A rapid and simple method for screening large numbers of recombinant DNA clones

A simple and rapid method has been described for the isolation of plasmid, phagemid and phage DNAs. Hundreds of recombinant clones can be screened in one day employing this method. It takes half an hour to prepare plasmid DNA from ten clones, and the DNA prepared from a single colony using this method is of sufficient quality and in sufficient amount to perform at least five restriction digestions. This method eliminates the need for RNase treatment and phenol chloroform extraction if the plasmids are needed only for the restriction digestion. If needed, RNAs can be removed after restriction digestion by adding RNase and incubating for two minutes at room temperature. After RNase treatment and phenol/chloroform extraction, the plasmid DNA serves as a good template for sequencing. The DNA can be stored at -20 degrees C for over eight weeks.     

Factors affecting the isolation of CCC DNA from Streptomyces lividans and Escherichia coli

Based on the results of a systematic study of factors affecting plasmid yield and purity, a procedure suitable for the rapid screening for and isolation of covalently closed circular DNA from Streptomyces lividans and Escherichia coli was developed. The method consists of lysis of lysozyme-treated bacteria combined with alkaline denaturation of DNA at high temperature. Renaturation of CCC DNA and precipitation of single-stranded DNA together with protein is achieved by the addition of a minimal amount of phenol/chloroform. The screening procedure uses only a single tube and the samples can be analyzed by agarose gel electrophoresis about 30 min after lysis. Removal of phenol and further purification of the plasmid preparation is achieved by consecutive precipitations with isopropanol and spermine, followed by extraction with ethanol, producing samples suitable for restriction endonuclease digestion, ligation, and transformation of S. lividans protoplasts or competent E. coli cells in about 2 h. All steps of the procedure are explained in detail with information about the effects of changing parameters. This should help the experimenter to obtain reproducible results and may be useful if the method has to be adapted to new strains or plasmids.     

Site-directed mutagenesis by combination of homologous recombination and DpnI digestion of the plasmid template in Escherichia coli

A rapid site-directed mutagenesis strategy using homologous recombination and DpnI digestion of the template in Escherichia coli is described. Briefly, inverse polymerase chain reaction amplification of the entire circular plasmid was performed by mutagenic primers with overlapping sequences ( approximately 15 bp) for generating PCR products with approximately 15 bp of homology on the terminal ends. On direct transformation of the amplified PCR products into restriction endonuclease DpnI-expressing E. coli BUNDpnI, homologous recombination occurs in E. coli while the original templates are removed via DpnI digestion in vivo, thus yielding clones harboring mutated circular plasmids. Nearly 100% efficiency was attained when this strategy was used to modify DNA sequences.     

Development of a Rapid Method for Identifying Carryover Contamination of Positive Control DNA,Using a Chimeric Positive Control and Restriction Enzyme for the Diagnosis of White Spot Syndrome Virus by Nested PCR

Chimeric positive plasmids have been developed to minimize false-positive reactions caused by polymerase chain reaction (PCR) contamination. Here, we developed a rapid method for identifying false-positive results while detecting white spot syndrome virus (WSSV) by nested PCR, using chimeric positive plasmids. The results of PCRs using WSSV diagnostic primer sets showed PCR products of a similar size (WSSV 1st PCR product, 1,447 bp; WSSV 2nd PCR product, 941 bp) using WSSV chimeric plasmids or DNA from shrimp infected with WSSV. The PCR products were digested with DraI for 1 h at 37 °C. The digested chimeric DNA separated into two DNA bands; however, the WSSV-infected shrimp DNA did not separate. Thus, chimeric plasmid DNA may be used as positive control DNA instead of DNA from WSSV-infected shrimp, in order to prevent PCR contamination. Thus, the use of restriction enzyme digestion allowed us to rapidly distinguish between WSSV DNA and WSSV chimeric plasmid DNA.     

