Generation of a restriction minus enteropathogenic <Emphasis Type="Italic">Escherichia coli</Emphasis> E2348/69 strain that is efficiently transformed with large,low copy plasmids

Background  

Many microbes possess restriction-modification systems that protect them from parasitic DNA molecules. Unfortunately, the presence of a restriction-modification system in a given microbe also hampers genetic analysis. Although plasmids can be successfully conjugated into the enteropathogenic Escherichia coli strain E2348/69 and optimized protocols for competent cell preparation have been developed, we found that a large, low copy (~15) bioluminescent reporter plasmid, pJW15, that we modified for use in EPEC, was exceedingly difficult to transform into E2348/69. We reasoned that a restriction-modification system could be responsible for the low transformation efficiency of E2348/69 and sought to identify and inactivate the responsible gene(s), with the goal of creating an easily transformable strain of EPEC that could complement existing protocols for genetic manipulation of this important pathogen.     

Cloning and expression in Escherichia coli of the BanI and BanIII restriction-modification systems from Bacillus aneurinolyticus

The genes coding for the GGPyPuCC-specific (BanI) and ATCGAT-specific (BanIII) restriction-modification systems of Bacillus aneurinolyticus IAM1077 were cloned and expressed in Escherichia coli using pBR322 as a vector. The plasmids carrying the BanI and BanIII restriction-modification genes were designated pBanIRM8 and pBanIIIRM12, respectively. The restriction maps of these recombinant plasmids were constructed. These two plasmids were stably maintained in E. coli HB101. However, when E. coli JM109 was used as a host, pBanIIIRM12 was efficiently propagated but pBanIRM8 was not. The HB101 cells carrying only the restriction gene of BanIII were viable, but the BanI restriction gene carrier could not form colonies on agar plates. The growth of bacteriophage λ was strongly restricted only in the F. coli HB101 cells harboring pBanIRM8. These facts indicate that the BanI restriction enzyme is expressed and functions more efficiently than BanI modification enzyme in E. coli.     

Transfer of RP4::Mu plasmids to Agrobacterium tumefaciens

Transfers of RP4::Mu plasmids from Escherichia coli to Agrobacterium tumefaciens are very inefficient in contrast to the very efficient transfer of RP4. Apparently, one or more Mu functions prevent RPR::Mu plasmids from establishing in some Gram-negatives other than E. coli. This problem was eliminated by the use of a mutant Mu prophage, Mu cts62r23, in RP4. Moreover, the transfer of RP4::Mu cts62r23 to the Agrobacterium strain C58 was found to be affected by a restriction modification system. The target for this restriction was located on Mu DNA and not on RP4 DNA. The plaque-forming phage production of Mu cts62r23 in Agrobacterium was found to be 10⁶ times lower than in E. coli.     

Plasmid pEC156, a Naturally Occurring Escherichia coli Genetic Element That Carries Genes of the EcoVIII Restriction-Modification System,Is Mobilizable among Enterobacteria

Type II restriction-modification systems are ubiquitous in prokaryotes. Some of them are present in naturally occurring plasmids, which may facilitate the spread of these systems in bacterial populations by horizontal gene transfer. However, little is known about the routes of their dissemination. As a model to study this, we have chosen an Escherichia coli natural plasmid pEC156 that carries the EcoVIII restriction modification system. The presence of this system as well as the cis-acting cer site involved in resolution of plasmid multimers determines the stable maintenance of pEC156 not only in Escherichia coli but also in other enterobacteria. We have shown that due to the presence of oriT-type F and oriT-type R64 loci it is possible to mobilize pEC156 by conjugative plasmids (F and R64, respectively). The highest mobilization frequency was observed when pEC156-derivatives were transferred between Escherichia coli strains, Enterobacter cloacae and Citrobacter freundii representing coliform bacteria. We found that a pEC156-derivative with a functional EcoVIII restriction-modification system was mobilized in enterobacteria at a frequency lower than a plasmid lacking this system. In addition, we found that bacteria that possess the EcoVIII restriction-modification system can efficiently release plasmid content to the environment. We have shown that E. coli cells can be naturally transformed with pEC156-derivatives, however, with low efficiency. The transformation protocol employed neither involved chemical agents (e.g. CaCl₂) nor temperature shift which could induce plasmid DNA uptake.     

