A suitable method for construction and cloning hybrid plasmids containing EcoRI-fragments of E. coli genome.

Summary A convenient procedure for the isolation of specificEcoRI-fragments ofE. coli genome and their amplification on Km-resistance plasmid vector CK 11 is described. The hybrid molecules were constructedin vitro usingEcoRI-digestion, followed by ligation. Then appropriatedE. coli strain was transformed with ligated DNA mixture and hybrid plasmids CK 11-arg ⁺, CK 11-his ⁺, CK 11-thr ⁺ and CK 11-leu ⁺ containing loci ofE. coli genome were selected by molecular cloning. The hybrid plasmids obtained consisted of oneEcoRI-fragment of initial plasmid CK 11 and one respective specific portion ofE. coli genome.     

Electroporation and stable maintenance of plasmid DNAs in a biocontrol strain of Pseudomonas syringae

Transformation efficiencies as high as 10⁷ transformants g^–1 DNA have been previously reported for pseudomonads using electroporation protocols established for E. coli with plasmid DNAs prepared from methylation proficient E. coli hosts. We report here a protocol for electroporation of plasmid DNAs into a biocontrol strain of Pseudomonas syringae which could not be electroporated by standard E. coli methods. Transformation efficiencies of 10⁷ or higher were obtained with DNA recovered from initial P. syringae transformation or with DNA prepared from methylation deficient E. coli. Both plasmids used in this study were stably maintained in the absence of selection for at least 50 generations.     

Cloning of the tyrocidine synthetase 1 gene from Bacillus brevis and its expression in Escherichia coli

Summary The entire structural gene for tyrocidine synthetase 1 from Bacillus brevis ATCC 8185 has been cloned and expressed in Escherichia coli. Transformed E. coli cells were screened for their ability to produce tyrocidine synthetase 1 by in situ immunoassay using antibodies against gramicidin S synthetase 2 which cross-react with tyrocidine synthetase 1. The cloned gene is within a 5.2 kb fragment of B. brevis genomic DNA and requires no external promoter for its expression in E. coli. It was also observed that cloning of the 5.2 kb insert in the opposite orientation still resulted in a high level of tyrocidine synthetase 1 expression in transformed E. coli cells. In addition, protein blotting and partial purification of the gene product by gel filtration revealed a major protein of molecular weight about 100,000 with specific d-phenylalanine dependent ATP-³²PP_i and 2deoxy ATP-³²PP_i exchange activities. These unique activities of tyrocidine synthetase 1 were not detected in protein extracts of E. coli strains carrying the vector.     

Intergeneric conjugal transfer of plasmid DNA from<Emphasis Type="Italic"> Escherichia coli</Emphasis> to<Emphasis Type="Italic"> Kitasatospora setae</Emphasis>, a bafilomycin B<Subscript>1</Subscript> producer

An effective transformation procedure for Kitasatospora setae was established based on transconjugation from Escherichia coli ET12567 (pUZ8002) using a C31-derived integration vector, pSET152, containing oriT and attP fragments. While no transconjugation was observed under the standard transconjugation conditions for Streptomyces species, sufficient transconjugation (>1×10^-6) was achieved on ISP4 medium containing 30 mM MgCl₂ using a 25- to 125-fold excess of E. coli donor cells. In addition, the sequence and location of the chromosomal integration site attB of K. setae was identified for the first time in genera of non-Streptomyces actinomycetes. K. setae contains a single C31 attB site. Similar to the case of Streptomyces species, the attB site of K. setae is present within an ORF encoding a pirin-homolog, but the K. setae-attB sequence deviates slightly from the consensus sequence of Streptomyces attB sequences.     

Electroporation of Bradyrhizobium japonicum

Summary Electroporation offers a fast, efficient and reproducible way to introduce DNA into bacteria. We have successfully used this technique to transform two commercially important strains of Bradyrhizobium japonicum, the nitrogen-fixing soybean symbiont. Initially, electroporation conditions were optimized using plasmid DNA which had been prepared from the same B. japonicum strain into which the{imDNA was to b}e transformed. Efficiencies of 10⁵-10⁶ transformants/g DNA were obtained for strains USDA 110 and 61A152 with ready-to-use frozen cells. Successful electroporation of B. japonicum with plasmid DNA prepared from Escherichia coli varied with the E. coli strain from which the plasmid was purified. The highest transformation efficiencies (10⁴ transformants/g DNA) were obtained using DNA prepared from a dcm ^– dam ^– strain of E. coli. This suggests that routine isolation of DNA from an E. coli strain incapable of DNA modification should help in increasing transformation efficiencies for other strains of bacteria where DNA restriction appears to be a significant obstacle to successful transformation. We have also monitored the rate of spontaneous mutation in electroporated cells and saw no significant difference in the frequency of streptomycin resistance for electroporated cells compared to control cells.     

