RecP, a new minor pathway of general recombination in Escherichia coli encoded by plasmid R1drd-19.

Plasmid R1drd-19 markedly improves the recombination deficiency of recB and recBrecC mutants of Escherichia coli K12 as measured by Hfr crosses and increases their resistance to uv inactivation. The effect correlates with the production of an ATP-dependent ds DNA exonuclease in recB/R1drd-19 cells. This paper further investigates the suppressive effect of plasmid R1drd-19 on the recB mutation of E. coli. The gene(s) responsible for the effect was localized to the 13.1-kb EcoRI-C fragment of the resistance transfer factor (RTF) portion of R1drd-19. The plasmid-encoded activity does not merely replace the RecBCD enzyme failure but differs in several significant ways. It promotes a hyper-recombinogenic phenotype, as judged by the phenomenon of super oligomerization of the tester pACYC184 plasmid in recB/R1drd-19 cells and two inter- and intramolecular plasmid recombination test systems. It is probably not inhibited by lambda Gam protein and does not restrict plating of T4gp2 mutant. No significant homology between the E. coli chromosomal fragment carrying recBrecCrecD genes and the EcoRI-C fragment of R1drd-19 was observed. It is suggested that the plasmid-encoded recombination activity is involved in a new minor recombination pathway (designated RecP, for Plasmid). RecP resembles in some traits the RecBCD-independent pathways RecE and RecF but differs in activity and perhaps substrate specificity from the main RecBCD pathway.     

Clustering of genes involved in replication, copy number control, incompatibility, and stable maintenance of the resistance plasmid R1drd-19.

Plasmid R1drd-19 is present in a small number of copies per cell of Escherichia coli. The plasmid was reduced in size by in vivo as well as in vitro (cloning) techniques, resulting in a series of plasmid derivatives of different molecular weight. All plasmids isolated contain a small region (about 2 x 10(6) daltons of deoxyribonucleic acid) of the resistance transfer factor part of the plasmid located close to one of the IS1 sequences that separates the resistance transfer factor part from the resistance determinant. All these derivatives were present at the same copy number, retained the incompatibility properties of plasmid R1drd-19, and were stably maintained during cell division. Genes mutated to yield copy mutations also were found to be located in the same region.     

Plasmid R1drd-19-mediated superoligomerization of the plasmid pACYC184in the recB mutant of Escherichia coli K12

It was found that monomers of the pACYC184 plasmid undergo superoligomerization in a recB mutant of Escherichia coli K12 which is deficient in ATP-dependent RecBC nuclease and carries the drug resistance plasmid R1drd-19. The observed effect is specifically related to the ability of R1drd-19 to determine an ATP-dependent exonucleolytic activity which is functionally similar but not identical to the RecBC nuclease. The oligomerization of pACYC184 is accompanied by the formation of high-order circular structures, and this leads to elimination of the plasmid from cells growing under non-selective conditions.     

Transfer among Erwinia spp. and other enterobacteria of antibiotic resistance carried on R factors

