Natural plasmid transformation in<Emphasis Type="Italic">Escherichia coli</Emphasis>

Although Escherichia coli does not have a natural transformation process, strains of E. coli can incorporate extracellular plasmids into cytoplasm 'naturally' at low frequencies. A standard method was developed in which stationary phase cells were concentrated, mixed with plasmids, and then plated on agar plates with nutrients which allowed cells to grow. Transformed cells could then be selected by harvesting cells and plating again on selective agar plates. Competence developed in the lag phase, but disappeared during exponential growth. As more plasmids were added to the cell suspension, the number of transformants increased, eventually reaching a plateau. Supercoiled monomeric or linear concatemeric DNA could transform cells, while linear monomeric DNA could not. Plasmid transformation was not related to conjugation and was recA-independent. Most of the E. coli strains surveyed had this process. All tested plasmids, except pACYC184, could transform E. coli. Insertion of a DNA fragment containing the ampicillin resistance gene into pACYC184 made the plasmid transformable. By inserting random 20-base-pair oligonucleotides into pACYC184 and selecting for transformable plasmids, a most frequent sequence was identified. This sequence resembled the bacterial interspersed medium repetitive sequence of E. coli, suggesting the existence of a recognition sequence. We conclude that plasmid natural transformation exists in E. coli.     

Amikacin resistance of clinical strains of Enterobacteriaceae and Pseudomonas]

Amikacin resistance was studied in 380 bacterial strains of Enterobacter, Klebsiella, Serratia, Pseudomonas and E. coli isolated in clinics of the Moscow Region. It was shown that 69 isolates were resistant to amikacin. Plasmid DNA was detected in 10 amikacin resistant isolates. Three of them belonging to Klebsiella and 3 belonging to E. coli contained plasmids controlling resistance to amikacin. The plasmids isolated from the strains of Klebsiella determined as well resistance to kanamycin and streptomycin but did not control resistance to sisomicin, tobramycin and gentamicin while the plasmids isolated from the strains of E. coli determined resistance to amikacin, kanamycin, gentamicin, tobramycin and sisomicin.     

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.     

Glycogen is the primary source of glucose during the lag phase of E. coli proliferation

In the studies of Escherichia coli (E. coli), metabolomics analyses have mainly been performed using steady state culture. However, to analyze the dynamic changes in cellular metabolism, we performed a profiling of concentration of metabolites by using batch culture. As a first step, we focused on glucose uptake and the behavior of the first metabolite, G6P (glucose-6-phosphate). A computational formula was derived to express the glucose uptake rate by a single cell from two kinds of experimental data, extracellular glucose concentration and cell growth, being simulated by Cell Illustrator. In addition, average concentration of G6P has been measured by CE-MS. The existence of another carbon source was suggested from the computational result. After careful comparison between cell growth, G6P concentration, and the computationally obtained curve of glucose uptake rate, we predicted the consumption of glycogen in lag phase and its accumulation as an energy source in an E. coli cell for the next proliferation. We confirmed our prediction experimentally. This behavior indicates the importance of glycogen participation in the lag phase for the growth of E. coli. This article is part of a Special Issue entitled: Computational Methods for Protein Interaction and Structural Prediction.     

Content of DNA in cells of Escherichia coli carrying standard R-plasmids

DNA content was studied in Escherichia coli K12 cells carrying conjugative R plasmids. Cultures at the exponential growth phase were used for the fractionation of nucleic acids. The content of total and chromosomal DNA was found to be much lower in the presence of R plasmids than in the strain carrying no plasmids. The content of RNA also decreased in the cells of E. coli in the presence of R plasmids.     

Modelling the work to be done by Escherichia coli to adapt to sudden temperature upshifts

AIMS: This paper studies and models the effect of the amplitude of a sudden temperature upshift DeltaT on the adaptation period of Escherichia coli, in terms of the work to be done by the cells during the subsequent lag phase (i.e., the product of growth rate mumax and lag phase duration lambda). METHODS AND RESULTS: Experimental data are obtained from bioreactor experiments with E. coli K12 MG1655. At a predetermined time instant during the exponential growth phase, a sudden temperature upshift is applied (no other environmental changes take place). The length of the (possibly) induced lag phase and the specific growth rate after the shift are quantified with the growth model of Baranyi and Roberts (Int J Food Microbiol 23, 1994, 277). Different models to describe the evolution of the product lambda x mumax as a function of the amplitude of the temperature shift are statistically compared. CONCLUSIONS: The evolution of lambda x mumax is influenced by the amplitude of the temperature shift DeltaT and by the normal physiological temperature range. As some cut-off is observed, the linear model with translation is preferred to describe this evolution. SIGNIFICANCE AND IMPACT OF THE STUDY: This work contributes to the characterization of microbial lag phenomena, in this case for E. coli K12 MG1655, in view of accurate predictive model building.     

