Improved vector, pHSG664, for direct streptomycin-resistance selection: cDNA cloning with G:C-tailing procedure and subcloning of double-digest DNA fragments

A plasmid cloning vector, pHSG664, has been constructed which is suitable for the direct-selection of transformed cells with recombinant DNAs. The plasmid contains the replicon and ApR-gene region of pUC9 ligated to the strA+ (rpsL+) gene derived from pNO1523 [Dean, Gene 15 (1981) 99-102]. The vector contains ten unique restriction sites: EcoRI, HpaI, PvuII, SphI, PstI, SmaI(XmaI), BamHI, SalI(AccI, HincII), XbaI and HindIII. Five sites (bold-face lettering) are located within the coding region of the strA+ gene. Any insertion at the five bold-faced sites or any nucleotide replacement involving the strA+ gene region and the other unique sites can be selected by Ap and Sm double selection in a strA- (SmR) strain such as E. coli HB101. Thus, this vector is useful for cDNA cloning at either the SphI or the PstI site with the G:C-tailing procedure, as well as for the cloning of double-digest DNA segments.     

Cloning of the yeast methionyl-tRNA synthetase gene

A pool of random wild type yeast DNA fragments obtained by partial Sau IIIA restriction enzyme digestion and inserted in the Bam HI site of the hybrid yeast Escherichia coli plasmid ((pFL1) has been used to transform to prototrophy a methionyl-tRNA synthetase-impaired mutant requiring methionine. In the numerous prototroph strains recovered at least two independent clones have been obtained which show nonchromosomic inheritance character and an approximately 30-fold increase in methionyl-tRNA synthetase activity as compared to the wild type. Measurement of the Km for methionine in the transformed yeast cells indicates that the activity has been restored by decreasing the Km for methionine to the same level as found for the wild type methionyl-tRNA synthetase. Southern blotting experiments show that the yeast DNA's fragments inserted in the two independent plasmids share a common sequence which must correspond at least partly to the structural gene for methionyl-tRNA synthetase. They also suggest that the methionyl-tRNA synthetase gene is differently orientated in the two plasmids     

Construction of a cloning site near one end of Tn917 into which foreign DNA may be inserted without affecting transposition in Bacillus subtilis or expression of the transposon-borne erm gene

A 1.3-kb restriction fragment carrying a cat gene derived from Staphylococcus aureus was inserted by ligation in both possible orientations into a HpaI restriction site located less than 300 bp from one end of Tn917. The resulting transposon derivatives were unimpaired in their ability to make and resolve transpositions into the chromosome of Bacillus subtilis and they displayed no detectable defect in expression of the inducible erm gene carried by the transposon. This demonstrates that the HpaI site itself, and perhaps the entire 250- to 300-bp region between the HpaI site and the nearest transposon terminal inverted repeat consists of nonessential DNA, and is there fore available to be modified or used as a cloning site with the expectation that the resulting transposon derivatives should be capable of normal transposition activity. To facilitate such manipulations, the HpaI site was "replaced" by a 24-bp DNA segment which contains a BamHI site flanked on either side by SmaI sites; these BamHI and SmaI sites are unique to the transposon. Several of the plasmid constructions undertaken in the course of this work illustrate ways in which homologous recombination may be used in conjunction with ligation in B. subtilis (and other bacteria, such as Streptococcus pneumoniae, which have similar mechanisms for DNA uptake during competence) to facilitate significantly the recovery of certain kinds of recombinant molecules.     

Versatile cloning vector for Pseudomonas aeruginosa.

A pBR322:RSF1010 composite plasmid, constructed in vitro, was used as a cloning vector in Pseudomonas aeruginosa. This nonamplifiable plasmid, pMW79, has a molecular weight of 8.4 X 10(6) and exists as a multicopy plasmid in both P. aeruginosa and Escherichia coli. In P. aeruginosa strain PAO2003, pMW79 conferred resistance to carbenicillin and tetracycline. Characterization of pMW79 with restriction enzymes revealed that four enzymes (BamHI, SalI, HindIII, and HpaI) cleaved the plasmid at unique restriction sites. Cloning P. aeruginosa chromosomal deoxyribonucleic acid fragments into the BamHI or SalI site of pMW79 inactivated the tetracycline resistance gene. Thus, cells carrying recombinant plasmids could be identified by their carbenicillin resistance, tetracycline sensitivity phenotype. Deoxyribonucleic acid fragments of approximately 0.5 to 7.0 megadaltons were inserted into pMW79, and the recombinant plasmids were stably maintained in a recombination-deficient (recA) P. aeruginosa host.     

