemostat experiments showed that no cointegrate plasmids were found from the strains ofE. coli initially containing both plasmid TP120 and plasmid R1.     

Sequence analysis and characterization of plasmids from Streptococcus thermophilus

The nucleotide sequences of eight plasmids isolated from seven Streptococcus thermophilus strains have been determined. Plasmids pSt04, pER1-1, and pJ34 are related and replicate via a rolling circle mechanism. Plasmid pJ34 encodes for a replication initiation protein (RepA) and a small polypeptide with unknown function. Plasmids pSt04 and pER1-1 carry in addition to repA genes coding for small heat shock proteins (sHsp). Expression of these proteins is induced at elevated temperatures or low pH and increases the thermo- and acid resistance. Plasmids pER1-2 and pSt22-2 show identical sequences with five putative open reading frames (ORFs). The gene products of ORF1 and ORF4 reveal some similarities to transposon encoded proteins of Bacillus subtilis and Tn916. ORF1 of plasmid pSt106 encodes a protein similar to resolvases of different Gram-positive bacteria. Integrity of ORF2 and 3, encoding a putative DNA primase and a replication protein, is essential for replication. ORF1 to 3 of plasmid pSt08, which are organized in a tricistronic operon, encode a RepA protein, an adenosine-specific methyltransferase, and a type II restriction endonuclease. Another type II restriction-modification (R/M) system is encoded on plasmid pSt0 which is highly similar to those encoded on lactococcal plasmid pHW393 and B. subtilis plasmid pXH13. Plasmid-free derivatives of strains St0 and St08 show increased phage sensitivity, indicating that in the wild-type strains the R/M systems are functionally expressed. Recombinant plasmids based on the replicons of plasmids pSt04, pJ34, pSt106, pSt08, and pSt0, are able to replicate in Lactococcus lactis and B. subtilis, respectively, whereas constructs carrying pER1-2 only replicate in S. thermophilus.     

Transforming activity of R- and Lac-plasmids of clinical strains of Gram-negative bacteria]

The isolated plasmid DNA of clinical strains of Gram-negative bacteria were shown to have transforming activity when E. coli strain 0600 and S. typhimurium strain LT-2 were used as recipients. The frequency of transformation depended on the recipient strain and the character of the plasmids. The presence of deletion mutants was revealed among the transformants. Such mutants occurred with varying frequency, most often in S. typhimurium strain LT-20; the reason for this phenomenon is at present under discussion. The transformation of plasmids controlling lactose splitting and their conjugation transfer into recipient S. typhimurium strain LT-2 is possible only under condition of using recipient (R+). The possibility of the formation of the cointegrate (R and lac plasmids) in recipient S. typhimurium strain LT-2 is discussed.     

The sym plasmid pRP2JI and at least two other loci of Rhizobium leguminosarum biovar phaseoli can confer resistance to infection by the virulent bacteriophage RL38

Abstract The virulent Rhizobium bacteriophage RL38 did not form plaques on R.leguminosarum by phaseoli but did so at high efficiency on a derivative of that strain lacking its symbiotic plasmid pRP2JI. Other strains with large deletions in pRP2JI which removed many nod and nif genes retained resistance to RL38, showing that the gene which confers phage resistance lies elsewhere on the plasmid. Although the wild-type strain of R. leguminosarum bv. phaseoli failed to plate RL38, it was possible to transduce chromosomal markers into this strain, indicating that the 'block' was not at an early stage in the infection process. Two different recombinant plasmids obtained from a clone bank of genomic DNA of R. leguminosarum bv. phaseoli , which appeared to have no DNA in common, both conferred resistance to RL38. Surprisingly, the DNA cloned in each of these plasmids did not originate from pRP2JI. Therefore, several different loci both on the Sym plasmid and elsewhere on the bacterial genome can be involved in conferring resistance to this bacteriophage.     

Polyresistant Enterobacteriaceae strains and their plasmids in a hospital. Medical and theoretical aspects

The properties and origin of multiple resistant strains of Enterobacteriaceae found in the intestine and nasopharynx of infants admitted to the hospital for premature infants were studied. The strains of E. coli of different serovars isolated at various periods contained similar conjugative R plasmids with a molecular weight of 80 Md belonging to the O incompatibility group controlling resistance to kanamycin and physically independent small plasmids controlling resistance to ampicillin (7 Md) and streptomycin-sulfanilamides (4 Md). Multiple drug resistance in the strains of K. pneumoniae was controlled by single large (100-120 Md) plasmid cointegrates with 6-8 resistance markers. Such cointegrates consisted of several potentially independent plasmids, sometimes dividing on transformation of plasmid DNA of the recipient strains of E. coli K12. The small plasmids controlling resistance to ampicillin and streptomycin-sulfanilamides similar to the respective plasmids of E. coli were the constant components of the plasmids cointegrates. The multiple drug resistance in the above strains was combined with high capacity for colonization in premature infants. The medical staff and mothers were the sources of bacterial strains with single plasmids controlling definite types of resistance. It is suggested that the multiple resistant strains of Enterobacteriaceae are formed in hospital as a result of accumulation of the plasmids or plasmid markers and selection. One of the conditions for successive acquisition of new plasmid markers by definite bacterial strains was their high capacity for colonization in patients, which provided constant contacts and genetic exchange of such strains with a wide range of immigrant strains during colonization in the newly admitted patients.     