Antibiotic resistance carried on R factors was transferred by conjugation from Escherichia coli B/r and Shigella flexneri 1a to Erwinia spp. Tetracycline resistance (TetR) carried on R factor R100 drd-56 was transferred from E. coli B/r to strains of Erwinia amylovora, E. aroideae, E. atroseptica, E. chrysanthemi, E. cytolytica, E. dissolvens, E. herbicola, E. nigrifluens, and E. nimipressuralis, but not to strains of Erwinia carotovora, E. carnegieana, E. dieffenbachiae, E. oleraceae, and E. quercina. Multiple antibiotic resistance (chloramphenicol, streptomycin, tetracycline; ChlR-StrR-TetR) carried on R factor SR1 was transferred from a clinical isolate of S. flexneri 1a to strains of E. aroideae, E. chrysanthemi, E. herbicola, and E. nigrifluens, but not to strains of other Erwinia spp. The frequency of this transfer was low with receptive cultures of Erwinia spp. and E. coli (F(-) strain). Antibiotic resistance in the exconjugants showed varying degrees of stability in the presence or absence of acridine orange, depending on the strain tested. The frequencies of segregation to drug susceptibility in the presence of acridine orange, though low, suggest that the elements exist as plasmids in the majority of the Erwinia exconjugants. Multiple antibiotic resistance (ChlR-StrR-TetR) was found to segregate into various resistance classes (ChlR-StrR, StrR-TetR, TetR, StrR, and none) in these exconjugants. The exconjugants of E. amylovora, E. herbicola, and E. nigrifluens, to which R100 drd-56 was transferred from E. coli B/r, were sensitive to the male (F)-specific phage M13. There was a positive correlation between the susceptibility of exconjugants to the F-specific phage M13 and their ability to transfer R100 drd-56 to the recipient cultures of Escherichia coli, Erwinia herbicola, Salmonella typhimurium, and Shigella dysenteriae. Exceptions were, however, noted with Erwinia dissolvens and E. nimipressuralis exconjugants harboring R100 drd-56; these exconjugants, although not susceptible to M13, transferred R100 drd-56 to the recipient cultures. The frequency of transfer of R100 drd-56 and the levels of resistance to tetracycline in Erwinia exconjugants were found to differ markedly depending upon the strain employed. Transfer of multiple antibiotic resistance (ChlR-StrR-TetR) from Erwinia exconjugants was not obtained in preliminary trials with an E. coli F(-) strain as the recipient culture.     

A comparative study of the functions of recBCD-nuclease from Escherichia coli and "recombinase", encoded by plasmid R1drd-19]

The RecBCD nuclease of Escherichia coli and "recombinase" determined by R1drd-19 plasmid (the latter is able to replace at least partially the indicated cellular enzyme) were shown to differ from each other in some essential features. The product encoded by the plasmid as distinct from RecBCD nuclease practically is not sensitive to inhibition by GamS protein of the lambda phage. Earlier, it was found that the presence of R1drd-19 plasmid in the recBC cells restores the level of the total ATP-dependent exonuclease activity because of appearance in such cells of a new exonuclease activity also ATP-dependent. The exonuclease activity determined by R1drd-19 plasmid was found to differ from the corresponding activity of the RecBCD enzyme. The plasmid enzyme was able to prevent reproduction of T4g2- mutant on recBC cells. The ability of the plasmid "recombinase" to some stimulation of intrachromosomal recombination in recA mutant witness to incomplete RecA-dependence of its function. No significant homology was registered between Escherichia coli DNA fragment containing the recB, recC, recD genes and the EcoRI-C-fragment of R1drd-19 carrying the sequences responsible for recombination and repair functions of the plasmid.     

Isolation of the kanamycin resistance region (Tn2350) of plasmid R1drd-19 as an autonomous replicon.

We have isolated a circular form of Tn2350, an IS1-flanked kanamycin resistance transposon forming part of the plasmid R1drd-19. This circle (pTn2350::9.6 kilobases) contains a single IS1 element and probably arises by recombination between the two directly repeated Is1 sequences of Tn2350. It can be used to transform Escherichia coli to kanamycin resistance. It is capable of autonomous replication but is not maintained stably in dividing cells and segregates under nonselective conditions. Cloning of a segment of pTn2350 on a conditional plasmid vector allowed us to assign the replication functions of this plasmid to a 1.6-kilobase restriction fragment. The plasmid R1drd-19 can thus be considered as a cointegrate between two replicons separated by IS1 sequences.     

Curing Action of Sodium Dodecyl Sulfate on a Proteus mirabilis R+ Strain

Growth of Proteus mirabilis harboring R100-1 (fi(+)drd str(r)cml(r)tet(r)sul(r)) factors in Penassay broth containing sodium dodecyl sulfate (SDS) leads to the loss of all or part of the genetic elements in high frequencies. In media containing SDS at concentrations as low as 0.03%, both lysis of R(+) cells and elimination of the R factors occur at high frequencies. Appearance of drug-susceptible cells in R(+) cultures occurs during the exponential phase of growth; however, the frequencies of susceptible cells increase substantially after the culture reaches the stationary phase. Reconstruction experiments, coupled with other observations, suggest that the major factor in altering the frequency of drug-susceptible variants is the greater resistance of the variants to the lytic action of SDS. This resistance correlates in most cases with the loss of the transfer functions in the resistance transfer factor.     