Cloned human polyomavirus JC DNA can transform human amnion cells.

The genome of the human polyomavirus JC (Mad-1 strain) was molecularly cloned in Escherichia coli by using the plasmid vector pBR322. Recombinant DNA molecules were constructed with the entire JC genome inserted either at its unique EcoRI site at 0.0 map units or at its unique BamHI site at 0.51 map units. Viral DNA from each of these recombinant plasmids was capable of transforming human amnion cells, and cell lines established from transformed foci were positive for JC tumor antigen as assayed by indirect immunofluorescence.     

Construction and characterization of three yeast-Escherichia coli shuttle vectors designed for rapid subcloning of yeast genes on small DNA fragments

We have constructed three new subcloning plasmid vectors, pRC1, pRC2, and pRC3, derived from pKC7, which allow the rapid, single-step subcloning of yeast genes. Subcloning with these vectors utilizes a partial digestion with Sau3A to generate a quasi-random set of DNA fragments from the original plasmid. All three vectors contain a kanamycin resistance gene. Therefore, if the original cloned yeast DNA fragment is present in a vector that does not specify kanamycin resistance, the subclone pool can be propagated in Escherichia coli in the presence of kanamycin to select against parent plasmids that escaped restriction by Sau3A. Selection by complementation in yeast yields a collection of plasmids with smaller yeast DNA inserts containing the gene of interest. In the vectors pRC2 and pRC3, constructed from pRC1, the unique BamHI site is located within an intact tetracycline resistance gene, thus making it possible to screen bacterial transformants for those containing recombinant plasmid molecules. Vectors pRC2 and pRC3 also contain the yeast 2 micrometers DNA replication origin, and thus are more stable than plasmids carrying only the TRP1-associated replicator (ars1).     

In vitro recognition of the replication origin of pLS1 and of plasmids of the pLS1 family by the RepB initiator protein.

Rolling-circle replication of plasmid pLS1 is initiated by the plasmid-encoded RepB protein, which has nicking-closing (site-specific DNA strand transferase) enzymatic activity. The leading-strand origin of pLS1 contains two regions, (i) the RepB-binding site, constituted by three directly repeated sequences (iterons or the bind region), and (ii) the sequence where RepB introduces the nick to initiate replication (the nic region). A series of plasmids, belonging to the pLS1 family, show features similar to those of pLS1 and have DNA sequences homologous to the pLS1 nic region. In addition, they all share homologies at the level of their Rep proteins. However, the bind regions of these plasmids are, in general, not conserved. We tested the substrate specificity of purified RepB of pLS1. The RepB protein has a temperature-dependent nicking-closing action on supercoiled pLS1, as well as on recombinant plasmid DNAs harboring the pLS1 nic region. The DNA strand transferase activity of pLS1-encoded RepB was also assayed on two plasmids of the pLS1 family, namely, pE194 and pFX2. DNAs from both plasmids were relaxed by RepB, provided they had a proper degree of supercoiling; i.e., it was necessary to modulate the supercoiling of pE194 DNA to achieve RepB-mediated DNA relaxation. Single-stranded oligonucleotides containing the nic regions of various plasmids belonging to the pLS1 family, including those of pE194 and pFX2, were substrates for RepB. In vitro, the RepB protein does not need to bind to the iterons for its nicking-closing activity.     