Construction and characterization of new cloning vehicles. IV. Deletion derivatives of pBR322 and pBR325

In vitro recombinant DNA experiments involving restriction endonuclease fragments derived from the plasmids pBR322 and pBR325 resulted in the construction of two new cloning vehicles. One of these plasmids, designated pBR327, was obtained after an EcoRII partial digestion of pBR322. The plasmid pBR327 confers resistance to tetracycline and ampicillin, contains 3273 base pairs (bp) and therefore is 1089 bp smaller than pBR322. The other newly constructed vector, which has been designated pBR328, confers resistance to chloramphenicol as well as the two former antibiotics. This plasmid contains unique HindIII, BamHI and SalI sites in the tetracycline resistance gene, unique PvuI and PstI sites in the ampicillin resistance gene and unique EcoRI, PvuII and BalI sites in the chloramphenicol resistance gene. The pBR328 plasmid contains approx. 4900 bp.     

Molecular cloning of DNA complementary to a mouse α-fetoprotein mRNA sequence

DNA complementary to mouse yolk sac messenger RNA has been inserted at the PstI site of the plasmid pBR322 by annealing of the oligo(dG)-tailed plasmid DNA with the oligo(dC)-tailed mouse DNA. Transformation of Escherichia coli strain RRI with this annealed DNA yielded clones bearing recombinant plasmids. The clones were screened for DNA complementary to mouse a-fetoprotein (AFP) messenger RNA sequences by hybridization with a cDNA probe transcribed from an AFP mRNA of over 90% purity. Out of nine plasmids that were isolated and analyzed by restriction mapping, all had homologous insert DNA of various lengths. The plasmid with the longest insert, pAF6, contained 1.65 kb of added DNA, which is about 70% of the AFP mRNA. This clone was positively identified by a hybridization-translation procedure to contain a cDNA sequence for AFP. A restriction map of this clone and the orientation of the message are presented.     

Intramolecular recombination during plasmid transformation of Bacillus subtilis competent cells.

We have constructed plasmids carrying direct internal repeats 260-2000 bp long. Monomers of such plasmids transformed Bacillus subtilis competent cells. The efficiency of transformation varied with the square of the length of repeats. The transformed clones harbored either the entire transforming plasmid and the plasmid arising by recombination between the repeats, or only the latter plasmid. Internally-repeated plasmids linearized by in vitro cleavage with restriction endonuclease could transform, yielding clones which exclusively harbored a plasmid resulting from recombination between the repeats. When the transforming plasmid carried repeats which differed slightly, conversion of one repeat into the other could occur. The following model of plasmid transformation accounts for these data: (1) plasmid DNA is cleaved and rendered linear in contact with competent cells; (2) a linear, at least partially double-stranded plasmid molecule is introduced or formed by repair within the cell; (3) a circular viable plasmid is produced by recombination between repeats carried on this molecule; (4) alternatively, a viable plasmid is produced by repairing the cut within one of the repeats by DNA synthesis which uses the other repeat as a template.     

A method for the deletion of restriction sites in bacterial plasmid deoxyribonucleic acid

Summary A general method has been developed for the deletion of restriction endonuclease sites in bacterial plasmid DNA. The procedure involves partial digestion of the covalently closed circular plasmid DNA with an appropriate restriction endonuclease under conditions which allow accumulation of unit-length linear DNA molecules, controlled digestion of the exposed 5 ends with the 5-exonuclease, and in vivo recircularization of the resulting linear DNA in a bacterial host cell. The method has been used for the deletion of one of the two EcoRI sites in the plasmid pML2 (colE1-Km). Two of the resulting plasmids, pCR1 and pCR11, have a single EcoRI cleavage site, but retain genetic determinants specifying resistance to colicin E1 and kanamycin, and thus may be useful as vectors for the cloning and amplification of DNA in bacteria.     

A method for the generation of small pre-determined deletions in plasmid DNA: deletion analysis of the tetR region of vector pBR322

A general method is described that allows precise deletion of a chosen restriction fragment(s) from a plasmid having many cleavage sites for that restriction enzyme. The DNA to be deleted is first separated from the rest of the plasmid on a larger DNA fragment contained between two different unique restriction sites. This fragment is then subdigested by the restriction endonuclease of interest, which recognises two or more tetranucleotide (cohesive end or blunt end) sequences on the fragment, and is recloned between the two original unique restriction sites. The method is rapid, efficient, and the results are predictable. Examples are given in which predetermined HpaII (9 bp, 147 bp), TaqI (141 bp) and AluI (15 bp, 403 bp) fragments have been selectively removed from the tetR region of plasmid pBR322.     

