A gene for DNA invertase and an invertible DNA in Escherichia coli K-12

An assay system for the pin gene function, which suppresses the vh2 mutation of Salmonella, was developed and used to show that most strains of Escherichia coli K-12 are Pin+, whereas all the strains of E. coli C examined are Pin-. An E. coli host strain was constructed and used for detection of DNA fragments carrying the E. coli K-12 pin gene cloned in the plasmid vector pBR322. Restriction analysis of the cloned fragments showed that the invertible DNA (designated P region) is adjacent to the pin gene and that its inversion is mediated by the pin gene product. The pin gene was found to be functionally homologous to the gin gene of Mu phage and the cin gene of P1 phage. The P region most probably resides within the cryptic prophage e14, and the Pin- phenotype is likely to be associated with the loss of e14.     

The invertible P-DNA segment in the chromosome of Escherichia coli.

In the chromosome of many strains of Escherichia coli K12 the excisable element e14 is found, which contains an invertible DNA region. This invertible P region, and the gene responsible for the inversion (pin) were cloned, together with other e14 sequences. The element e14 contains a gene which kills the host cell. This can be repressed by a function also coded by e14. The kil and repressor genes as well as the attachment site of the element were mapped in different regions of the element. The invertible segment and pin gene were sequenced. The invertible segment is 1794 bp long, and contains one large internal open reading frame of 879 bp and reading frames which overlap the end pont of the invertible segment. Although pin highly homologous to gin of phage Mu, neither the genetic organization of the P segment nor the sequence of the putative proteins resemble the invertible G segment of phage Mu (which codes for genes involved in tail fiber assembly). The complete DNA sequences of both invertible segments were screened for homology. No resemblance was found. The P segment is flanked by inverted repeat sequences of 16 bp. Comparison of these with related inversion systems points out that the recombination site maps probably within a 2-bp region. This cross-over site is contained within a short palindromic sequence (AAACC AA GGTTT) which is more or less conserved in the recombination sites of all related DNA invertases.     

Construction of promoter-probe plasmid vector

A new plasmid vector, designated pBRS188 has been constructed for cloning of promoter-containing DNA fragments. This plasmid is a derivative of the E. coli drug-resistance plasmid pBR322 in which a small region (13 base pairs long) within the Tc promoter is eliminated. As a result of the alteration pBRS188 has lost the ability to confer Tc resistance to the host strain. Cloning of foreign DNA fragments, carrying promoters for E. coli RNA polymerase, into the unique EcoRI site of pBRS188 allows to isolate the recombinant TcR transformants. Our construction required the use of new techniques, involving partial hydrolysis of DNA fragments by E. coli DNA polymerase I in the presence of one deoxyribonucleosidetriphosphate and by nuclease S1. An important feature of this method is the ability to regenerate restriction endonuclease recognition sites at junctions of DNA fragments.     

低温菌启动子探针质粒的构建

为了在宿主菌Acinetobacter sp.DWC6中构建低温菌蛋白表达载体,以pBR322质粒为基础,去除质粒上β-内酰胺酶基因的启动子片段,取而代之为来源于质粒pJRD215的卡那霉素抗性基因片段,并在pBR322中插入Acinetobacter菌属特异性ori的DNA片段,构建了能在Acinetobacter sp.DWC6和E.coli中正常复制的启动子探针质粒pBAP1。通过在质粒pBAP1中的β-内酰胺酶基因上游随机导入Acinetobacter sp.DWC6基因组片段,通过检测宿主细胞的氨苄青霉素抗性和β-内酰胺酶活性,来筛选强启动子片段,并分析了启动子探针质粒载体的功能及启动子的强度。     

Absolute and relative QPCR quantification of plasmid copy number in Escherichia coli

Real-time QPCR based methods for determination of plasmid copy number in recombinant Escherichia coli cultures are presented. Two compatible methods based on absolute and relative analyses were tested with recombinant E. coli DH5alpha harboring pBR322, which is a common bacterial cloning vector. The separate detection of the plasmid and the host chromosomal DNA was achieved using two separate primer sets, specific for the plasmid beta-lactamase gene (bla) and for the chromosomal d-1-deoxyxylulose 5-phosphate synthase gene (dxs), respectively. Since both bla and dxs are single-copy genes of pBR322 and E. coli chromosomal DNA, respectively, the plasmid copy number can be determined as the copy ratio of bla to dxs. These methods were successfully applied to determine the plasmid copy number of pBR322 of E. coli host cells. The results of the absolute and relative analyses were identical and highly reproducible with coefficient of variation (CV) values of 2.8-3.9% and 4.7-5.4%, respectively. The results corresponded to the previously reported values of pBR322 copy number within E. coli host cells, 15-20. The methods introduced in this study are convenient to perform and cost-effective compared to the traditionally used Southern blot method. The primer sets designed in this study can be used to determine plasmid copy number of any recombinant E. coli with a plasmid vector having bla gene.     