Heterogeneity among the 2 microns plasmids in Saccharomyces cerevisiae: a new sequence for the REP1 gene

Some species of yeasts contain naturally-occurring circular DNA plasmids. The most studied of these plasmids is the 2 microns circle of Saccharomyces cerevisiae. Three variants of this plasmid, Scp1, Scp2 and Scp3, have been described according to their restriction maps [Cameron et al., Nucleic Acids Res. 4 (1977) 1429-1448; Livingston, Genetics 86 (1977) 73-84]. The entire nucleotide (nt) sequence of the Scp1 variant from strain A364A has been published [Hartley and Donelson, Nature 286 (1980) 860-864]. We report here the nt sequence of the 2 microns plasmid REP1 gene from S. cerevisiae strain SKQ2n. According to the restriction analysis, this plasmid is the Scp3 variant previously described. The only observed differences between the Scp1 and Scp3 variants were the loss of one EcoRI restriction site and an apparent deletion in Scp3. The nt sequence we report differs significantly from the previously published one for Scp1. The differences correspond to 128 (about 8.5%) substituted, deleted or additional nt of 1510 nt compared. These differences affect the coding region (8%) as well as the noncoding regions (9.7%). Regarding the putative encoded proteins, 38 (about 10%) amino acids (aa) are modified or deleted in our sequence and 11 are added. Most of these aa modifications are not randomly distributed but are concentrated in certain regions. These observations are indicative of important intraspecific evolution between the two 2 microns plasmid variants considered, as well as of conservative selection pressure on some domains of the REP1 protein.     

The 2-micron plasmid as a nonselectable, stable, high copy number yeast vector

The endogenous 2-microns plasmid of Saccharomyces cerevisiae has been used extensively for the construction of yeast cloning and expression plasmids because it is a native yeast plasmid that is able to be maintained stably in cells at high copy number. Almost invariably, these plasmid constructs, containing some or all 2-microns sequences, exhibit copy number levels lower than 2-microns and are maintained stably only under selective conditions. We were interested in determining if there was a means by which 2-microns could be utilized for vector construction, without forfeiting either copy number or nonselective stability. We identified sites in the 2-microns plasmid that could be used for the insertion of genetic sequences without disrupting 2-microns coding elements and then assessed subsequent plasmid constructs for stability and copy number in vivo. We demonstrate the utility of a previously described 2-microns recombination chimera, pBH-2L, for the manipulation and transformation of 2-microns as a pure yeast plasmid vector. We show that the HpaI site near the STB element in the 2-microns plasmid can be utilized to clone yeast DNA of at least 3.9 kb with no loss of plasmid stability. Additionally, the copy number of these constructs is as high as levels reported for the endogenous 2-microns.     

Sequence of 863 nucleotides encompassing the PstI site of the yeast 2 micron plasmid.

The sequence of part of the larger unique region of the yeast 2 micron plasmid cloned in pMB9 has been determined. The sequence extends from the single EcoRI site in this region to the AvaI site and includes the single PstI site and HpaI site. A notable feature of this sequence is the presence of tandem repeats of 124 residues beginning at the HpaI site and extending beyond the AvaI site. The sequence was determined independently by both the Maxam-Gilbert procedure applied to isolated restriction fragments, and by the chain-termination procedure applied to restriction fragments cloned in the single-stranded phage M13mp2 and purified by plaque selection.     

A bovine papillomavirus E1-related protein binds specifically to bovine papillomavirus DNA.

The E1 open reading frame of bovine papillomavirus (BPV) was expressed as a RecA-E1 fusion protein in Escherichia coli. The bacterially expressed RecA-E1 protein exhibited sequence-specific DNA binding activity; strong binding to the region from nucleotides 7819 to 93 on the BPV genome (designated region A) and weak binding to the adjacent region from nucleotides 7457 to 7818 (region B) were observed. The interaction between the BPV-derived RecA-E1 protein and region A appeared to be highly specific for BPV DNA, as no comparable binding was detected with heterologous papillomavirus DNAs. Binding to region A was eliminated by digestion of region A at the unique HpaI site, which suggests that the RecA-E1 binding site(s) was at or near the HpaI recognition sequence. Binding to region B but not region A was observed when nuclear extracts from ID13 cells were used as a source of E1 proteins. The absence of region A binding by ID13 extracts may reflect a negative regulation of E1 DNA binding activity.     