A simple procedure for maximum yield of high-quality plasmid DNA

We have established a simple procedure for the rapid isolation of high-quality plasmid DNA suitable for various molecular techniques and provided a step-by-step protocol. The DNA samples isolated by this procedure have been used successfully for double-stranded DNA sequencing, restriction enzyme mapping, subcloning, in vitro mutagenesis, generation of deletion clones and so on. The procedure is highly reproducible, and superior quality DNA can be obtained without the use of phenol, chloroform or other organic solvents.     

Large-scale purification of plasmid DNA by anion-exchange high-performance liquid chromatography.

Numerous methods have previously been reported for the final steps in the large-scale purification of plasmid DNA. Although gel permeation and reverse-phase high-performance liquid chromatography have been utilized for this procedure in the past, the limited capacity of these systems often necessitated multiple rounds of chromatography, especially with the high copy number plasmids commonly in use today. In this paper, the use of the high-capacity, high-resolution Protein-Pak DEAE 8HR column is presented for the large-scale isolation of highly purified plasmid DNA from crude E. coli cell lysates. Up to 5 mg of plasmid DNA have been purified in a single 50-minute chromatography run. The purified DNA demonstrated excellent biological activity as demonstrated by restriction endonuclease digestion, E. coli transformation and DNA-mediated gene transfection of eukaryotic cells.     

Preparation of large numbers of plasmid DNA samples in microtiter plates by the alkaline lysis method

A protocol is described for the growth and preparation of plasmid DNAs from small culture volumes (250 μl) and utilizing standard 96-well plates. Several hundred plasmids can be prepared simultaneously, yielding sufficient DNA for subsequent analysis by restriction digestion and gel electrophoresis. This protocol may be useful for rapid screening of clones arising in recombinant DNA work such as site-directed mutagenesis, oligonucleotide cassette cloning, deletion analysis, etc. The technique was initially developed to meet our requirement to provide large numbers of cosmid DNAs for restriction enzyme fingerprint analyses in genome mapping projects.     

A sequence of the yeast 2 micron DNA plasmid chromosome near the origin of replication is exposed to restriction endonuclease digestion

The yeast 2 μm DNA plasmid nucleoprotein complex was subjected to restriction endonuclease digestion to ascertain whether all possible sites are equally accessible to hydrolysis. When plasmid nucleoprotein complexes which had been fixed with formaldehyde were exhaustively digested with restriction endonucleases HinfI or CfoI, only a few of the limit digest products were produced. Furthermore, the limited set of restriction endonuclease sites exposed in formaldehyde-treated plasmid chromosomes could be shown to be preferentially hydrolyzed when plasmid chromosomes which had not been treated with formaldehyde were digested with the same restriction endonucleases. Mapping of the preferred sites revealed that they mapped to the region of the plasmid near the replication origin. These results demonstrate that the protection of DNA from nuclease activity is not constant along the plasmid chromatin, and that a region near the replication origin is preferentially exposed to endonuclease hydrolysis.     

A protocol for DNA fragment extraction from polyacrylamide gels

A simple and efficient method of purifying linear plasmid DNA from contaminating DNA fragments is described. Both vector and insert containing plasmids may be used without extensive purification, in particular without cesium chloride centrifugation. Careful deproteinization with phenol-chloroform allows efficient restriction enzyme digestion. Fragment separation can be performed immediately after restriction endonuclease digestion in a single 6% polyacrylamide gel. Extraction of DNA fragments from the gel is easy and gives a good yield. The DNA may be used for ligation and transformation without further purification.     

Construction and restriction endonuclease mapping of hybrid plasmids containing Saccharomyces cerevisiae ribosomal DNA.

