Properties of new Escherichia coli Hfr strains constructed by integration of pSC101-derived conjugative plasmids.

Conjugative temperature-sensitive plasmids were derived from pSC101. These plasmids are useful in genetic analysis for two reasons: (i) they render possible the construction of new Hfr lines by plasmid integration at predetermined chromosomal loci via Tn10 inverse transposition, and (ii) the Hfr characters are transducible via bacteriophage P1. We also showed that replication from pSC101 origin is deleterious for the plasmid-chromosome fusion.     

Organization of chimeras between filamentous bacteriophage f1 and plasmid pSC101

Two recombinants formed in vivo between the filamentous phage f1 and the tetracycline-resistance-conferring plasmid pSC101 are capable of transducing sensitive cells to Tet^r. These chimeric filamentous phage, VO-1 and VO-2, were previously shown to contain the entire f1 and pSC101 genomes (Vovis et al., 1977; Ohsumi et al., 1978). The genomes of VO-1 and VO-2 are unstable in vivo; VO-1 breaks down to yield a molecule similar to pSC101 and an f1-like species, f1′. f1′ was previously shown to differ from f1 by the presence of 209 additional nucleotides inserted in the carboxy-terminal portion of gene IV (Ravetch et al., 1979). We have found by hybridization analysis and direct DNA sequencing that this 209-nucleotide segment is present in one copy in pSC101, and that it has properties similar to known transposable elements. Therefore, we have called this sequence IS101. We have characterized the structures of both VO-1 and VO-2 in greater detail by restriction mapping and DNA sequence analysis. Both chimeras contain two copies of IS101, which are present as direct repeats and form the junctions between the f1 and pSC101 genomes. The IS101 elements in VO-1 and VO-2 are flanked by a five-base direct repeat of f1 sequence that is not repeated in wild-type f1. The junction between f1 and pSC101 in VO-1 is located at the same point as the IS101 element in f1′, while in VO-2 the junction between the two genomes is at a point in f1 located between the promoter and ribosome binding site for gene VIII. The pSC101-like molecules derived from the breakdown of VO-1 in vivo are identical to the original pSC101 in the region of IS101. The IS101 elements in the original and derived pSC101 plasmids are not flanked by any repeated sequence. Attempts to regenerate VO-1 from f1′ and pSC101, both of which contain one IS101 element, indicate that the breakdown of VO-1 is irreversible. These results are discussed in terms of current models for transposition, which postulate structures similar to VO-1 and VO-2 as intermediates in transposition.     

The partition (par) locus of pSC101 is an enhancer of plasmid incompatibility

The incompatibitity that pSC101-derived plasmids express toward each other is mediated by directly repeated sequences (iterons) located near the plasmid's replication origin. We report here that the pSC101 par locus, which stabilizes plasmid inheritance in dividing cell populations and alters DNA superheliclty, can function as a cis-acting enhancer of incompatibility, which we show is determined jointly by the copy number of the plasmid and the number of iterons per copy. A single synthetic 32 bp iteron sequence carried by the pUC19 plasmid confers strong pSC101-specific incompatibility in the absence of any other pSC101 sites but requires the par locus to express strong incompatibility when carried by a lower-copy-number plasmid. We propose a model by which the par locus can enchance the apparently antagonistic processes of incompatibility and pSC101 DNA replication while concurrently facilitating plasmid distribution during cell division.     

