Establishment of Escherichia coli cells with an integrated high copy number plasmid

Autogenous regulation of synthesis of the replication protein in plasmid pSC101

A 1.3-kb segment of plasmid pSC101 includes the replication origin (ori) and the gene (rep) encoding the 37 kilodalton (K) protein required for autonomous replication of the plasmid. The present work describes the regulation of the rep gene expression. The gamma promoters PR and PL fail to promote rep gene expression when located upstream of a sequence with dyad symmetry overlapping the rep promoter, whereas elimination of this sequence allows expression and results in over-production of the rep protein. When expression of trpA'-lacZ is controlled under the rep promoter, beta-galactosidase is produced without the lac inducer. However, this enzyme synthesis is effectively reduced when the complete rep sequence is provided in trans. A partial disruption of the sequence with dyad symmetry relieves the repression. These results suggest that expression of the rep gene is negatively regulated by its own product and that the sequence with dyad symmetry plays the role of a receptor site for the rep protein.

Endonuclease III (nth) mutants of Escherichia coli

Two strains that overproduce endonuclease III were found in a colony bank containing hybrid ColE1-Escherichia coli plasmids. The enzyme was identified in crude extracts by the degradation of partially depyrimidinated DNA in the presence of EDTA, by its sedimentation velocity, and by its associated thymine glycol-DNA glycosylase activity. An insertion mutation was produced by cloning the kanamycin-resistance gene of Tn5 into the plasmid copy of the nth gene. The mutation was then transferred to the chromosome in the following steps: (i) selection for chromosomal integration of the plasmid at 42 degrees C in a temperature-sensitive polA strain, (ii) curing via temperature shifts, and (iii) phage P1-mediated transduction of a new host. The insertion mutant, as well as a separately isolated deletion mutant, had no measurable glycosylase activity for DNA containing thymine glycol. Although such residues are common lesions in oxidized or irradiated DNA, the mutants were not unusually sensitive to H2O2 or gamma-rays. The insertion mutation had a mutator effect (4- to 22-fold enhancement) on one tested allele.

In vivo transfer of chromosomal mutations onto multicopy plasmids by transduction with bacteriophage P1

A technique is presented by which chromosomal mutations may be efficiently transferred onto chimeric multicopy plasmids in vivo. The technique employs the transduction of plasmids using bacteriophage P1 as vector. The utility of this method was demonstrated by cloning a chromosomal ompR mutation of Escherichia coli K-12. The high-frequency transduction of the chimeric plasmid appeared to be dependent on its integration into the chromosome by homologous recombination. The results also suggest that the plasmid was transduced as part of the chromosome and resolved from its integrated state in the recipient cell, resulting in a high yield of mutant plasmid segregants.

Replacement of the fip gene of Escherichia coli by an inactive gene cloned on a plasmid

To determine whether the fip gene of Escherichia coli, which is required for filamentous phage assembly, is required for cell viability, we replaced the chromosomal copy of the gene with an inactive copy introduced on a plasmid. We found that the fip gene is dispensable. The method we devised, which should be generally useful, was also tested with an inactivated rho gene. As expected, the rho gene is essential.

The replication origin of pSC101: the nucleotide sequence and replication functions of the ori region

The nucleotide sequence of a 770-bp ori region of plasmid pSC101 is presented. The sequence shows homologies to some parts of Escherichia coli oriC and phage G4 ori. Several other features are an 80-bp A + T-rich region overlapping a part of the region homologous to oriC, three direct repeats of an 18-bp sequence adjacent to the A + T-rich region, a typical promoter sequence just upstream of the longest open reading frame (ORF) and a long inverted repeat sequence overlapping the putative promoter region. Analysis of successive deletions by BAL31 exonuclease demonstrated that one of the regions homologous to oriC along with the A + T-rich region are essential for autonomous replication of the plasmid. The three 18-bp repeats are responsible for incompatibility phenotype. The region containing the promoter-like sequence is required for expression of a trans-acting function.