Summary Fragments produced by partial digestion of Saccharomyces cerevisiae ribosomal DNA (rDNA) with the restriction endonuclease EcoRI were ligated in vitro to the bacterial plasmid RSF2124. The resulting hybrid plasmids were cloned in Escherichia coli. Three hybrid plasmids which contain at least one intact repetitive unit of the multiple, tandem sequences of the yeast rDNA genes have been further characterized. These plasmids have been used to construct a map of the EcoRI, SmaI, HindII and HindIII restriction sites in the individual repetitive units of yeast rDNA.     

Relief of polarity caused by transposon Tn5: application in mapping a cloned region of the Escherichia coli uvrB locus essential for UV resistance

The structure and function of recombinant plasmid pNP5, which consists of vector pMB9 and a 2.5 kb EcoRI fragment harbouring the Escherichia coli uvrB gene, has been investigated. Insertional inactivation with the transposons Tn1 (Apr) or Tn5 (Kmr) has been used to determine the region on pNP5 DNA that is essential for UV resistance in uvrB deletion strains. This region spans approx. 1.8 kb and is separated by at least 280 bp from the pMB9 promoter to which it has been fused. Furthermore, a procedure is described to eliminate the polarity exerted by the transposon Tn5. A combination of in vitro digestion of pNP5::Tn5 DNA with restriction endonuclease XHoI, followed by ligation and subsequent in vivo propagation of the resulting plasmid DNA yields predominantly pNP5 molecules with a site-specific nonpolar mutation. The method allows an investigation of cloned complex genetic units, such as operons.     

Molecular analyses of conjugative, gentamicin-resistance plasmids from staphylococcal clinical isolates

Gentamicin-resistant Staphylococcus aureus and Staphylococcus epidermidis strains which were isolated from infants with staphylococcal bacteremia were analyzed for the presence of self-transmissible gentamicin-resistance (Gmr) plasmids. Conjugative GMr plasmids of approximately 43.8-63 kilobases (kb) were found in all S. aureus strains. Inter- and intra-species transfer of Gmr plasmids by conjugation was observed from S. aureus to S. aureus and to S. epidermidis recipient strains. However, neither inter- nor intra-species transfer of gentamicin resistance by conjugation was observed with nine out of nine S. epidermidis donor strains which were mated with either S. epidermidis or S. aureus recipient strains. These conjugative Gmr plasmids were unable to comobilize a smaller (15-kb) plasmid present in all but two S. aureus clinical isolates. Many of the conjugative Gmr plasmids also carried genetic determinants for kanamycin, tobramycin, neomycin, and ethidium bromide resistance, and for beta-lactamase synthesis. EcoRI restriction endonuclease digests of the S. aureus Gmr conjugative plasmids revealed three different digestion patterns. Four EcoRI restriction endonuclease digestion fragments of 15, 11.4, 6.3, and 4.6 kb in size were common to all plasmids. These plasmids and conjugative Gmr staphylococcal plasmids from other geographical regions shared restriction digestion fragments of similar molecular weights. DNA hybridization with biotinylated S. aureus plasmid pIZ7814 DNA revealed a high degree of homology among these plasmids. A 50.9-kb plasmid from one of the nonconjugative S. epidermidis clinical isolates showed homology with the probe DNA but lacked a portion of a 6.3-kb fragment which was present in all conjugative plasmids and believed to carry much genetic information for conjugation.     

Transposon-like structure of a new plasmid-encoded restriction-modification system in Rhizobium leguminosarum VF39SM

Total DNA isolated from Rhizobium leguminosarum VF39SM cells is resistant to cleavage by the restriction endonuclease PstI. Plasmid curing and transfer studies localized this phenotype to pRleVF39b, the second smallest of six plasmids found in this bacterium. In vitro selection for vector modification was employed to isolate a presumptive methylase gene (M.Rle39BI) from a plasmid gene library. Total and plasmid DNAs isolated from E. coli containing M.RleBI were resistant to digestion by PstI. Sequence data suggested that a putative restriction endonuclease (R.Rle39BI) was also encoded on the same fragment. The two genes were flanked by identical copies of a putative insertion sequence, which was also present in several copies elsewhere in the VF39SM genome. The presence of this element in other strains examined suggested that this element is indeed an insertion sequence. The differences in G/C content between the DNA coding for the R/M system and that of the IS element suggest that this DNA region may have been acquired by horizontal transfer.