Transposition of the composite synthetic transposon TnV (Tn5-Rep(pSC101)) is accompanied by the formation of the mini-plasmid pTnV, containing defective Is50-elements

Using thermoelimination (at 42 degrees C) of the thermoinducible coliphage P1tsCmr omega::TnV (TnV is a Tn5 derivative which contains the replication origin (Rep) of plasmid pSC101), more than 110 KmrCms Escherichia coli K12 clones were selected. It was supposed that the KmrCms phenotype could result only from insertion of TnV (Kmr) into E. coli chromosome and the loss of phage (Cms). It was found that the majority of KmrCms clones (35-90%) contained miniplasmids. Their molecular sizes did not exceed the TnV size (6.1 kb). The formation of miniplasmids called pTnV was observed both in RecA+ cells (C600) and in RecA- (HB101), more often in the latters. Interestingly, that miniplasmids of only several molecular sizes were detected: from 6.1 kb (pTnV60) to 4.35 kb (pTnV43). A restriction analysis showed that DNA of the majority of pTnV plasmids had varying deletions (0.3-1.3 kb) of mainly IS50L element which together with IS50R flank TnV. Very low transposition frequencies (approx. 10(-8) Kmr transconjugants per transferred R388) of all pTnV types (including pTnV60 plasmids containing probably microdeletions of the joining "outside" IS50's ends) suggest that pTnV plasmids are not intermediates in TnV transposition. Possibly the circularized TnV derivatives (pTnV's) are side products of the transposition resulting from the abortive attempts of an excised and autonomous transposon molecule to insert into itself. In the present paper the possible mechanisms of the origin of limited pTnV type numbers are also discussed.     

Deletions within E. coli plasmids carrying yeast rDNA.

Deletions occur in recombinant DNA plasmids that contain yeast ribosomal DNA (rDNA) inserted into the E. coli plasmids pSC101 and pMB9. Deletions within a pMB9 plasmid containing an insert longer than one tandem rDNA repeat apparently are due to homologous recombination because (1) all of the independently derived deletion products of this plasmid lost one complete rDNA repeat (8.6 kb) and retained only a single copy of the segment repeated at the ends of the original insert and (2) deletions were detected only when the insert had terminal redundancy. Deletions also occur within a pSC101 plasmid containing a tandem duplication of a segment (4.7 kb) including both pSC101 DNA and rDNA. Once again these deletions appear to be due to the presence of a duplicated region because all deletion products have lost one complete repeat. Deletions within both of these plasmids took place in both rec+ and recA- host cells, but occurred more frequently in rec+ cells. Oligomerization of the deletion products also occurred in both hosts and was more frequent in rec+ cells.     

Site-specific deletions in the recombinant plasmid pSC101 containing the redB-ori region of phage lambda

Large deletions occur in the hybrid plasmid formed by pSC101 and the EcoRI fragment f2 of phage lambda (redB-ori region) under well defined growth conditions (Bernardi and Bernardi, 1980). We have sequenced the novel joints of the four deletions so obtained and shown that they have one endpoint in pSC101, identical in all four cases, the other endpoint being located in four different lambda sequences. Furthermore, the nucleotide sequences of the novel joints show homologies between the conserved pSC101 sequence and the lambda sequences both conserved and deleted. The presence of an IS-type element in pSC101 is postulated; however, this element is unrelated to the 200 bp element already described in pSC101 (Ravetch et al., 1976).     

New pSC101-derivative cloning vectors with elevated copy numbers

Mutations that increase the copy number of the pSC101 replicon have been used for construction of new cloning vectors. Replacement of glutamate at position 93 in RepA yields plasmids that replicate at medium (27 copies/cell) and high (approximately 240 copies/cell) copy numbers. Based on the crystal structure of RepE, a structurally similar replication initiator protein from the F factor, the pSC101 repA mutants are predicted to be defective in dimerization. The cloning vectors permit increased expression of gene products along with the advantages of pSC101-derivative plasmids, including stable maintenance and compatibility with ColE1 plasmids. The plasmids also allow blue/white screening for DNA inserts and impart resistance to ampicillin, chloramphenicol and kanamycin. The vectors were used in a genetic assay to suppress temperature-sensitive mutants of ffh, encoding the protein component of the Escherichia coli signal recognition particle, by overproduction of 4.5S RNA. While expression of 4.5S RNA from a wild type pSC101-derivative plasmid was not sufficient for suppression, use of the new vectors did suppress the temperature-sensitive phenotype.     