An Improved Method of Preparing High Efficiency Transformation <Emphasis Type="Italic">Escherichia coli</Emphasis> with Both Plasmids and Larger DNA Fragments

The high-throughput, cost-efficient transformation systems determine the success of gene cloning and functional analysis. Among various factors that affect this transformation systems, the competence ability of target cells is one of the most important factors. We found antimicrobial peptides LFcin-B can increase the permeability of the cell membrane, and their lethal antibacterial properties can be inhibited by moderately high concentrations of Ca²⁺ and Mn²⁺. In this study, we established a convenient and rapid method (CRM) by adding small concentrations of (0.35 mg/L) and moderately high concentrations of MnCl₂ (50 mM) and CaCl₂ (30 mM) in transformation buffer. The transformation efficiency of E. coli cells (DH5α, JM109 and TOP10) prepared by CRM were comparable with electroporation for plasmid transformation (3.1?±?0.3?×?10⁹ cfu/µg). Unlike competent cells prepared using other chemical methods, those obtained using CRM method are extremely competent for receiving larger size DNA fragments (>?5000 bp) into plasmid vectors. The competent E. coli cells prepared by CRM method are particularly useful for most high-efficiency transformation experiments under normal laboratory conditions.     

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.     

Degradation of 4′-dimethylaminoazobenzene-2-carboxylic acid by Pseudomonas stutzeri

4-Dimethylaminoazobenzene-2-carboxylic acid (DMBC) was utilized as a necessary carbon and nitrogen source by Pseudomonas stutzeri IAM 12097. o-Aminobenzoic acid (o-ABA), N,N-dimethyl-p-phenylenediamine (DMPA) and cathecol were identified as intermediates of DMBC degradation. DMBC was degraded at a concentration below 70 mol dm^–3. The ability to utilize DMBC in P. stutzeri was lost spontaneously to some extent. When P. stutzeri was cured of plasmid DNA (approximately 8 MDal) by treatment with mitomycin C, acridine orange, and chloramphenicol, DMBC was not utilized by the resultant strain. These facts suggest that the degradative ability on DMBC in P. stutzeri is controlled by plasmid DNA. Correspondence to: C. Yatome     

The host specificity system inEscherichia coli SK

E. coli SK has its own enzyme system providing DNA host specificity which differs from the known types of specificity inE. coli K12 andE. coli B. Modification and restriction are observed when the PBVI or PBV3 phages are transferred fromE. coli SK toE. coli B or K12 (and back).A methylase has been isolated fromE. coli SK cells and partly purified. This methylase catalyzesin vitro transfer of the labelled methyl groups from S-adenosylmethionine (SAM) to DNA of both phage and tissue origin which gives rise to 5-methylcytosine (5MC) and 6-methylaminopurine (6MAP). The methylase preparations isolated from the cells at the stationary growth have proved to be 1.5–1.7 times as active as the enzyme from the cells at the logarithmic growth stage. The extract ofE. coli SK cells infected with the phage S_D cannot methylate DNAin vitro. This fact is due tode novo synthesis of the enzyme which disintegrates SAM down to 5-methylthioadenosine (5MTA) and homoserine (HS). This enzyme is not found in the cells infected with the S_D phage in the presence of chloroamphenicole. The activity of the enzyme which disintegrates SAM is the highest between the 4th and the 5th minutes of infection. Thus it may be assumed that this enzyme, most probably, is an early virus specific protein and preventsin vivo methylation of the phage DNA.     

Exchange of chromosomal markers by natural transformation between the soil isolate,Pseudomonas stutzeri JM300, and the marine isolate,Pseudomonas stutzeri strain ZoBell

Both the soil isolate,Pseudomonas stutzeri JM300, and the marine isolate,Pseudomonas stutzeri strain ZoBell, have been shown previously to be naturally transformable. This study reports the detection of genetic exchange by natural transformation between these two isolates. Transformation frequency was determined by filter transformation procedures. Three independent antibiotic resistance loci were used as chromosomal markers to monitor this exchange event: resistance to rifampicin, streptomycin, and nalidixic acid. The maximum frequencies of transformation were on the order of 3.1 to 3.8×10^-6 transformants per recipient; frequencies over an order of magnitude greater than those for spontaneous antibiotic resistance, although they are lower than those observed for soil: soil or marine: marine strain crosses. This exchange was inhibited by DNase I. Transformation was observed between soil and marine strains, both by filter transformation using purified DNA solutions and when transforming DNA was added in the form of viable donor cells. The results from this study support the close genetic relationship betweenP. stutzeri JM300 andP. stutzeri strain ZoBell. These results also further validate the utility ofP. stutzeri as a benchmark organism for modeling gene transfer by natural transformation in both soil and marine habitats.     