Effect of recB- and recA-mutations on phage restriction in various modification-restriction plasmid systems of E. coli

The effect of recB and recA mutations on lambda vir and P1 vir restriction by different restriction-modification plasmid systems of E. coli was studied. It was shown that effect of R1 plasmid coded restriction-modification in E. coli K12 and E. coli B strains and pJA4620 plasmid coded restriction in E. coli K12 is observed only in RecB+ strain. Phenomenon of restriction-modification determined by R124, R245 plasmids does not depend of recB mutation. Effect of recA mutation has not been found in cultures harbouring R1, R245, R124 pJA4620 plasmids.     

Antirestriction

Modern data on the molecular mechanisms of antirestriction are reviewed. The systems of inhibition are described for the restriction-modification enzymes of type I in phages and in conjugative plasmids. The phenomenon of alleviation of DNA restriction and its mechanisms is presented for bacteriumEscherichia coli. The principle of protein mimicry of nucleic acids is discussed as a novel way to control biological processes in the cell with reference to antirestriction proteins Ard.     

Analysis of chromosome mobilization using hybrids between plasmid RP4 and a fragment of bacteriophage λ carrying IS1

In vitro recombination was used to generate RP4 plasmids with an inserted restriction fragment of bateriophage λ. In some cases the λ DNA also carried the insertion sequence IS1. Comparisons were made between the abilities of these plasmids to mobilize the Escherichia coli K-12 chromosome in different genetic backgrounds. RP4-borne IS1 acting alone promoted chromosome transfer but with an efficiency 1% of that resulting from more extensive plasmid-chromosome homology. A recA mutation in the donor depressed the mobilization frequency below the level of detection. Correlation of the direction of chromosome transfer and the orientation of the cloned λ DNA allowed the direction of RP4 transfer to be determined. Studies on recombinants showed that in general they also acquired an intact, autonomous plasmid, suggesting the process of mobilization by RP4 may differ in certain features from chromosome transfer by F.     

Protein synthesis induced by infection with packaged λdv plasmid

Plasmid λdv or imm²¹dv DNA was joined to a λ arm having a cos site. This recombinant plasmid can be packaged in a λ head, and used to infect Escherichia coli K12 cells. The injected DNA molecules become plasmids in cells. By adding these particles to uv-irradiated uvrA cells, the packageable λdv or imm²¹dv plasmids can be induced to synthesize proteins coded by genes on the plasmid genome. The packageable plasmid system is thus suitable for studying on synthesis and regulation of plasmid-coded biopolymers. Analyses of the dv-coded proteins in gel electrophoreses revealed that among several genes carried on the dv plasmid genome, only those genes that are members of the pRoR-tof-cII-O-P operon can be expressed. Evidence has been presented to show that expression of this operon, which is directly correlated with replication of the genome, is only partially allowed in cells perpetuating the dv plasmid. These observations are discussed in connection with the autorepressor model (D. E. Berg, 1974, Virology 62, 224–233; K. Matsubara, 1976, J. Mol. Biol. 102, 427–439) that genetically accounts for the control mechanism of plasmid replication.     