Nucleotide sequences and properties of the sites involved in lysogenic insertion of the bacteriophage HP1c1 genome into the Haemophilus influenzae chromosome.

Bacteriophage HP1c1 lysogenizes its host Haemophilus influenzae Rd by inserting its genome into the bacterial chromosome. The DNA segments corresponding to the integration regions on the phage and host chromosomes and the two junctions formed between phage and host sequences on lysogenic insertion were isolated and propagated in Escherichia coli HB101 as hybrid plasmids by using pBR322 as the vector. The nucleotide sequences in the vicinity of the point of recombinational insertion were determined. Phage and host DNA shared an extensive, nearly identical, segment that was 183 base pairs long. This segment consisted of 93 identical residues and a 27-residue portion containing 6 mismatches, followed by 63 identical residues. Recombinational insertion occurred within the 63-residue identical segment and involved neither duplication nor deletion of any residues. Short inverted repeats consisting of clustered A-T base pairs were present within the two 27-residue segments. Two additional sites on the host chromosome showed significant hybridization to the phage-host homology region.     

Determination of plasmid DNA concentration maintained by nonculturable Escherichia coli in marine microcosms.

The concentration of plasmid pBR322 DNA in nonculturable Escherichia coli JM83 was measured to determine whether the plasmid concentration changed during survival of E. coli in marine and estuarine water. E. coli JM83 containing the plasmid pBR322 was placed in both sterile seawater and sterile estuarine water and analyzed for survival (i.e., culturability) and plasmid maintenance. The concentration of pBR322 DNA remained stable in E. coli JM83 for 28 days in an artificial seawater microcosm, even though nonculturability was achieved within 7 days. E. coli JM83 incubated in sterile natural seawater or sterile estuarine water did not reach nonculturability within 30 days. Under all three conditions, plasmid pBR322 DNA was maintained at approximately the initial concentration. Cloning of DNA into the plasmid pUC8 did not alter the ability of E. coli to maintain vector plasmid DNA, even when the culture was in the nonculturable state, but the concentration of plasmid DNA decreased with time in the microcosm. We conclude that E. coli is able to maintain plasmid DNA while in the nonculturable state and that the concentration at which the plasmid is maintained appears to be dependent upon the copy number of the plasmid and/or the presence of foreign DNA.     

Determination of plasmid DNA concentration maintained by nonculturable Escherichia coli in marine microcosms.

The concentration of plasmid pBR322 DNA in nonculturable Escherichia coli JM83 was measured to determine whether the plasmid concentration changed during survival of E. coli in marine and estuarine water. E. coli JM83 containing the plasmid pBR322 was placed in both sterile seawater and sterile estuarine water and analyzed for survival (i.e., culturability) and plasmid maintenance. The concentration of pBR322 DNA remained stable in E. coli JM83 for 28 days in an artificial seawater microcosm, even though nonculturability was achieved within 7 days. E. coli JM83 incubated in sterile natural seawater or sterile estuarine water did not reach nonculturability within 30 days. Under all three conditions, plasmid pBR322 DNA was maintained at approximately the initial concentration. Cloning of DNA into the plasmid pUC8 did not alter the ability of E. coli to maintain vector plasmid DNA, even when the culture was in the nonculturable state, but the concentration of plasmid DNA decreased with time in the microcosm. We conclude that E. coli is able to maintain plasmid DNA while in the nonculturable state and that the concentration at which the plasmid is maintained appears to be dependent upon the copy number of the plasmid and/or the presence of foreign DNA.     

The effect of the oligomerization of pBR322 on the level of transformation in Escherichia coli

The ability of the known Escherichia coli strain JC3881 recB recC recF sbc15 to produce oligomeric and multimeric forms of pBR322 underlies the study presented. The individual oligomeric forms of pBR322 were isolated from the agarose gel. The plasmid forms were used for electron microscopic control and also introduced into the system of E. coli competent cells. The E. coli transformation level of different forms of plasmid DNA rose from monomers to pentamers. CCC forms of the plasmid possessed high efficiency of the E. coli cell transformation. The systems of the host recombination are to be significant in the process of plasmid oligomerization.     

Evidence for the involvement of the 16kD gene promoter in initiation of chromosomal replication of Escherichia coli strains carrying a B/r-derived replication origin.