Alternate forms of the resistance factor R1 in Proteus mirabilis

The resistance factor R1 may exist in either of two stable physical states in Proteus mirabilis PM-1. In one case, the R1 deoxyribonucleic acid (DNA) has a buoyant density of 1.711 g/cm(3) and replicates under stringent control. Cells harboring R1 in this form may transfer drug resistance by conjugation. In the other case, R1 DNA shows two buoyant density classes at 1.707 and 1.714 g/cm(3). The 1.714 g/cm(3) component is replicated under a degree of relaxed control, and strains carrying this form generally cannot transfer drug resistance by conjugation. Intracellular amounts of the R factor-coded enzyme, chloramphenicol acetyltransferase, did not correspond to amounts of plasmid DNA in Proteus, and the enzyme was present in lower amounts than in Escherichia coli. It is proposed that the two states of R1 in Proteus may represent stable associated and dissociated forms of the plasmid.     

Replication of R-factor R1 in Scherichia coli K-12 at different growth rates.

The R-factor R1drd-19 mediates resistance to beta-lactam antibiotics via a beta-lactamase. A strain of Escherichia coli K-12 carrying R1drd-19 was grown at different growth rates by using different carbon sources. The specific rate of production of the R1 beta-lactamase increased linearly with the growth rate and with the gene dosage. The content of R1 deoxyribonucleic acid was estimated by alkaline sucrose gradient centrifugation and by analysis of the specific rate of beta-lactamase synthesis in nutritional shift-up experiments and was found to decrease fivefold when the growth rate was increased from 0.4 to 1.8 doublings per h. The number of R1 molecules per cell decreased from six to two in the same growth range. The presence of the plasmid affected the mean cell size significantly; at a growth rate of 0.4 doublings per h the R-+ cells were on the average 50% bigger than the R-minus cells, whereas the effect was less than 10% at a growth rate of 1.8 doublings per h. Several reports in the leterature state that the initiation mass of chromosome replication is constant. In this paper it is shown that the initiation mass of R1 replication is proportional to the growth rate. Thus, the replication of the plasmid R1 and of the chromosome are independently regulated processes. It is argued that plasmid replication is under negative control.     

Inheritance of low-level resistance to penicillin, tetracycline, and chloramphenicol in Neisseria gonorrhoeae.

The genetics of low-level resistance to penicillin and other antibiotics in a clinical isolate and a multistep laboratory mutant of Neisseria gonorrhoea was studied by transformation. Mutations at three loci affected sensitivity to penicillin. Mutation at penA resulted in an eightfold increase in resistance to penicillin without affecting response to other antimicrobial agents. Mutation at ery resulted in a two- to fourfold increase in resistance to penicillin and similar increases in resistance to many other antibiotics, dyes, and detergents. Mutation at penB resulted in a fourfold increase in resistance to penicillin and tetracycline, the phenotypic expression of which was dependent on the presence of mutation at ery. The cumulative effect of mutations at penA, ery, and penB was an approximate 128-fold increase in penicillin resistance, to a minimum inhibitory concentration of 1.0 mug/ml. Low-level resistance to tetracycline or chloramphenicol was due to similar additive effects between mutations at the nonspecific ery and penB loci and a locus specific for resistance to each drug (tet and chl, respectively). No evidence was found for penicillinases or other drug-inactivating enzymes.     

Intra- and intermolecular recombination of test plasmids in K12 Escherichia coli cells carrying an RTF derivative of the R1drd-19 plasmid

The RTF derivative of the plasmid R1drd-19 was found to stimulate recombination of the tester plasmids in a recB mutant of Escherichia coli K12. The frequency of intramolecular recombination is increased 3.5 and 20-fold, as compared to the one in rec+ and rec- strains, respectively. The frequency of interplasmid recombination is enhanced 4 and 9-fold, respectively. Considerable heterogeneity of the recombination products of the tester plasmid intramolecular recombination in recB-/RTFR1-19 strain has been revealed. It is hypothesized that a "recombinase" encoded by Rldrd-19 plasmid determines a new minor pathway in recB- (Rec P) which differs in activity and, perhaps substrate specificity from the main Rec BCD pathway.     