Physical Analysis of Tn10- and Is10-Promoted Transpositions and Rearrangements

We have investigated by Southern blot hybridization the rate of IS10 transposition and other Tn10/IS10-promoted rearrangements in Escherichia coli and Salmonella strains bearing single chromosomal insertions of Tn10 or a related Tn10 derivative. We present evidence for three primary conclusions. First, the rate of IS10 transposition is approximately 10(-4) per cell per bacterial generation when overnight cultures are grown and plated on minimal media and is at least ten times more frequent than any other Tn10/IS10-promoted DNA alteration. Second, all of the chromosomal rearrangements observed can be accounted for by two previously characterized Tn10-promoted rearrangements: deletion/inversions and deletions. Together these rearrangements occur at about 10% the rate of IS10 transposition. Third, the data suggest that intramolecular Tn10-promoted rearrangements preferentially use nearby target sites, while the target sites for IS10 transposition events are scattered randomly around the chromosome.     

A 37 X 10(3) molecular weight plasmid-encoded protein is required for replication and copy number control in the plasmid pSC101 and its temperature-sensitive derivative pHS1

Nucleotide sequences were determined for a region essential for autonomous replication and partitioning of pSC101, a plasmid whose replication is dependent on the Escherichia coli dnaA gene product. The essential replication region contains one long coding sequence, rep101 , for a protein composed of 316 amino acids, and a polypeptide approximately 37 X 10(3) Mr in size was identified as the rep101 gene product. rep101 is preceded by two inverted repeat sequences, three directly repeated sequences and a region of high A + T content containing a sequence similar to the E. coli oriC consensus sequence. Because the lesions in seven replication-deficient insertion mutants, four mutants with increased copy number and one temperature-sensitive replication mutant occur within rep101 , the rep101 gene product must control pSC101 replication and copy number. par, a region adjacent to the replication region, which functions in stable plasmid inheritance, contains several inverted repeat sequences.     

IS1-mediated intramolecular rearrangements: formation of excised transposon circles and replicative deletions.

A system is described which permits visualization and analysis of a number of molecular species associated with transposition activity of the bacterial insertion sequence, IS1, in vivo. The technique involves induction of an IS1 transposase gene carried by a plasmid which also includes an IS1-based transposable element. It is, in principle, applicable to the identification of transposition intermediates as well as unstable transposition products and those which are not detectable by genetic means. Thirteen novel molecular species were detected after 4 h of induction. Five major species were characterized, based on their behaviour as a function of time, on their hybridization patterns and on the nucleotide sequences of the transposon-backbone junctions. All result from intramolecular IS1 transposition events. The two reciprocal partner products of IS1-mediated deletions, the intramolecular equivalent of co-integrates generated by intermolecular transposition, have been identified. Both carry a single copy of the transposable element and present complementary distributions of deletion endpoints. These results establish, by direct physical means, that adjacent IS1-mediated deletions are accompanied by duplication of the element. A second type of molecule identified was an excised circular copy of the transposon, raising the possibility that IS1 is capable of following an intermolecular transposition pathway, via excised transposon circles, leading to direct insertion.     

Neighboring plasmid sequences can affect Mini-Mu DNA transposition in the absence of expression of the bacteriophage Mu semi-essential early region

Bacteriophage Mu DNA, like other transposable elements, requires DNA sequences at both extremities to transpose. It has been previously demonstrated that the transposition activity of various transposons can be influenced by sequences outside their ends. We have found that alterations in the neighboring plasmid sequences near the right extremity of a Mini-Mu, inserted in the plasmid pSC101, can exert an influence on the efficiency of Mini-Mu DNA transposition when an induced helper Mu prophage contains a polar insertion in its semi-essential early region (SEER). The SEER of Mu is known to contain several genes that can affect DNA transposition, and our results suggest that some function(s), located in the SEER of Mu, may be required for optimizing transposition (and thus, replication) of Mu genomes from restrictive locations during the lytic cycle.     