Analysis of genome-specific sequences inPhleum species: Identification and use for study of genomic relationships

Sau3AI shot gun cloning and colony hybridization with total genomic probes were used to isolate genome-specific sequences inPhleum species. The total DNA isolated from diploid speciesP. alpinum andP. bertolonii was partially digested withSau3AI and cloned using pUC19 as a vector to anE. coli strain DH5mcr. A partial genomic DNA library consisting of 3030 colonies for the genome ofP. alpinum and one consisting of 3240 colonies for the genome ofP. bertolonii were constructed. Twelve hundred and thirty colonies from the DNA library ofP. alpinum and 1320 from that ofP. bertolonii were respectively blotted to membrane filters and hybridized to the total genomic probes from these two species. Eight clones specific toP. alpinum and 13 specific toP. bertolonii were isolated through colony hybridization and further dot-blot hybridization. Most of these clones may carry highly or moderately repetitive sequences. Three sequences specific toP. alpinum and 3 specific toP. bertolonii were used as probes to hybridize theEcoRI-digested DNA samples from four species,P. alpinum,P. bertolonii,P. pratense andP. montanum, on Southern blot. The results from these hybridization experiments showed that all 3P. bertolonii-specific probes and 2 of the 3P. alpinum-specific probes hybridized to the DNA ofP. pratense, thus confirming the conclusion of the close relationships between the cultivated timothy and its two wild relatives that was drawn in our previous study using the C-banding technique.     

Sequence divergence of an archaebacterial gene cloned from a mesophilic and a thermophilic methanogen

Summary A 1.6-kb fragment of DNA from the thermophilic, methane-producing, anaerobic archaebacteriumMethanobacterium thermoautotrophicum H has been cloned and sequenced. This DNA complements mutations in both the purE₁ and purE₂ loci ofEscherichia coli. The sequence of theM. thermoautotrophicum DNA predicts that complementation inE. coli results from the synthesis of a polypeptide with a molecular weight of 36,249. A polypeptide apparently of this molecular weight is synthesized inE. coli minicells containing recombinant plasmids that carry the cloned fragment of methanogen DNA. We have previously cloned and sequenced a purE-complementing gene from the mesophilic methanogenMethanobrevibacter smithii. The two methanogen-derived purE-complementing genes are 53% homologous and encode polypeptides that are 45% homologous in their amino acid sequences but would be 74% homologous if conservative amino acid substitutions were considered as maintaining sequence homology. The genome ofM. thermoautotrophicum has a molar G+C content of 49.7%, whereas the genome ofM. smithii is 30.6% G+C. Conservation of encoded amino acids while accommodating the very different G+C contents is accomplished by use of different codons that encode the same amino acid. The majority of base changes occur at the third codon position. The intergenic regions of the clonedM. thermoautotrophicum DNA contain sequences previously identified as ribosome binding sites and as putative methanogen promoters. Although the two purE-complementing genes are apparently derived from a common ancestor, only the gene fromM. smithii maintains a codon usage that conforms to the RNY rule.     

Development of an electro-transformation system for Escherichia coli DH10B

Summary Escherichia coli can be transformed to high efficiencies by subjecting a mixture of cells and DNA to a brief but intense electrical field. Factors that affect the transformation efficiency of E.coli strain DH10B were analysed. Optimal conditions gave an efficiency of 10⁸ to 10⁹ transformants/g DNA with E.coli strains K803 and DH10B, and plasmids pB1221.23 and pBSK+. The use of ligated DNA resulted in 10⁶ transformants/g DNA. Detailed protocols for these systems are given.     

Active protection by bacteriophages T3 and T7 againstE. coli B-and K-specific restriction of their DNA

Summary The bacteriophages T3 and T7 are not modified and restricted byE. coli strains with different host specificity (E. coli B, K, O) in vivo. The phages code for a gene product with the ability toovercomeclassicalrestriction (ocr):ocr ^– mutants are subject to modification and restriction via DNA methylation vs cleavage. The T3 genome possesses recognition sites for the restriction endonuclease R.EcoB which, unless the DNA is B-specifically modified, trigger 5–7 DNA cleavages. Theocr gene function of T3 and T7 is located within the gene 0.3 region of these phages and is not identical with thesam (SAMase) function of T3. The mechanisms ofocr protection remains unclear, while it is certain that this protection by the gene 0.3 protein is exerted in the infected cell and not through over-all modification in the preceding growth cycle of the phage.     