Transfer of the gonococcal penicillinase plasmid: mobilization in Escherichia coli by IncP plasmids and isolation as a DNA-protein relaxation complex

A 4.4-megadalton penicillinase plasmid, pWD2, from Neisseria gonorrhoeae was transformed into Escherichia coli. pWD2 was efficiently mobilized by IncP plasmids in E. coli but not by Flac, R1drd-19, or R64drd-11. pWD2 could be isolated as a DNA-protein relaxation complex with properties similar to the well characterized ColE1 complex. The host range of pWD2 was shown to include gonococci, Enterobacteriaceae, and Hemophilus influenzae, but not Acinetobacter calcoaceticus or Pseudomonas aeruginosa. These findings suggest that P-group plasmids could have played a role in the dissemination of the TEM beta-lactamase to pathogenic gram-negative bacteria.     

Characterisation of plasmids coding for the restriction endonuclease EcoRI

Summary The properties of two plasmids coding for the EcoRI restriction and modification enzymes are described. Both plasmids are non auto-transferring (NTP) but can be mobilised by transfer factors. Strains carrying NTP13 produce colicin E1 and the EcoRI enzymes. This plasmid has a molecular weight of 6x10⁶ daltons and is present as approximately 12 copies per chromosome. The second plasmid, NTP14, was detected after mobilisation of the EcoRI plasmid with the R factor R1–19. NTP14 codes for ampicillin resistance, synthesis of the EcoRI enzymes and colicin E1. The molecular weight of NTP14 is 10.7x10⁶ daltons and there are about 14 copies per chromosome. DNA-DNA reassociation experiments were performed to determine the interrelationships of NTP13, NTP14, ColE1 and the R factor R1–19. NTP13 and NTP14 continue to replicate when cellular protein synthesis is inhibited by the addition of chloramphenicol.     

The long-term survival of Escherichia coli in river water

Escherichia coli introduced into autoclaved filtered river water survived for up to 260 d at temperatures from 4 degrees to 25 degrees C with no loss of viability. Survival times were less in water which was only filtered through either a Whatman filter paper or a 0.45 micron Millipore filter or in untreated water, suggesting that competition with the natural microbial flora of the water was the primary factor in the disappearance of the introduced bacteria. Survival was also dependent upon temperature with survival at 4 degrees C greater than 15 degrees C greater than 25 degrees C greater than 37 degrees C for any water sample. Direct counts showed that bacterial cells did not disappear as the viable count decreased. The possession of the antibiotic resistance plasmids, R1drd-19 or R144-3, did not enhance survival nor cause a faster rate of decay, indicating that the metabolic burden imposed by a plasmid was not a factor in survival under starvation conditions. There was no evidence of transfer of either plasmid at 15 degrees C or of loss of plasmid function during starvation.     

Curing effect of clorobiocin on Escherichia coli plasmids

Summary Clorobiocin, an inhibitor of the gyrB subunit of DNA gyrase, was used for the curing of some Escherichia coli plasmids. Of the plasmids studied, ampicillin resistant R28K and a miniplasmid derived from R1 drd-19 were effectively eliminated. We also succeeded in eliminating the ColA factor from E. coli strain B834 (pBS103), which was resistant to the effect of currently used curing agents. Although a derivative of ColE1-pBR322 was effectively cured by clorobiocin, the ColE1-plasmid was resistant to its effect. The ColV plasmid determining virulence was effectively eliminated.     

Zymogenic and enzymatic properties of the 70-80 loop mutants of factor X/Xa

The Ca(2+) binding 70-80 loop of factor X (fX) contains one basic (Arg(71)) and three acidic (Glu(74), Glu(76), and Glu(77)) residues whose contributions to the zymogenic and enzymatic properties of the protein have not been evaluated. We prepared four Ala substitution mutants of fX (R71A, E74A, E76A, and E77A) and characterized their activation kinetics by the factor VIIa and factor IXa in both the absence and presence of cofactors. Factor VIIa exhibited normal activity toward E74A and E76A and less than a twofold impaired activity toward R71A and E77A in both the absence and presence of tissue factor. Similarly, factor IXa in the absence of factor VIIIa exhibited normal activity toward both E74A and E76A; however, its activity toward R71A and E77A was impaired approximately two- to threefold. In the presence of factor VIIIa, factor IX activated all mutants with approximately two- to fivefold impaired catalytic efficiency. In contrast to changes in their zymogenic properties, all mutant enzymes exhibited normal affinities for factor Va, and catalyzed the conversion of prothrombin to thrombin with normal catalytic efficiencies. However, further studies revealed that the affinity of mutant enzymes for interaction with metal ions Na(+) and Ca(2+) was impaired. These results suggest that although charged residues of the 70-80 loop play an insignificant role in fX recognition by the factor VIIa-tissue factor complex, they are critical for the substrate recognition by factor IXa in the intrinsic Xase complex. The results further suggest that mutant residues do not play a specific role in the catalytic function of fXa in the prothrombinase complex.     