A technique for integrating any DNA fragment into the chromosome of Escherichia coli

We describe a technique that allows the insertion of any DNA fragment into the EcoRI-site-containing malPpa, the promoter of malPQ, one of the three maltose operons of Escherichia coli. DNA fragments were cloned into the unique EcoRI site of the pBR322-derived plasmid pOM40, which carries malPpa. In the next step these fragments were transposed into the chromosome by homologous recombination events occurring on both sides of malPp. Cells in which such insertion of the entire recombinant plasmid have occurred can be conveniently selected. Excision and curing of the vector plasmid could then occur spontaneously at a high frequency, leaving behind the inserted fragment that can be manipulated as any chromosomal marker. When the inserted fragment contains a properly positioned promoter, its promoting activity can be estimated by assaying amylomaltase, the product of malQ. When required, the inserted fragment can be easily transferred back onto pOM40. As examples of application we have transferred two different fragments into the chromosome of E. coli: one contained the ceaC-ceiC operon, which encodes colicin E3 and its immunity protein, and the other contained the lac promoter of E. coli.

Cloning of the integration and attachment regions of bacteriophage P4

The integration and attachment regions of bacteriophage P4 have been cloned into a multicopy plasmid. This plasmid can integrate into the E. coli chromosome at the same location as the parent phage. Integration increases the stability of the plasmid and allows it to be retained even under conditions in which a non-integrated plasmid would be lost. None of the genes needed for P4 lytic growth is required for integration. The P4 integration and attachment regions have been cloned on separate plasmids. A plasmid that carries the attachment site can integrate into the chromosome only if another plasmid that carries the P4 integration functions is present. A plasmid that carries only this trans-acting integration function cannot integrate. Using deletion mutants of the plasmid, the maximum size of the region needed for integration has been determined to be 1.6 kb, of which no more than 1.2 kb codes for the integrase protein. A nonsense mutant defective in integration has been isolated by using a rapid screening procedure that identifies unstable plasmids.

Fructose bisphosphatase of Escherichia coli: cloning of the structural gene (fbp) and preparation of a chromosomal deletion

The fbp locus at 96 min on the Escherichia coli chromosome governs fructose bisphosphatase (fructose-1,6-P2 1-phosphatase). We have cloned and subcloned fbp on vector pBR322 to obtain strains with high levels of the enzyme. In vivo mutagenesis of the clone was used to show that fbp is the structural gene. The gene was deleted on the plasmid in vitro, and the chromosomal wild-type locus was replaced with this deletion by a method involving stabilization of a heterozygous intermediate resulting from plasmid integration, followed by segregation of the wild-type gene.

P1 plasmid replication: replicon structure

Bacteriophage P1 lysogenizes Escherichia coli as a unit-copy plasmid. We have undertaken to define the plasmid-encoded elements implicated in P1 plasmid maintenance. We show that a 2081 base-pair fragment of the 90,000 base P1 plasmid confers the capacity for controlled plasmid replication. DNA sequence analysis reveals several open reading frames in this fragment. The largest is shown to encode a 32,000 Mr protein required for plasmid replication. The corresponding gene, repA, has been identified genetically. A set of five 19 base-pair repeats is located upstream from repA; a set of nine similar repeats is located immediately downstream from repA. Each set of repeats, when cloned into pBR322, exerts incompatibility towards a P1 replicon. The upstream set, designated incC, consists of direct repeats that are spaced about two turns of the DNA helix apart; the downstream set, designated incA, consists of nine repeats arranged three in one orientation and six in the other. Spacing between incA repeats were three or four turns of the helix apart. The organization of the plasmid maintenance regions of P1 and the unit-copy sex factor plasmid, F, is strikingly similar. Although the DNA sequences of this region in the two plasmids exhibit little homology, a 9 base-pair sequence that appears four times in the origin region of members of the Enterobacteriaceae also occurs twice as direct repeats in similar positions in P1 and F. This sequence, where it occurs in E. coli, has been postulated to be the binding site for the essential replication protein determined by dnaA. The dnaA protein appears not to be essential for the replication of either plasmid; therefore, the function of the sequence in P1 and F may be regulatory.