A Mimicking-of-DNA-Methylation-Patterns Pipeline for Overcoming the Restriction Barrier of Bacteria

Genetic transformation of bacteria harboring multiple Restriction-Modification (R-M) systems is often difficult using conventional methods. Here, we describe a mimicking-of-DNA-methylation-patterns (MoDMP) pipeline to address this problem in three difficult-to-transform bacterial strains. Twenty-four putative DNA methyltransferases (MTases) from these difficult-to-transform strains were cloned and expressed in an Escherichia coli strain lacking all of the known R-M systems and orphan MTases. Thirteen of these MTases exhibited DNA modification activity in Southwestern dot blot or Liquid Chromatography–Mass Spectrometry (LC–MS) assays. The active MTase genes were assembled into three operons using the Saccharomyces cerevisiae DNA assembler and were co-expressed in the E. coli strain lacking known R-M systems and orphan MTases. Thereafter, results from the dot blot and restriction enzyme digestion assays indicated that the DNA methylation patterns of the difficult-to-transform strains are mimicked in these E. coli hosts. The transformation of the Gram-positive Bacillus amyloliquefaciens TA208 and B. cereus ATCC 10987 strains with the shuttle plasmids prepared from MoDMP hosts showed increased efficiencies (up to four orders of magnitude) compared to those using the plasmids prepared from the E. coli strain lacking known R-M systems and orphan MTases or its parental strain. Additionally, the gene coding for uracil phosphoribosyltransferase (upp) was directly inactivated using non-replicative plasmids prepared from the MoDMP host in B. amyloliquefaciens TA208. Moreover, the Gram-negative chemoautotrophic Nitrobacter hamburgensis strain X14 was transformed and expressed Green Fluorescent Protein (GFP). Finally, the sequence specificities of active MTases were identified by restriction enzyme digestion, making the MoDMP system potentially useful for other strains. The effectiveness of the MoDMP pipeline in different bacterial groups suggests a universal potential. This pipeline could facilitate the functional genomics of the strains that are difficult to transform.     

A type IV modification-dependent restriction enzyme SauUSI from Staphylococcus aureus subsp. aureus USA300

A gene encoding a putative DNA helicase from Staphylococcus aureus USA300 was cloned and expressed in Escherichia coli. The protein was purified to over 90% purity by chromatography. The purified enzyme, SauUSI, predominantly cleaves modified DNA containing 5mC and 5-hydroxymethylcytosine. Cleavage of 5mC-modified plasmids indicated that the sites S5mCNGS (S = C or G) are preferentially digested. The endonuclease activity requires the presence of adenosine triphosphate (ATP) or dATP whereas the non-hydrolyzable γ-S-ATP does not support activity. SauUSI activity was inhibited by ethylenediaminetetraacetic acid. It is most active in Mg⁺⁺ buffers. No companion methylase gene was found near the SauUSI restriction gene. The absence of a cognate methylase and cleavage of modified DNA indicate that SauUSI belongs to type IV restriction endonucleases, a group that includes EcoK McrBC and Mrr. SauUSI belongs to a family of highly similar homologs found in other sequenced S. aureus, S. epidermidis and S. carnosus genomes. More distant SauUSI orthologs can be found in over 150 sequenced bacterial/archaea genomes. Finally, we demonstrated the biological function of the type IV REase in restricting 5mC-modified plasmid DNA by transformation into clinical S. aureus strain SA564, and in restricting phage λ infection when the endonuclease is expressed in E. coli.     

Strains of Escherichia coli carrying the structural gene for histidyl-tRNA synthetase on a high copy-number plasmid

Summary That portion of the Escherichia coli chromosome caried by a number of lambda transducing phages, all of which carry the gua operon, wss mapped using restriction endonucleases. The DNA from one of these transducing phages was subcloned onto pBR322. We have identified two recombinant plasmids which carry the Escherichia coli gene hisS, the structural gene for histidyl-tRNA synthetase. The two plasmids, pSE301 and pSE401, have in common a 3,540 bp fragment of E. coli DNA which is bounded by BglII and SalI restriction endonuclease recognition sites. Strains carrying these plasmids overproduce histidyl-tRNA synthetase 20 to 30 fold. The growth rate of these strains is not affected although the histidine biosynthetic enzymes are derepressed. This derepression seems to be in addition to that caused by introduction of a hisT mutation on the chromosome.     