Control of tryptophan synthetase amplified by varying the numbers of composite plasmids in Escherichia coli cells.

Using pSC101, RSF1010, RSF2124 and RP4 plasmids as vectors and bacteriophage lambdatrpD-A60-3 DNA as a source of the Escherichia coli whole tryptophan operon, composite plasmids of pSC101-trp, RSF1010-trp, RSF2124-trp and RP4-trp were constructed in vitro with EcoRI restriction endonuclease and DNA ligase. Each composite plasmid could be maintained stably in E. coli cells. The copy number of pSC101-trp, RSF1010-trp, RSF2124-trp and RP4-trp were 4.2, 11.2, 11.9 and 1.6 per chromosome respectively. The tryptophan synthetase activities in cells containing pSC101-trp, RSF1010-trp, RSF2124-trp aand RP4-trp plasmid were found to be 2.1, 6.0, 5.0 and 2.5 times compared with the level in chromosomal trp+ cells when they were grown in a minimal medium. By partial derepression with indolylacrylic acid, the enzyme levels were elevated to 10.1, 16.3, 15.3, 12.3 times, respectively, that of the control cells. The tryptophan synthetase activities did not increase in proportion to the copy number of the plasmids, but were strongly affected by the repression system of host cells.     

Simple and efficient generation in vitro of nested deletions and inversions: Tn5 intramolecular transposition.

We have exploited the intramolecular transposition preference of the Tn 5 in vitro transposition system to test its effectiveness as a tool for generation of nested families of deletions and inversions. A synthetic transposon was constructed containing an ori, an ampicillin resistance (Ampr) gene, a multi-cloning site (MCS) and two hyperactive end sequences. The donor DNA that adjoins the transposon contains a kanamycin resistance (Kanr) gene. Any Amprreplicating plasmid that has undergone a transposition event (Kans) will be targeted primarily to any insert in the MCS. Two different size targets were tested in the in vitro system. Synthetic transposon plasmids containing either target were incubated in the presence of purified transposase (Tnp) protein and transformed. Transposition frequencies (Ampr/Kans) for both targets were found to be 30-50%, of which >95% occur within the target sequence, in an apparently random manner. By a conservative estimate 10(5) or more deletions/inversions within a given segment of DNA can be expected from a single one-step 20 microl transposition reaction. These nested deletions can be used for structure-function analysis of proteins and for sequence analysis. The inversions provide nested sequencing templates of the opposite strand from the deletions.     

Isolation and characterization of plasmid mutations that enable partitioning of pSC101 replicons lacking the partition (par) locus.

Second-site mutations that allow stable inheritance of partition-defective pSC101 plasmids mapped to seven distinct sites in the 5' half of the plasmid repA gene. While the mutations also elevated pSC101 copy number, there was no correlation between copy number increase and plasmid stability. Combinations of mutations enabled pSC101 DNA replication in the absence of integration host factor and also stabilized par-deleted plasmids in cells deficient in DNA gyrase or defective in DnaA binding. Our findings suggest that repA mutations compensate for par deletion by enabling the origin region RepA-DNA-DnaA complex to form under suboptimal conditions. They also provide evidence that this complex has a role in partitioning that is separate from its known ability to promote plasmid DNA replication.     

Sequence organization and expression of a yeast plasmid DNA.

Saccharomyces cerevisiae strain A364A D5 contains circular double-stranded DNA molecules of 6230 +/- 30 base pairs (2mu DNA) which are present in 68 copies per cell and make up 2.4% of the haploid genome. About 0.4% of non-poly A containing yeast RNA hybridizes to the yeast DNA circles. When denatured and then self-annealed, the DNA molecules assume a characteristic "dumbbell" shape in the electron microscope indicating that each circle possesses a non-tandem inverted repeat sequence of 630 +/- 10 base pairs. Eco-RI digestion of purified 2mu DNA yields 4 fragments on an agarose gel whose combined molecular mass is twice that of the monomer circle, suggesting that there are 2 populations of circles, each of the same molecular weight. Representatives of each population have been separated by cloning in Escherichia coli via the bacterial plasmid pSC101. Heteroduplex analysis of the cloned circles show that the 2 different populations arise because of intramolecular recombination between the inverted repeat sequences. Acrylamide gel patterns of polypeptides synthesized in bacterial mini-cells containing the hybrid plasmids between 2mu DNA and pSC101 are significantly different than the pattern obtained from mini-cells containing pSC101 alone.     