Function of RNase H in DNA replication revealed by RNase H defective mutants of Escherichia coli

Escherichia coli rnh mutants were isolated using localized mutagenesis and selective measurements of RNase H activity in mutagenized cell extracts with [3H]poly(rC) X poly(dG) as substrate. RNase H activity in extracts of one mutant, ON152 (rnh-91), was undetectable (less than 0.05% of that of wild-type cells). This mutant formed small colonies at 43 degrees C. At this temperature, accumulation of nascent fragments was more prominent in the rnh-91 X polA4113 double mutant than in the polA4113 mutant; however, no accumulation was found in the rnh single mutant at 43 degrees C. Unlike the 1-3 nucleotide primer RNA found on nascent fragments of polA4113 cells, primers from the rnh-91 X polA4113 cells ranged from one to about ten bases. These results suggest that the 5' leads to 3' exonuclease activity of DNA polymerase I plays a major role in removal of primer RNA and that RNase H functions in an auxiliary role, excising the 5'-portion of longer primers. The rnh mutant supports replication of ColE1-type plasmids. A possible mechanism of replication of such plasmids in rnh mutants and a role of RNase H in the initiation of chromosomal replication are discussed.

Replication defective RP4 plasmids recovered after chromosomal integration

pHH6000 is a composite replicon made by the in vitro ligation of the IncP plasmid RP4 to a fragment of bacteriophage lambda capable of autonomous replication. Derivatives were selected in which it had integrated into the Escherichia coli chromosome by homologous recombination with the resident lambda prophage, and plasmids were subsequently regenerated from the integrated molecules. Although of the same molecular size as pHH6000, all had altered properties: those recovered from the chromosome of cells simultaneously carrying a distinguishable autonomous IncP plasmid showed a 100- to 1000-fold reduction in their ability to become established in a lambda lysogen; those regenerated from cells with no autonomous IncP plasmid were no longer RP4 replicons, now being dependent on replication functions encoded by the lambda DNA they carry and therefore unable to form a plasmid in a lambda lysogen. This second class of plasmids still exhibited normal RP4 incompatibility and stability even though neither property is encoded by the lambda replicator DNA. It was concluded that expression of RP4 incompatibility and partitioning control do not require an intact RP4 replicon. The data also suggest that the presence in the chromosome of a normal RP4 molecule may be deleterious to the host, although the manner in which the integrated molecules were obtained allows other explanations. The composite plasmids replicating from cloned lambda genes should be useful in analysis of the regulated distribution of RP4 molecules at cell division.

Evidence for positive regulation of plasmid prophage P1 replication: integrative suppression by copy mutants

Like low-copy-number plasmids including P1 wild type, multicopy P1 mutants (P1 cop, maintained at five to eight copies per chromosome) can suppress the thermosensitive phenotype of an Escherichia coli dnaA host by forming a cointegrate. At 40 degrees C in a dnaA host suppressed by P1 cop, the only copy of P1 is the one in the host chromosome. Trivial explanations of the lack of extrachromosomal copies of P1 cop have been eliminated: (i) during integrative suppression, the P1 cop plasmid does not revert to cop+; (ii) the dnaA+ function of the host is not required to maintain P1 cop at a high copy number; and (iii) integrative recombination does not occur within the region of the plasmid involved in regulation of copy number. Since there are no more copies of the chromosomal origin (now located within the integrated P1 plasmid) than in a P1 cop+-suppressed strain, the extra initiation potential of the P1 cop is not used to provide multiple initiations of the chromosome. When a P1 cop-suppressed dnaA strain was grown at 30 degrees C so that replication could initiate from the chromosomal origin as well as from the P1 origin, multicopy supercoiled P1 DNA was found in the cells. This plasmid DNA was lost again when the temperature was shifted back to 40 degrees C.

A novel type of E. coli mutants with increased chromosomal copy number

We have isolated E. coli mutants which can grow at 30 degrees C but not at 42 degrees C and are able to harbor the oriC plasmid (minichromosome) at a higher copy number than the parental wild-type strain at the permissive temperature. The mutants were found to contain higher amounts of chromosomal DNA per mg protein than the wild-type, whether or not they harbor the plasmid. Experimental results suggest that the higher amount of chromosomal DNA is due to a higher copy number of chromosomes and not to a larger amount of DNA per chromosome. These properties in each of the mutants are caused by a single mutation at the rpoB or rpoC gene that code for the beta or beta' subunit of RNA polymerase, respectively. The mutations are thought to affect the regulation of replication of oriC-bearing replicons, that is, the E. coli chromosome and oriC plasmids, but not the miniF plasmid.