Restriction-modification systems determined by Pseudomonas plasmids

Four additional Pseudomonas R plasmids determining the PaeR7 restriction-modification system have been detected. All are transfer deficient and appear to belong to the same incompatibility group. The Pseudomonas fertility plasmid FP110 determines a different restriction-modification system and also inhibits the propagation of phage B39 by a separate mechanism. Pseudomonas R plasmid pMG73 has a third distinct restriction-modification specificity. PaeFP110 and PaeR73 are proposed as designations for these new plasmid-determined systems for restriction and modification.     

The restriction-modification system in Streptomyces flavopersicus

To clone bifunctional vectors in streptomycetes, it was necessary to define the restriction-modification system ofStreptomyces flavopersicus. Plasmid DNA from bifunctional vectors pIJ699 and pXED3-13, isolated fromE. coli strains with different methylation systems:E. coli DH5α (dam ⁺ dcm ⁺),E. coli MB5386(dam dcm), E. coli CB51 (dam dcm ⁺),E. coli NM544 (dam ⁺ dcm), was used for transformation of protoplasts from strainS. flavopersicus. Restriction ofdcm-methylated DNA fromS. flavopersicus was established. As a host in the intermediate cloning strainE. coli NM544 (dam ⁺ dcm) should be used, as thedcm-transmethylase-dependent strainS. flavopersicus does not process DNA from this strain.     

Bacteriophage lambda-E. coli K12 vector-host system for gene cloning and expression under lactose promoter control. II. DNA fragment insertion at the vicinity of the lac UV5 promoter.

Summary Recombinant plasmids containing the entire 16S RNA gene from the rrn B cistron of E. coli inserted in Col E1 and pBR322 plasmid vectors have been constructed. These plasmids have been mapped using several restriction endonucleases as well as by DNA-RNA hybridization. These maps reveal previously undetected restriction sites in the rrn B cistron and in Col E1 plasmid DNA.     

Cloning in Escherichia coli of genes involved in the synthesis of proline and leucine in Desulfovibrio desulfuricans Norway

Summary A library of Deusulfovibrio desulfuricans Norway genomic DNA was constructed in Escherichia coli with pBR322 as vector and plasmids able to complement the proA and leuB mutations of the host were screened. It was observed that all the plasmids studied were highly unstable, the insert DNA being rapidely lost under non-selective growth conditions. A 2.75 kb DNA fragment of D. desulfuricans Norway was found to complement E. coli ProA, ProB and ProC deficiencies. From the results of restriction analysis and Southern hybridization, it is proposed that the genes involved in proline and leucine biosynthesis are clustered on the chromosome of D. desulfuricans Norway.     

Comparative analysis of antirestriction activity of the ArdA and ArdB proteins encoded by genes of the R64 transmissible plasmid (IncI1)

Antirestriction proteins ArdA and ArdB are specific inhibitors of type I restriction-modification enzymes. The ardA and yfeB (ardB) genes were cloned from the transmissible plasmid R64 in the pUC18 and pZE21 vectors. The R64 ArdA and ArdB proteins were shown to inhibit only restriction activity of the type I restriction-modification enzyme (EcoKI) in Escherichia coli K12 cells. In contrast to ArdA, ArdB inhibited EcoKI restriction activity only at a high intracellular concentration. Antirestriction activity of ArdB did not depend on the ClpXP protease. The yfeB (ardB) gene of the R64 plasmid is transcribed from a weak promoter located upstream of yfeA.     