Initiation of chromosomal DNA replication of several Escherichia coli dnaA (Ts) strains is diminished in cell harbouring pBR322 hybrid plasmids carrying both oriC and the adjacent 16kD gene promoter of E. coli K12. This perturbance, resulting in very slow growth, is caused both by the dnaA allele and the E. coli B/r-derived region of the replication origin of these strains. Cloning and DNA sequence analysis of the E. coli B/r replication origin revealed several base differences as compared to the E. coli K12 sequence. The replication origin of temperature sensitive fast growing mutants, originating from a homologous exchange between chromosomal and plasmid DNA sequences were also cloned. Sequence data showed that a single base change within the promoter of the 16kD gene of these dnaA (Ts) strains is able to suppress the inhibition of chromosomal DNA replication by the mentioned pBR322 hybrid plasmids. Our results strongly indicate a role of the 16kD gene promoter in control of initiation of chromosomal DNA replication.     

Cloning of chicken embryo tRNA genes using single stranded nucleosomal DNA highly enriched for tRNA complementary sequences

DNA from chicken embryo nucleosome tetramers (about 760 base pairs in size) was enriched for tRNA genes by RPC-5 chromatography. The enriched DNA was hybridized with chicken embryo total tRNA and the hybridized DNA isolated utilizing a) avidinbiotin interaction, b) diazobenzyloxymethyl paper, and c) high temperature RPC-5 chromatography. The obtained single stranded DNA highly enriched for tRNA complementary sequences was hybridized with total DNA from nucleosome monomers (140--190 base pairs in size) and the excess of non hybridized monomer nucleosome DNA removed by Sepharose 4B chromatography. The hybrid molecules obtained were made fully double stranded by incubation with E. coli DNA polymerase I, DNA ligase, and exonuclease III. DNA was inserted into plasmid pBR322 by G-C joining procedure and the recombinant DNA used to transform the E. coli strain chi 1776. More than 70% of the transformants obtained hybridize to chicken embryo total tRNA.     

Molecular cloning of cDNA for rat glycine methyltransferase

Using a highly purified preparation of glycine methyltransferase mRNA, double-stranded cDNA was synthesized and inserted into the PstI site of pBR322. The resulting recombinant DNA was used to transform E. coli X 1776 by conventional methods. Among tetracycline-resistant transformants, a number of colonies were found to contain cDNA sequence for glycine methyltransferase as examined by hybrid-selected translation. A restriction endonuclease cleavage map was constructed covering about 720 base pairs. With the cDNA as the probe, the content of the glycine methyltransferase mRNA was quantitated in various rat tissues and was found to be proportional to the specific enzyme activity.     

Site and sequence specificity of the daunomycin-DNA interaction

The site and sequence specificity of the daunomycin-DNA interaction was examined by equilibrium binding methods, by deoxyribonuclease I footprinting studies, and by examination of the effect of the antibiotic on the cleavage of linearized pBR322 DNA by restriction endonucleases PvuI and EcoRI. These three experimental approaches provide mutually consistent results showing that daunomycin indeed recognizes specific sites along the DNA lattice. The affinity of daunomycin toward natural DNA increases with increasing GC content. The quantitative results are most readily explained by binding models in which daunomycin interacts with sites containing two adjacent GC base pairs, possibly occurring as part of a triplet recognition sequence. Deoxyribonuclease I footprinting studies utilizing the 160 base pair (bp) tyrT DNA fragment and 61 and 53 bp restriction fragments isolated from pBR322 DNA further define the sequence specificity of daunomycin binding. Specific, reproducible protection patterns were obtained for each DNA fragment at 4 degrees C. Seven protected sequences, ranging in size from 4 to 14 bp, were identified within the tyrT fragment. Relative to the overall tyrT sequence, these protected sequences were GC rich and contained a more limited and distinct distribution of di- and trinucleotides. Within all of the protected sequences, a triplet containing adjacent GC base pairs flanked by an AT base pair could be found in one or more copies. Nowhere in the tyrT fragment did that triplet occur outside a protected sequence. The same triplet occurred within seven out of nine protected sequences observed in the fragments isolated from pBR322 DNA. In the two remaining cases, three contiguous GC base pairs were found. We conclude that the preferred daunomycin triplet binding site contains adjacent GC base pairs, of variable sequence, flanked by an AT base pair. This conclusion is consistent with the results of a recent theoretical study of daunomycin sequence specificity [Chen, K.-X., Gresh, N., & Pullman, B. (1985) J. Biomol. Struct. Dyn. 3, 445-466]. Adriamycin and the beta-anomer of adriamycin produce the same qualitative pattern of protection as daunomycin with the tyrT fragment. Daunomycin inhibits the rate of digestion of pBR322 DNA by PvuI (recognition sequence 5'-CGATCG-3') to a greater extent than it does EcoRI (recognition sequence 5'-GAATTC-3'), a finding consistent with the conclusions derived from our footprinting studies. Our results, as a whole, are the clearest indication to date that daunomycin recognizes a specific DNA sequence as a preferred binding site.     