Yeast centromere DNA is in a unique and highly ordered structure in chromosomes and small circular minichromosomes

We have examined the chromatin structure of the centromere regions of chromosomes III and XI in yeast by using cloned functional centromere DNAs (CEN3 and CEN11) as labeled probes. When chromatin from isolated nuclei is digested with micrococcal nuclease and the resulting DNA fragments separated electrophoretically and blotted to nitrocellulose filters, the centromeric nucleosomal sub-units are resolved into significantly more distinct ladders than are those from the bulk of the chromatin. A discrete protected region of 220–250 bp of CEN sequence flanked by highly nuclease-sensitive sites was revealed by mapping the exact nuclease cleavage sites within the centromeric chromatin. On both sides of this protected region, highly phased and specific nuclease cutting sites exist at nucleosomal intervals (160 bp) for a total length of 12–15 nucleosomal subunits. The central protected region in the chromatin of both centromeres spans the 130 bp segment that exhibits the highest degree of sequence homology (71%) between functional CEN3 and CEN11 DNAs. This unique chromatin structure is maintained on CEN sequences introduced into yeast on autonomously replicating plasmids, but is not propagated through foreign DNA sequences flanking the inserted yeast DNA.     

Transfer of chimeric plasmids among Salmonella typhimurium strains by P22 transduction

Salmonella typhimurium bacteriophage P22 transduced plasmids having P22 sequences inserted in the vector pBR322 with high frequency. Analysis of the structure of the transducing particle DNA and the transduced plasmids indicates that this plasmid transduction involves two homologous recombination events. In the donor cell, a single recombination between the phage and the homologous sequences on the plasmid inserted the plasmid into the phage chromosome, which was then packaged by headfuls into P22 particles. The transducing particle DNA contained duplications of the region of homology flanking the integrated plasmid vector sequences and lacked some phage genes. When these defective phage genomes containing the inserted plasmid infected a recipient cell, recombination between the duplicated regions regenerated the plasmid. A useful consequence of this sequence of events was that genetic markers in the region of homology were readily transferred from phage to plasmid. Plasmid transduction required homology between the phage and the plasmid, but did not depend on the presence of any specific P22 sequence in the plasmid. When the infecting P22 carried a DNA sequence homologous to the ampicillin resistance region of pBR322, the vector plasmid having no P22 insert could be transduced. P22-mediated transduction is a useful way to transfer chimeric plasmids, since most S. typhimurium strains are poorly transformed by plasmid DNA.     

Effective method of oligonucleotide-controlled mutagenesis of DNA fragments

A procedure has been designed for changing specific nucleotides in a DNA sequence with efficiency. The method involves the use of the specially constructed cloning vectors pBRS1, pHS1, and pHS2. These plasmids are derivatives of pBR322 in which the EcoRI-HindIII region has been replaced by synthetic duplexes carrying SmaI, HpaI and XhoI sites, in addition to EcoRI and HindIII sites. The DNA fragment to be mutagenized is cloned in pHS1 (or pBRS1, or pHS2) using restriction sites close to the SmaI and HpaI sites. The recombinant plasmid obtained is digested with one of these enzymes to produce double-stranded DNA with blunt ends. This linear DNA is a substrate for exonuclease III (or T4 DNA polymerase). The digestion under controlled conditions produces duplex with protruding single-stranded 5'-regions which include the site of the desired mutation. The synthesis of DNA by DNA-polymerase I (Klenow's fragment), primed in part by the synthetic oligonucleotide containing the desired mutation, leads to the linear heteroduplex. The closed circular heteroduplex is formed by ligation. After transformation into E. coli, DNA replication generates homoduplexes, some of which contain the mutation. Colony hybridization with the same 32P-labeled oligonucleotide is used to select mutants. The yield of the mutants is 10-20%. This technique can be extended to replicative form of M13 vectors. It can be also applied to any DNA sequence which has a unique site of restriction endonuclease generating blunt ends.     

Evidence for the involvement of a single major species of replicative complex in DNA synthesis from two diverse nuclear replicons in yeast

The activity that replicates the 2-micron yeast DNA plasmid in vitro can be isolated as a high-molecular weight (approximately 2 X 10(6)) fraction, which possesses many of the features of a multiprotein replicative complex. This fraction also initiates DNA synthesis at the yeast chromosomal replicator ARS1 raising the question whether the preparations discriminate between origins. It was determined that the binding of replicative complex to plasmids containing either 2-microns or ARS1 origins of replication was indistinguishable. The preparations also showed no preference among them for replication. In addition, the DNAs competed with each other to the same extent for binding of replicative complex. These results suggest that these two origins share one major species of replicative complex.     