Isolation and characterization of a higher-copy-number mutant of plasmid R6K

A stable copy-number mutant (pNH601) of plasmid R6K was isolated by selection for increased resistance to ampicillin determined by this plasmid. The size of the mutant plasmid was found to be unchanged (26 Mg/mol) but it is present in 27 copies of pNH601 per E. coli K-12 chromosome which represents a two-fold increase of R6K copy number value. The following genetic properties of pNH601 are reported and compared with those of R6K: conjugative transfer, fertility inhibition of plasmids belonging to other incompatibility groups, incompatibility with plasmid R485 under both non-selective and selective conditions and the integrative suppression of the dnaA ts mutation. The mutant plasmid pNH601 was found to be different from the original R6K in most of these properties.

Replacement and amplification of bacterial genes with sequences altered in vitro

An efficient method for the replacement of chromosomal DNA by segments altered in vitro has been developed for bacteria. The method requires (i) a recombinant plasmid with a ColE1-like replicon and (ii) a strain defective in DNA polymerase I (polA), which is unable to replicate the plasmid extrachromosomally. This method is of general use since there are a number of suitable vectors and polA strains are available in both Escherichia coli and Salmonella typhimurium, the two most widely studied bacterial species. Using the method, we have constructed two chromosomal deletions in the chemotaxis gene region of S. typhimurium. In addition, plasmid sequences integrated into the chromosome have been amplified up to 30-fold by varying the concentration of ampicillin or tetracycline in the growth medium.

Genetic mapping of the Escherichia coli leader (signal) peptidase gene (lep): a new approach for determining the map position of a cloned gene

The gene for leader peptidase, termed lep, was mapped to the region between purI and nadB at min 54 to 55 on the Escherichia coli chromosome. Mapping involved (i) cloning the gene into the plasmid pBR322, (ii) transforming the plasmid into a polA strain where it cannot replicate autonomously, (iii) selecting by ampicillin resistance the rare cell in which the plasmid had recombined into the chromosome, and (iv) mapping the chromosomal site of drug resistance (and thus plasmid integration) by Hfr matings and P1 transduction. The map position was confirmed by an assay of the enzyme content of cells bearing an F' factor which covered that region of the chromosome.

Demonstration by a novel genetic technique that leader peptidase is an essential enzyme of Escherichia coli

It was previously shown that two separate regions of DNA are required for expression of the cloned leader peptidase gene on plasmid pTD101 (T. Date and W. Wickner, Proc. Natl. Acad. Sci. U.S.A. 78:6106-6110, 1981). Both loci have been mapped in detail, and their roles have been established. A 1.3-kilobase region, termed the L region, encodes the 37,000-dalton leader peptidase protein. Another region, termed the P region, is about 1.5 kilobases away from the L region and is less than 350 base pairs long. The P region acts in cis to the L region, suggesting that it plays a role as a promoter. A technique for inactivation of the leader peptidase gene on the Escherichia coli chromosome has been developed to examine whether the leader peptidase which we had cloned is essential for cell growth. A specific plasmid (P(-) L(-)) which deletes both the P region and a substantial portion of the L region was constructed and transformed into a polA mutant strain. The plasmid cannot replicate in this strain; thus, the plasmid-borne ampicillin resistance is lost unless the plasmid DNA recombines into the chromosome. Integration of the P(-) L(-) plasmid did not yield any viable ampicillin-resistant cells, whereas the three control plasmids, P(+) L(+), P(+) L(-), and P(-) L(+), did. When the P(-) L(-) plasmid was transformed into the polA(Ts) strain, the strain could only grow in the presence of ampicillin at a permissive temperature, suggesting that integration of the plasmid into the host chromosome leads to inactivation of the chromosomal leader peptidase gene. Southern hybridization analysis demonstrated that the integration of plasmids into the chromosome occurred at the homologous site. This study demonstrates that expression of the leader peptidase gene is critical for cell growth.