Efficient transformation of Serratia marcescens with pBR322 plasmid DNA

Eight Serratia marcescens strains tested could be transformed with the plasmid pBR322. Transformants were selected on the basis of resistance to high levels of ampicillin (400 to 500 micrograms/ml). For six of the strains, the CaCl2- mediated transformation procedure developed for Escherichia coli was successful. For the other two strains, no transformants were obtained with the CaCl2-mediated transformation procedure unless the cells first received a heat treatment. Transformation frequency was dependent on DNA concentration, and no transformation was detected with linear pBR322 DNA. The stability and copy number of pBR322 were similar in S. marcescens and E. coli. As in E. coli, the pBR322 DNA was amplified in S. marcescens after inhibition of proteins synthesis. Based on these results, cloning in S. marcescens should be possible and pBR322 should be a useful cloning vehicle.     

Directed modification of the Tcr gene region of the plasmid pBR322 using complementary single-stranded DNA fragments carrying alkylating groups

A method is suggested for chemical modification of preselected regions of plasmid DNA by complementary single-stranded restriction fragments of DNA (srf DNA), carrying alkylating reagents. The gene coding for tetracycline resistance of plasmid pBR322 was used as a target. Srf DNA was prepared by a partial digestion of a double-stranded EcoRI-BamHI restriction fragment (377 base pairs) from Tcr by E. coli exonuclease III. The residues of an alkylating reagent N,N,N'-tri(beta-chlorethyl)-N'-(p-formylphenyl) propylenediamine 1,3 (TFP) were attached covalently to 4-5% of sfr DNA bases. The alkylating derivative of the sfr DNA was hybridized with supercoiled pBR322 plasmid DNA. The hybridization conditions (37 degrees C, 40% formamide, 0,2 M NaCl, 0,1 M Tris-HCl pH 7,5, 0,001 M EDTA) under which the bases carrying TFP residues are not eliminated from the sfr DNA, and transforming activity of pBR322 DNA does not decrease were established. It was shown that about 20% of plasmid pBR322 molecules form D-loops with alkylating sfr DNA under these conditions. It was shown that sfr DNA, carrying TFP can alkylate the complementary region of plasmid DNA, forming cross-linked D-loops. A method for the site-directed mutagenesis of switching off the preselected genes or non-transcribed DNA functional regions (promotors, introns etc) integrated into plasmids of other vectors is suggested.     

Expression of the yeast galactokinase gene in Escherichia coli.

In Saccharomyces cerevisiae the genes for three of the enzymes involved in galactose metabolism are tightly linked near the centromere of chromosome II (Douglas and Hawthorne, 1964). However, the molecular mechanisms which control the expression of these genes are not well understood. A DNA fragment containing at least one of these yeast genes, the galactokinase gene (gal1), has been joined to the bacterial plasmid pBR322 and maintained in an Escherichia coli strain that carries a deletion in its own galactokinase gene, galK. The presence of the yeast gene was demonstrated by (i) complementation of the E. coli galactokinase deletion, (ii) by hybridization of the cloned DNA fragment to restriction enzyme digests of total yeast DNA and (iii) by assaying for yeast galactokinase activity in bacterial cell extracts. The yeast DNA fragment is 4700 base pairs long, and enables the host E. coli K-12 strain to grow in minimal medium containing galactose as the sole carbon source with a generation time of 14.3 h. The yeast galactokinase activity in the bacterial extracts is 0.7% of the bacterial galactokinase activity found in wild-type E. coli fully induced with fucose.     

DNA sequence of the gene coding for Escherichia coli ribonuclease H

The gene for Escherichia coli ribonuclease H has been studied by use of a plasmid which contains a segment of the E. coli chromosome. The genomic DNA was subcloned from pLC28-22 to pBR322 by use of various restriction enzymes. Such subcloning limited the RNase H gene to a piece of DNA no longer than 760 base pairs. Cells bearing plasmids containing the RNase H gene produce as much as 10-15 times the normal amount of RNase H without any drastic effect on maintenance of the plasmid or cell growth. DNA sequence analysis has permitted the prediction of a protein whose molecular weight is 17,559 (155 amino acid residues). The predicted sequence was confirmed by amino acid analysis, NH2-terminal amino acid sequence, and size determination of highly purified RNase H.