Design and synthesis of a quintessential self-transmissible IncX1 plasmid, pX1.0

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.     

Inhibition of the maintenance and transfer of antibiotic-resistance plasmids by quinolones

The role of quinolones in the maintenance and transfer of antibiotic resistance plasmids was investigated. Curing effect of eleven quinolones, at subinhibitory concentrations, was studied on Escherichia coli strains harbouring ten plasmids belonging to different incompatibility groups. R386, R446b and S-a were the only plasmids eliminated by all the quinolones at a rate between 0.5 to 16%. The best culture medium was human urine. A total inhibition of transfer of RP4 plasmid between two Escherichia coli strains was obtained with nalixidic and oxolinic acids and flumequin. A partial inhibition was observed with other quinolones.     

Persistence of pBR322-related plasmids in Escherichia coli grown in chemostat cultures

Abstract The stability of plasmid pBR322 and a number of close derivatives was examined by continuous culture of Escherichia coli . Cultures were subjected to either glucose, phosphate or magnesium limitation in non-selective medium at a dilution rate of 0.1/h. Under these conditions pBR322 was eventually lost from the population, but only after a distinct lag period. The closely related plasmids pBR325 and especially pBR327 and pBR328, but not pAT153, were lost more rapidly. Three cosmids pHC79, pSJ55 and pJB8 were generally found to be less stable than the pBR322-type plasmids from which they were derived. Chimaeric plasmids containing DNA from yeast and from a thermophilic bacillus were also unstable in E. coli .     

Control of methionine biosynthesis in Escherichia coli K12: a closer study with analogue-resistant mutants

Control of methionine biosynthesis in Escherichia coli K12 was reinvestigated by using methionine-analogue-resistant mutants. Norleucine (NL) and alpha-methylmethionine (MM) were found to inhibit methionine biosynthesis directly whereas ethionine (Et) competitively inhibited methionine utilization. Adenosylation of Et to generate S-adenosylethionine (AdoEt) by cell-free enzyme from E. coli K12 was demonstrated. Tolerance of increasing concentrations of NL by E. coli K12 mutants is expressed serially as phenotypes NLR, NLREtR, NLRMMR and finally NLREtRMMR. All spontaneous NLR mutants had a metK mutation, whereas NTG-induced mutants had mutations in both the metK and metJ genes. The kinetics of methionine adenosylation by the E. coli K12 cell-free enzyme were found to be similar to those reported for the yeast enzyme, showing the typical lag phase at low methionine concentration and disappearance of this phase when AdoMet was included in the incubation mixture. NL extended the lag phase, and lowered the rate of subsequent methionine adenosylation, but did not affect the shortening of the lag phase of adenosylation by AdoMet.     

Hemolysis determinant common to Escherichia coli hemolytic plasmids of different incompatibility groups

By using cloned deoxyribonucleic acid fragments from the hemolysis determinant of the hemolytic plasmid pHly152 as hybridization probes, a deoxyribonucleic acid segment of about 3.8 megadaltons was identified as a common sequence in several hemolytic (Hly) plasmids of Escherichia coli belonging in four different incompatibility groups. This segment contained the genetic information for the synthesis and secretion of the extracellular toxin alpha-hemolysin of E. coli. With the exception of pSU5, representing a composite plasmid, one part of which seems to be very similar to pHly152, the overall sequence homology of these Hly plasmids with pHly152 seems to be rather restricted. However, the Hly plasmid pSU316 showed sequence homology with pHly152 that did not extend beyond the hemolysis determinant. The two other plasmids, pSU233 and pSU105, also shared homology with pHly152 in the hemolysis determinant as well as in various other parts of this plasmid which did not seem to be directly linked to the hemolysis determinant. This suggests that the hemolysis determinant has spread to presumably unrelated plasmids of E. coli.     