Mapping of RNA polymerase binding sites in R12 derived plasmids carrying the replication-incompatibility region and the insertion element IS1.

Interactions between Escherichia coli RNA polymerase holoenzyme and three small plasmid DNAs (pSM1, pSM2, and pSM15) derived from the drug resistant factor R12 have been studied. These plasmids carry the copy number and incompatibility determinants, the origin of DNA replication and the rep gene(s) necessary for plasmid replication. They also contain the insertion element IS1 and the putative finO cistron. Thirteen DNA segments within the largest of the three plasmids (pSM2) were able to form either a binary and/or ternary complex with RNA polymerase. A unique strong binding site was mapped within the left end of IS1. Five binding sites were found within the rep-cop-inc region. Four of these are weak binding sites whereas the fifth does not form a stable binary complex and was detected by ternary complex formation. A strong binding site was located in the putative finO region whereas the remaining six binding sites are located in regions with unidentified genetic functions.     

Biochemical transformation of thymidine kinase (TK)-deficient mouse cells by herpes simplex virus type 1 DNA fragments purified from hybrid plasmids.

The thymidine kinase (TK) gene of HSV-1 has been cloned in Escherichia coli K12 plasmids, pMH1, pMH1A, and pMH4. These plasmids contain a 1,92Obp HSV-1 TK DNA sequence, which replaces a 2,067 bp EcoR I to Pvu II sequence of plasmid pBR322 DNA. Superhelical DNAs of plasmids pMH1, pMH1A, and pMH4 as well as plasmid DNAs cleaved by EcoR I, Hinc II, Bg1 II, Sma I, and Pvu II transformed TK-deficient LM(TK-) cells to the TK+ phenotype. A 1,230bp EcoR I-Sma I fragment purified from pMH1 DNA (and from plasmid pAGO, DNA, the parent of pMH1) also transformed LM(TK-) cells. Serological and disc PAGE studies demonstrated that the TK activity expressed in biochemically transformed cells were HSV-1-specific. The experiments suggest that the HSV-1 TK coding region may be contained within a l.1kbp DNA sequence extending from about the Hinc II (or Bgl II) cleavage site to the Sma I site. 35S-methionine labeling experiments carried out on cell lines transformed by Hinc II-cleaved pMH1 DNA and by the EcoR I-Sma I fragment showed that the TKs purified from the transformed cells consisted of about 39-40,000 dalton polypeptides.     

Localization of the replication control region on the physical map of the octopine Ti plasmid

A series of small plasmids has been derived from the octopine plasmid pTi-B6 by in vitro manipulation. The smallest plasmid that is able to replicate in Agrobacterium tumefaciens contains the ampicillin-resistance determinant from Tn1, coupled to a piece of DNA that is homologous to HpaI fragment number 11 of the octopine Ti plasmid pTi-Ach 5. The incompatibility functions are also specified by this region.     

Changes in the DNase I sensitivity of DNA sequences within the yeast 2 micron plasmid nucleoprotein complex effected by plasmid-encoded products

We examined the effect of plasmid-encoded gene products on two DNase-I-sensitive regions of DNA in the yeast 2 micron plasmid nucleoprotein complex. For these studies, each sensitive region was cloned into an appropriate vector, and the chimeric plasmids were transformed into yeast. Nucleoprotein complexes of the chimeric plasmids were partially purified and tested for sensitivity to DNase I digestion. One sensitive region is between the 3' end of the 2 micron plasmid coding region D and the plasmid REP3 locus. This region was more sensitive and exhibited a different cleavage pattern when purified from a yeast strain containing endogenous 2 micron plasmid copies than when purified from a yeast strain lacking plasmid copies. Examination of the effect of individual gene products and combinations of the various gene products revealed that the plasmid's REP1, REP2 and D loci were all necessary to restore the pattern to that found in the preparation containing endogenous 2 micron plasmid copies. The other sensitive region studied brackets the binding site of the plasmid-encoded FLP protein, which catalyzes site-specific recombination between the 2 micron plasmid's inverted repeated sequences. In contrast to the first sensitive region examined, the sensitive region in the inverted repeat was less sensitive in chimeric plasmids isolated from a yeast strain containing endogenous 2 micron plasmid copies than from one lacking endogenous copies. Presumably, this protection results from the binding of the FLP protein.