Stopped-Flow Measurement of Reaction Rate of Dihydroxyfumaric Acid with 2, 6-Dichlorophenolindophenol

The proline auxotrophic strain of Acetobacter aceti No. 1023 treated with CaCl₂ solution was transformed to the Pro⁺ phenotype at a frequency of up to 10²/μg DNA using chromosomal DNA prepared from the wild type prototrophic strain. The CaCl₂-treated cells of A. aceti No. 1023 could also be rendered competent for uptake of plasmid DNA. In an attempt to produce an appropriate cloning vector for A. aceti, the restriction patterns of the cryptic plasmids, pTA5001 A (23.5 Kb) and pTA5001B (23 Kb), found in A. aceti No. 1023 were determined. A selectable marker (ampicillin resistance) was introduced onto these cryptic plasmids by fusing them to vector pACYC177 from E. coli, using their single restriction site for XhoI. The hybrid plasmids generated could replicate in and confer ampicillin resistance to both A. aceti and E. coli. The maximum transformation frequency for A. aceti No. 1023 with these vectors was 10³/μg DNA.     

Construction of a thermo-sensitive pRI857 vector for efficient DNA capturing in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Objectives

To establish a positive cloning system with a zero background for high-throughput DNA cloning purpose.

Results

The cloning vector, pRI857, and the genomic-library construction vector, pRI857-BAC, were constructed based on the mechanism of expression of the thermo-sensitive cI857 repressor gene that can stringently repress the P_R promoter and kanamycin resistance gene (P_R-kan ^R ) at 30 °C, but have no effect on P_R-kan ^R gene at 37 °C or at higher temperatures. When the pRI857 vectors were transformed into E. coli with or without a target foreign DNA fragment inserted at the BfrBI site of the cI857 gene, only colonies with the foreign DNA fragment survive. We extended this method to construct a pRI857-BAC vector for genomic library cloning which displays an efficiency of ~10⁷ cfu per µg of genomic DNA, with no empty vectors detected.

Conclusions

Cloning by indirect activation of resistance marker gene represents a novel DNA-capturing system, which can be widely applied for high-throughput DNA cloning.

     

Properties of phosphorylated NADP+-specific glutamate dehydrogenase fromEscherichia coli

The NADP⁺-specific glutamate dehydrogenase (GDH) fromEscherichia coli strain D₅H₃G₇, an enzyme that catalyzes the interconversion of -ketoglutarate andl-glutamate, has been shown to be phosphorylated in vitro in an ATP-dependent enzymatic reaction. The phosphorylated protein is extremely acid labile and is unstable at high pH. Treatment of GDH with diethyl pyrocarbonate (DEP), a histidine-modifying reagent, blocked the incorporation of³²P from [-³²P]ATP. GDH catalytic activity was also inhibited by DEP treatment. Hydroxylamine, a reagent hydrolyzing phosphoramidates, catalyzed the removal of phosphate from phosphorylated GDH, suggesting that GDH may be phosphorylated at a histidine residue(s). A total enzymatic hydrolysis of phosphorylated GDH, which was electroeluted from a native polyacrylamide gel, was analyzed by a Dowex 1-8X anion exchange chromatography. The presence of³²P-labeled 3-phosphohistidine, characterized and identified from this hydrolysate, demonstrates that a histidine residue(s) is the site of phosphorylation.     

Comparison of adherence properties ofEscherichia coli 0157:H7 and a 60-megadalton plasmid-cured derivative

Escherichia coli 0157H7 has previously been shown to be capable of adherence to the human small intestinal cell line INT 407. A quantitative subculture assay was developed to measure the adherent ability ofE. coli 0157H7 strain 932 and its 60-megadalton plasmid-cured derivative 932P. The assay involves enumeration of adherent bacteria by dilution and plating in penassay agar, and counting INT 407 cells by hemocytometry. With this assay system, it was shown that strain 932 adheres to INT 407 cells at an average level of 7.1 bacteria per INT 407 cell, but that adherence is not dependent on the 60-megadalton plasmid. Strain 932P adheres an average of three times better than strain 932, but demonstrates high variability in adherence. Testing of adherence under a variety of different cultural and test conditions revealed that 932 and 932P differed in response to different conditions. Therefore, it appears that adherence ofE. coli 0157H7 to INT 407 cells is not dependent on the presence of a 60-megadalton plasmid and may occur by two distinct mechanisms, both of which may be important in intestinal colonization.