DNA fusion product of phage P2 with plasmid pBR322: a new phasmid

The chromosome of the temperate bacteriophage P2 and that of the plasmid pBR322 have been joined in vitro after treatment with restriction endonuclease EcoRI. The fusion product - a phasmid - can behave as a plasmid, as a phage and as a prophage. It can replicate its DNA under the control of either the specific replication mechanism of the parent phage in a polA mutant or that of the parent plasmid in a rep mutant. Several interesting interactions between the two replication modes are indicated. In particular, phage particles may be produced even when the phage mode of DNA replication is blocked, and this throws new light on the involvement of the early gene A in the regulation of late gene expression in phage P2.

Use of deletions created in vitro to map transcriptional regulatory signals in the malA region of Escherichia coli

The malA region of Escherichia coli contains one of the three maltose operons, namely malPQ, and the positive regulatory gene, malT. Gene malT and the malPQ operon are transcribed in opposite directions, in a divergent manner. The distance separating the transcription start-points in the two directions was previously shown to be 513 base-pairs. We are now presenting a deletion analysis of this unexpectedly long intergenic region. Two sets of deletions were created in vitro, by using exonuclease BAL31. One set comprised deletions centered on a HincII restriction site located in the malPQ promoter, and extending towards gene malT. The other set was centered on an EcoRI site, which had been introduced close to the beginning of the malT cistron, and extended towards gene malP. These deletions, initially created on plasmids, were transferred onto the bacterial chromosome. By studying the phenotype resulting from the presence of these deletions, we concluded that: (1) all of the DNA sequences required for expression of malT and malPQ are within 100 base-pairs of the respective transcription start-points for these genes; (2) a sequence located more than 120 base-pairs upstream from the malT transcription start-point plays a role in limiting malT expression; and (3) a remaining DNA segment, 150 to 300 base-pairs in length, and centrally located in the inter-promoter region, seems to play no role in the expression of malT or malPQ.

Copy number mutations (Cop-) of the plasmid containing the replication origin (oriC) of the Escherichia coli chromosome: lethal effect of the cop region cloned onto a high-copy-number vector on host cells

High-copy-number mutants were isolated from an oriC plasmid. They carried insertion mutations within a region (about 470 base pairs) near the uncB gene. When a segment containing this region was cloned onto a high-copy-number plasmid, such a plasmid could be maintained as an intact form only when it was present in a lower copy number.

Incompatibility of plasmids containing the replication origin of the Escherichia coli chromosome

Plasmids containing the replication origin of the Escherichia coli chromosome (oriC plasmids) are unstable in certain recA strains of E. coli. However, they can be maintained more stably in other recA strains. This stable maintenance has allowed us to study the incompatibility properties of oriC plasmids. We have found that two oriC plasmids are incompatible: they cannot be stably coinherited in individual dividing cells. An oriC plasmid is excluded from growing bacteria at a much faster rate in the presence of a hybrid plasmid made from an oriC plasmid and a high-copy-number vector plasmid than in the presence of another oriC plasmid. By inserting various segments around the oriC region into high-copy-number vectors, we have shown that two different regions in the vicinity of the oriC region determine incompatibility. One region, which we named incA, includes the region essential for autonomous replication of the oriC plasmid. The other, incB, is adjacent to incA but is not required for autonomous replication.

Plasmid ColE1 incompatibility determined by interaction of RNA I with primer transcript

Mutants of plasmid pNT7 that can coexist with plasmid pMB9 in growing bacteria have been isolated. These mutants show altered incompatibility properties and increased copy numbers. Each mutant has a single base change at or near the center of one of the three palindromes in the region that specifies two RNA species: a larger one (primer transcripts) that provides a primer for DNA replication and a smaller one (RNA I) that is the incompatibility-specific inhibitor of primer formation. In vitro transcription studies show that the single base changes affect both the ability of RNA I to inhibit primer formation and the sensitivity of primer formation to inhibition by RNA I. RNA I hybridizes to the primer transcript, and the rate of hybridization is reduced by the single base changes. Based on analyses of inhibition of in vitro primer formation by RNA I and of in vivo properties of the mutant plasmids, we conclude that incompatibility between two plasmids can be attributed to inhibition of primer formation on one of the plasmids by the RNA I of the other. Inhibition of primer formation by RNA I appears to be the mechanism that determines the copy number of pNT7 and its derivatives.