Monitoring the spread of broad host and narrow host range plasmids in soil microcosms

Abstract: Escherichia coli recipient and E. coli donor strains carrying streptothricin-resistance genes were inoculated together into different soil microcosms. These genes were localized on the narrow host range plasmids of incompatibility (Inc) groups FII, Il, and on the broad host range plasmids of IncP1, IncN, IncW3, and IncQ. The experiments were intended to study the transfer of these plasmids in sterile and non-sterile soil with and without antibiotic selective pressure and in planted soil microcosms. Transfer of all broad host range plasmids from the introduced E. coli donor into the recipient was observed in all microcosm experiments. These results indicate that broad host range plasmids encoding short and rigid pili might spread in soil environments by conjugative transfer. In contrast, transfer of the narrow host range plasmids of IncFII and IncI1, into E. coli recipients was not found in sterile or non-sterile soil. These plasmids encoded flexible pili or flexible and rigid pili, respectively. In all experiments highest numbers of transconjugants were detected for the IncP1-plasmid (pTH16). There was evidence with plasmids belonging to IncP group transferred by conjugation into a variety of indigenous soil bacteria at detectable frequencies. Significantly higher numbers of indigenous transconjugants were obtained for the IncP-plasmid under antibiotic selection pressure, and a greater diversity of transconjugants was detected. Availability of nutrients and rhizosphere exudates stimulated transfer in soil. Furthermore, transfer of the IncN-plasmid (pIE1037) into indigenous bacteria of the rhizosphere community could be detected. The transconjugants were determined by BIOLOG as Serratia liquefaciens . Despite the known broad host range of IncW3 and IncQ-plasmids, transfer into indigenous soil bacteria could not be detected.     

Physical and genetic analysis of the ColD plasmid.

The plasmid ColD-CA23, a high-copy-number plasmid of 5.12 kilobases, encodes colicin D, a protein of approximately 87,000 daltons which inhibits bacterial protein synthesis. Colicin D production is under the control of the Escherichia coli SOS regulatory system and is released to the growth medium via the action of the lysis gene product(s). A detailed map of the ColD plasmid was established for 10 restriction enzymes. Using in vitro insertional omega mutagenesis and in vivo insertional Tn5 mutagenesis, we localized the regions of the plasmid responsible for colicin D activity (cda), for mitomycin C-induced lysis (cdl), and for colicin D immunity (cdi). These genes were all located contiguously on a 2,400-base-pair fragment similar to a large number of other Col plasmids (A, E1, E2, E3, E8, N, and CloDF). The ColD plasmid was mobilizable by conjugative transfer by helper plasmids of the IncFII incompatibility group, but not by plasmids belonging to the groups IncI-alpha or IncP. The location of the mobilization functions was determined by deletion analysis. The plasmid needs a segment of 400 base pairs, which is located between the mob genes and the gene for autolysis, for its replication.     

AgNO3对大肠杆菌和金黄色葡萄球菌的抗菌作用及机制

以大肠杆菌和金黄色葡萄球菌为模式菌,对AgNO3的抗菌效果进行研究,并对其抗菌机制作初步探讨。AgNO3对大肠杆菌的抑制生长曲线表明:2.891 mg/L的AgNO3能够完全抑制106个/mL的大肠杆菌细胞生长,AgNO3使大肠杆菌和金黄色葡萄球菌的延滞期加长,并且浓度越高,延滞期越长。另外,AgNO3对大肠杆菌和金黄色葡萄球菌脱氢酶的活性有明显影响,随着AgNO3浓度的提高,脱氢酶的活性逐渐降低。AgNO3溶液作用于细菌后,细菌表面疏水性均有不同程度地下降,且浓度越大对其影响也越明显,大肠杆菌的下降程度要大于金黄色葡萄球菌。     

Plasmid transfer and behaviour in Acinetobacter calcoaceticus EBF65/65

At least one plasmid from each of the incompatibility groups B, C, FIV, H2/S, I alpha, I delta, P, W and X was shown to be capable of transfer from Escherichia coli K12 to Acinetobacter calcoaceticus EBF65/65. Transfer was influenced by the presence of pAV2 (thought to encode a restriction-modification system) in the recipient strain; however, not all plasmids belonging to a particular incompatibility group behaved identically. All plasmids were unstable to varying degrees in A. calcoaceticus EBF65/65, but under suitable conditions were capable of transfer to further strains of EBF65/65 and re-transfer to E. coli K12. Of 40 recently isolated trimethoprim R plasmids 31 transferred successfully from E. coli K12 to A. calcoaceticus EBF65/65, but 17 of these 31 required the introduction of a second mobilizing plasmid for re-transfer to occur.     