The use of plasmid R1162 and derivatives for gene cloning in the methanol-utilizing Pseudomonas AM1

Summary A physical map for plasmid R1162 (Sm, Su, IncP4) was constructed. Neither EcoRI, PstI nor EcaI cut within a region essential for replication, mobilization or streptomycin resistence. Plasmid R1162 can replicate in E. coli as well as in Pseudomonas species and shows a strong dependence for DNA polymerase I in E. coli. By RP4 induced mobilization, R1162 can be transferred from E. coli to Pseudomonas AM1. A hybrid plasmid pFG7 (MW=8.4×10⁶, Sm, Su, Ap, Tc) was constructed between pBR322 and R1162, which allows the selection of hybrid plasmids by insertional inactivation with the restriction enzymes HindIII, BamHI, SalI, ClaI. Transformation of E. coli SK1592 with EcaI-cut and ligated R1162-DNA and Pseudomonas AM1-DNA and subsequent mobilization of the hybrid plasmids into Pseudomonas AM1/M15a (methanol dehydrogenase^-) led to the isolation of Pseudomonas AM1/M15a colonies, which could grow on methanol again. Back-conjugation into E. coli SK1592, subsequent mobilization studies and plasmid analysis suggests that the gene for Pseudomonas methanol dehydrogenase has been cloned in this vector.     

Cloning of two protease genes fromRhodocyclus gelatinosa APR 3-2 and their expression inEscherichia coli

Two different protease genes were cloned fromRhodocyclus gelatinosa APR 3-2 inEscherichia coli HB 101/ with pBR329 or its derivatives. The recombinant plasmids designated as pRP100 and pRP300 contained 11.2 and 10.6 kb DNA fragments, respectively. The differences of both plasmids in restriction enzyme maps indicate that these plasmids contained different protease genes. DNA fragments coding for protease, 6.4 kb and 4.5 kb from pRP100 and pRP300, were subcloned into pRP329 and designated as pRP101 and pRP301, respectively. The two cloned proteases were excreted in culture medium ofE. coli, and ß-lactamase ofE. coli, which was originally localized in periplasmic space, was also excreted in the medium.     

Damage and mutagenesis of E. coli and bacteriophage λ induced by oxathiolane and aziridinyl steroids

λ-Escherichia coli complexes exhibited remarkable sensitivity to the treatment with test steroidal derivatives in the presence of Cu(II). The decline in plaque-forming units after steroid treatment was more pronounced in complexes with some of the irradiation repair-defective mutants of E. coli K-12, i.e., recA, lexA and polA, as compared to uvrA and wild-type strains. The red gene of λ phage and recA gene of E. coli seem to have a complementary effect on the steroid-induced lesions. An enhanced level of mutagenesis was observed when steroid-treated E. coli cells were transformed with steroid-treated pBR322 plasmid DNA. A remarkable degree of c mutation was also observed when steroid I-treated phage particles were allowed to adsorb on steroid-treated wild-type bacteria. Moreover, the oxathione steroid treatment of λcI857-E. coli lysogen resulted in prophage induction in nutrient broth even at 32°C. Thus on the basis of these results, the role of SOS repair system in steroid-induced mutagenesis and repair of DNA lesions in E. coli and bacteriophage λ has been suggested.     

Efficient Transformation System for Propionibacterium freudenreichii Based on a Novel Vector

A 3.6-kb endogenous plasmid was isolated from a Propionibacterium freudenreichii strain and sequenced completely. Based on homologies with plasmids from other bacteria, notably a plasmid from Mycobacterium, a region harboring putative replicative functions was defined. Outside this region two restriction enzyme recognition sites were used for insertion of an Escherichia coli-specific replicon and an erythromycin resistance gene for selection in Propionibacterium. Hybrid vectors obtained in this way replicated in both E. coli and P. freudenreichii. Whereas electroporation of P. freudenreichii with vector DNA isolated from an E. coli transformant yielded 10 to 30 colonies per μg of DNA, use of vector DNA reisolated from a Propionibacterium transformant dramatically increased the efficiency of transformation (≥10⁸ colonies per μg of DNA). It could be shown that restriction-modification was responsible for this effect. The high efficiency of the system described here permitted successful transformation of Propionibacterium with DNA ligation mixtures.