A self-transmissible plasmid of an enteropathogenic Escherichia coli strain codes for mannose-resistant haemagglutinin and for antibiotic resistance

Abstract Four enteropathogenic Escherichia coli strains were studied with respect to their antibiotic resistance characters, plasmid patterns, toxin production and haemagglutination properties. Two of these strains showed multiple antibiotic resistance characters, although all possessed several plasmids of varying sizes. One of the strains DD-41 showed the presence of a non-fimbrial cell-associated mannose-resistant haemagglutinin (MRHA) which was encoded by a 70 MDa plasmid. Conjugation experiments demonstrated that this MRHA-containing plasmid also coded for ampicillin and tetracycline resistance factors and was self-transmissible.     

In vivo genetic exchange of a functional domain from a type II A methylase between lactococcal plasmid pTR2030 and a virulent bacteriophage.

The conjugative plasmid pTR2030 confers bacteriophage resistance to lactococci by two independent mechanisms, an abortive infection mechanism (Hsp+) and a restriction and modification system (R+/M+). pTR2030 transconjugants of lactococcal strains are used in the dairy industry to prolong the usefulness of mesophilic starter cultures. One bacteriophage which has emerged against a pTR2030 transconjugant is not susceptible to either of the two defense systems encoded by the plasmid. Phage nck202.50 (phi 50) is completely resistant to restriction by pTR2030. A region of homology between pTR2030 and phi 50 was subcloned, physically mapped, and sequenced. A region of 1,273 bp was identical in both plasmid and phage, suggesting that the fragment had recently been transferred between the two genomes. Sequence analysis confirmed that the transferred region encoded greater than 55% of the amino domain of the structural gene for a type II methylase designated LlaI. The LlaI gene is 1,869 bp in length and shows organizational similarities to the type II A methylase FokI. In addition to the amino domain, upstream sequences, possibly containing the expression signals, were present on the phage genome. The phage phi 50 fragment containing the methylase amino domain, designated LlaPI, when cloned onto the shuttle vector pSA3 was capable of modifying another phage genome in trans. This is the first report of the genetic exchange between a bacterium and a phage which confers a selective advantage on the phage. Definition of the LlaI system on pTR2030 provides the first evidence that type II systems contribute to restriction and modification phenotypes during host-dependent replication of phages in lactococci.     

Protein expression in Escherichia coli minicells containing recombinant plasmids specifying trimethoprim-resistant dihydrofolate reductases.

Deoxyribonucleic acid fragments containing the structural genes for several trimethoprim-resistant dihydrofolate reductases from naturally occurring plasmids were inserted into small cloning vehicles. The genetic expression of these hybrid plasmids was studied in purified Escherichia coli minicells. The type I dihydrofolate reductase, encoded by plasmid R483 and residing within transposon 7 (Tn7), had a subunit molecular weight of 18,000. The type II dihydrofolate reductase, specified by plasmid R67, had a subunit molecular weight of 9,000. These two enzymes were antigenically distinct in that anti-type II dihydrofolate reductase (R67) antibody did not cross-react with the type I (R483) protein. The trimethoprim-resistant reductase specified by plasmid R388 had a subunit molecular weight of about 10,500 and was immunologically related to the type II (R67) enzyme. A 9,000 subunit of the dihydrofolate encoded by the transposition element Tn402 was also antigenically related to the R67 reductase.     

Partial characterization of the genetic basis for sucrose metabolism and nisin production in Streptococcus lactis

We attempted to identify the genetic loci for sucrose-fermenting ability (Suc+), nisin-producing ability (Nip+), and nisin resistance (Nisr) in certain strains of Streptococcus lactis. To obtain genetic evidence linking the Suc+ Nip+ Nisr phenotype to a distinct plasmid, both conjugal transfer and transformation were attempted. A conjugation procedure modified to protect the recipients against the inhibitory action of nisin allowed the conjugal transfer of the Suc+ Nip+ Nisr marker from three Suc+ Nip+ Nisr donors to various recipients. The frequency of transfer ranged from 1.7 x 10(-4) to 5.6 x 10(-8) per input donor, depending on the mating pair. However, no additional plasmid DNA was apparent in these transconjugants. Transformation of S. lactis LM0230 to the Suc+ Nip+ Nisr phenotype by using the plasmid pool of S. lactis ATCC 11454 was not achieved, even though other plasmids present in the pool were successfully transferred. However, two results imply the involvement of plasmid DNA in coding for the Suc+ Nip+ Nisr phenotype. The Suc+ Nip+ Nisr marker was capable of conjugal transfer to a recipient deficient in host-mediated homologous recombination (Rec-), and the Suc+ Nip+ Nisr marker exhibited bilateral plasmid incompatibility with a number of lactose plasmids found in S. lactis. Although our results indicate that the Suc+ Nip+ Nisr phenotype is plasmid encoded, no physical evidence linking this phenotype to a distinct plasmid was obtained.     

Facile and gentle method for quantitative lysis of Escherichia coli and Salmonella typhimurium

Garrett et al. (Mol. Gen. Genet. 182:326-331, 1981) constructed strains of Escherichia coli harboring derivatives of plasmid pBR322 that carry the lysis genes (S, R, and Rz) of phage lambda. The plasmid construction placed the genes under control of the lactose operon operator-promotor (and thus of lac repressor). Induction of E. coli strains carrying these plasmids resulted in rapid lysis of the culture unless the S gene was defective, in which case the cells grew normally. A freeze-thaw treatment of induced cells carrying an S- plasmid gave quantitative lysis of either E. coli or Salmonella typhimurium cells under exceptionally gentle conditions. The method was equally effective on exponential phase cells and stationary phase cells and was readily extended to a large number of independent cultures.