R-Factor Mutant Capable of Specifying Hypersynthesis of Penicillinase

The physical characteristics of a mutant, R(M201-2), capable of conferring high and stable ampicillion resistance was analyzed. The R(M201-2) and its parent R-factor deoxyribonucleic acid (DNA) could be isolated as an extrachromosomal and covalently closed circular form. Their buoyant densities were both 1.712 g/cm(3), and their molecular weights were about 82 x 10(6) and 64 x 10(6), respectively, when measured by CsCl and sucrose density gradient analyses. The contour lengths by electron microscopy were 35.9 +/- 0.6 and 31.0 +/- 0.6 mum, respectively. By using the extracted R-factor DNA, the mutant and parent characters were transformable to another Escherichia coli strain. The mutant R factor showed an increased amount of DNA even after conjugal transfer to Proteus. An increase in the size of R-factor DNA was thus considered to be the cause of the high level of ampicillin resistance.     

Colloidal clay inhibits conjugal transfer of R-plasmid R1drd-19 in Escherichia coli.

Colloidal clay (montmorillonite) strongly inhibited the conjugal transfer of R-plasmid R1drd-19 in Escherichia coli. This finding is discussed in the context of the feasibility of plasmid transfer in environmental waters.     

Cloning the origin of transfer region of the resistance plasmid R1

The insertion of a 7.7-kb EcoRI fragment of the resistance plasmid R1 into pBR325 yielded a plasmid which is mobilizable by pDB12, a multicopy derivative of R1drd-19 lacking most of the resistance determinants. The vector alone was not mobilizable in this system. From this observation we conclude that we have cloned the origin of transfer (oriT) of R1. After inserting a 5.3-kb PvuII-EcoRI fragment of the 7.7-kb region into pUC9 the DNA was cleaved randomly with DNaseI and BamHI linkers were attached to the ends. A subsequent BamHI digestion and electrophoretic separation of the resulting DNA molecules by their size allowed us to generate an ordered series of stepwise shortened plasmids. Plasmids with a deletion of approximately 3400 bp could no longer be mobilized. Since the next larger plasmid with 284 additional base pairs could be mobilized, we are able to confine the oriT location within this extra nucleotide stretch. The DNA sequence of this region was determined. Dominant features within the DNA region are a high AT content and five inverted repeats, which might function as recognition or substrate sites for proteins of the conjugational transfer system.     

Overexpression of the putative thiol conjugate transporter TbMRPA causes melarsoprol resistance in Trypanosoma brucei

Melaminophenyl arsenical drugs are a mainstay of chemotherapy against late-stage African sleeping sickness, but drug resistance is increasingly prevalent. We describe here the characterization of two genes encoding putative metal-thiol conjugate transporters from Trypanosoma brucei. The two proteins, TbMRPA and TbMRPE, were each overexpressed in trypanosomes, with or without co-expression of two key enzymes in trypanothione biosynthesis, ornithine decarboxylase and gamma-glutamyl-cysteine synthetase. Overexpression of gamma-glutamyl-cysteine synthetase resulted in a twofold increase in cellular trypanothione, whereas overexpression of ornithine decarboxylase had no effect on the trypanothione level. The overexpression of TbMRPA resulted in a 10-fold increase in the IC50 of melarsoprol. The overexpression of the trypanothione biosynthetic enzymes alone gave two- to fourfold melarsoprol resistance, but did not enhance resistance caused by MRPA. Overexpression of TbMRPE had little effect on susceptibility to melarsoprol but did give two- to threefold resistance to suramin.