Growth of Salmonella typhimurium in Skim Milk Concentrates

The influence of various levels of skim milk solids and temperature on the duration of lag phase, growth rate, and extent of growth of Salmonella typhimurium was investigated. The effect on growth of salmonellae (and a strain of Escherichia coli) of reduced pressure at a constant solids level and under conditions simulating vacuum condensation of skim milk was also studied. S. typhimurium grew when inoculated into skim milk solutions ranging from 10 to 60% solids and over a temperature range of 23 to 44 C. At 10 to 12 C, growth was evident only in the 10% skim milk. As the total solids level was increased or incubation temperature was deviated from the optimum, or both, there was an increase in the lag phase and generation time of salmonellae. A lower cell population also resulted. The generation time at 37 C of S. typhimurium incubated at atmospheric pressure was approximately one-half that in skim milk concentrates held under reduced pressure. In addition, a slightly longer lag phase and lower cell yield characterized the growth under reduced pressure. Concentration of skim milk had little or no effect on viability of salmonellae or E. coli when the vapor temperature in the vacuum pan was below the maximum growth temperature for salmonellae. Increasing the vapor temperature to 48 C caused a two-log reduction in viable organisms during the concentrating period (65 min).     

The yefM-yoeB toxin-antitoxin systems of Escherichia coli and Streptococcus pneumoniae: functional and structural correlation

Toxin-antitoxin loci belonging to the yefM-yoeB family are located in the chromosome or in some plasmids of several bacteria. We cloned the yefM-yoeB locus of Streptococcus pneumoniae, and these genes encode bona fide antitoxin (YefM(Spn)) and toxin (YoeB(Spn)) products. We showed that overproduction of YoeB(Spn) is toxic to Escherichia coli cells, leading to severe inhibition of cell growth and to a reduction in cell viability; this toxicity was more pronounced in an E. coli B strain than in two E. coli K-12 strains. The YoeB(Spn)-mediated toxicity could be reversed by the cognate antitoxin, YefM(Spn), but not by overproduction of the E. coli YefM antitoxin. The pneumococcal proteins were purified and were shown to interact with each other both in vitro and in vivo. Far-UV circular dichroism analyses indicated that the pneumococcal antitoxin was partially, but not totally, unfolded and was different than its E. coli counterpart. Molecular modeling showed that the toxins belonging to the family were homologous, whereas the antitoxins appeared to be specifically designed for each bacterial locus; thus, the toxin-antitoxin interactions were adapted to the different bacterial environmental conditions. Both structural features, folding and the molecular modeled structure, could explain the lack of cross-complementation between the pneumococcal and E. coli antitoxins.     

Growth in cadmium-containing medium induces resistance to heat in E. coli

We have shown that 10 microM Cd2+ in the growth medium can induce resistance to subsequent heat treatment in E. coli B/r. Resistance was shown by cells during an extended lag phase and, especially, during log phase. The results contrast with the effect of Cd2+ exposure on radiation lethality, for which sensitization was previously reported in cells from lag and stationary phase cultures.     

Dynamic cellular location of bacterial plasmids

Recent studies have shown that plasmids are organized inside bacterial cells in a remarkably complex way. Plasmids containing active partitioning systems are tethered to specific regions of the cell, and the number and position of plasmid molecules within the cell are coordinated with the bacterial host cell cycle and growth rate. Plasmids belonging to different incompatibility groups are also tethered to different sites within the cell, and segregate at different times relative to one another and to the bacterial cell cycle. Recent studies suggest that many of these observations regarding subcellular plasmid dynamics formulated for Escherichia coli plasmids may be broadly conserved.     

Competition for proline between indigenous Escherichia coli and E. coli O157:H7 in gnotobiotic mice associated with infant intestinal microbiota and its contribution to the colonization resistance against E. coli O157:H7

Previously, we produced two groups of gnotobiotic mice, GB-3 and GB-4, which showed different responses to Escherichia coli O157:H7 challenge. E. coli O157:H7 was eliminated from GB-3, whereas GB-4 mice became carriers. It has been reported that the lag time of E. coli O157:H7 growth in 50% GB-3 caecal suspension was extended when compared to GB-4 caecal suspension. In this study, competition for nutrients between intestinal microbiota of GB-3 and GB-4 mice and E. coli O157:H7 was examined. Amino acid concentrations in the caecal contents of GB-3 and GB-4 differed, especially the concentration of proline. The supplementation of proline into GB-3 caecal suspension decreased the lag time of E. coli O157:H7 growth in vitro. When E. coli O157:H7 was cultured with each of the strains used to produce GB-3 mice in vitro, 2 strains of E. coli (proline consumers) out of 5 enterobacteriaceae strains strongly suppressed E. coli O157:H7 growth and the suppression was attenuated by the addition of proline into the medium. These results indicate that competition for proline with indigenous E. coli affected the growth of E. coli O157:H7 in vivo and may contribute to E. coli O157:H7 elimination from the intestine.