The structure and function of the replication initiator protein (Rep) of pSC101: an analysis based on a novel positive-selection system for the replication-deficient mutants

Plasmid pSC101 encodes a 37.5 kDa Rep (RepA) protein, which binds to three 21-base repeats (DR-1, DR-2, and DR-3) in the replication origin region (ori) of the plasmid to initiate replication. Rep also binds to two palindromic sequences (IR-1 and IR-2) which overlap the rep promoter. The binding of Rep to IR-2 represses the production of Rep itself. It is highly likely that the balance of these functions of Rep plays a major role in controlling the copy number of pSC101. In this study, we developed a positive-selection system for replication-deficient mutants of the initiator protein. This system can be applied to the study of other replication systems by changing ori and rep of pSC101 to the corresponding genes. Thirty-four replication-deficient (Ini(-)) mutants were isolated with this system, and analyzed as to the relation between the structure and function of the Rep protein. Seventeen of these 34 Ini(-) mutants were found to lack auto-repressor activity as well as initiator activity. DNA sequence analysis showed that one-third (from the C-terminus) of Rep is dispensable for the auto-repressor activity, while the initiator activity seems to require the whole protein.     

Excess intracellular concentration of the pSC101 RepA protein interferes with both plasmid DNA replication and partitioning.

RepA, a plasmid-encoded gene product required for pSC101 replication in Escherichia coli, is shown here to inhibit the replication of pSC101 in vivo when overproduced 4- to 20-fold in trans. Unlike plasmids whose replication is prevented by mutations in the repA gene, plasmids prevented from replicating by overproduction of the RepA protein were lost rapidly from the cell population instead of being partitioned evenly between daughter cells. Removal of the partition (par) locus increased the inhibitory effect of excess RepA on replication, while host and plasmid mutations that compensate for the absence of par, or overproduction of the E. coli DnaA protein, diminished it. A repA mutation (repA46) that elevates pSC101 copy number almost entirely eliminated the inhibitory effect of RepA at high concentration and stimulated replication when the protein was moderately overproduced. As the RepA protein can exist in both monomer and dimer forms, we suggest that overproduction promotes RepA dimerization, reducing the formation of replication initiation complexes that require the RepA monomer and DnaA; we propose that the repA46 mutation alters the ability of the mutant protein to dimerize. Our discovery that an elevated intracellular concentration of RepA specifically impedes plasmid partitioning implies that the RepA-containing complexes initiating pSC101 DNA replication participate also in the distribution of plasmids at cell division.     

Characterization of copy number mutants of plasmid pSC101

We have characterized three copy number mutants of the plasmid pSC101. These mutations caused single amino acid substitutions at the 46th, 83rd and 115th codons in the rep gene and an increase in the copy number by 4- to 8-fold. Although the in vivo and in vitro repressor activities of these mutated Rep proteins were quite different from each other, the intracellular concentrations of the proteins were maintained at higher levels than the wild-type protein. It has been reported that excess amounts of Rep inhibit pSC101 replication (Ingmer and Cohen, 1993). This inhibitory activity of Rep was markedly decreased in all three mutants. When both the wild-type and one of the mutated rep genes were retained in the same plasmids, the copy number of these plasmids was decreased compared with plasmids retaining a single mutated rep gene. These results support the theory that the inhibitory activity of Rep for its own replication plays an important role in copy number regulation.