Cloning the origin of transfer region of the resistance plasmid R1

The insertion of a 7.7-kb EcoRI fragment of the resistance plasmid R1 into pBR325 yielded a plasmid which is mobilizable by pDB12, a multicopy derivative of R1drd-19 lacking most of the resistance determinants. The vector alone was not mobilizable in this system. From this observation we conclude that we have cloned the origin of transfer (oriT) of R1. After inserting a 5.3-kb PvuII-EcoRI fragment of the 7.7-kb region into pUC9 the DNA was cleaved randomly with DNaseI and BamHI linkers were attached to the ends. A subsequent BamHI digestion and electrophoretic separation of the resulting DNA molecules by their size allowed us to generate an ordered series of stepwise shortened plasmids. Plasmids with a deletion of approximately 3400 bp could no longer be mobilized. Since the next larger plasmid with 284 additional base pairs could be mobilized, we are able to confine the oriT location within this extra nucleotide stretch. The DNA sequence of this region was determined. Dominant features within the DNA region are a high AT content and five inverted repeats, which might function as recognition or substrate sites for proteins of the conjugational transfer system.     

Isolation of the kanamycin resistance region (Tn2350) of plasmid R1drd-19 as an autonomous replicon.

We have isolated a circular form of Tn2350, an IS1-flanked kanamycin resistance transposon forming part of the plasmid R1drd-19. This circle (pTn2350::9.6 kilobases) contains a single IS1 element and probably arises by recombination between the two directly repeated Is1 sequences of Tn2350. It can be used to transform Escherichia coli to kanamycin resistance. It is capable of autonomous replication but is not maintained stably in dividing cells and segregates under nonselective conditions. Cloning of a segment of pTn2350 on a conditional plasmid vector allowed us to assign the replication functions of this plasmid to a 1.6-kilobase restriction fragment. The plasmid R1drd-19 can thus be considered as a cointegrate between two replicons separated by IS1 sequences.     

Removal of symmetrical sequences from the origin region of plasmid R1 reduces its replication efficiency

The R1 origin region contains many symmetrical DNA sequence elements which allow the formation of complex secondary structures. A 218-bp in vivo deletion in a cloned R1 origin fragment removes most of them. As this deletion was never observed in plasmids containing all R1 replication functions, it was introduced by BglI in vitro recombination into the `basic replicon' of R1 cloned into pBR322. The recombinant plasmid with the 218-bp deletion and its derivatives unambiguously show that the deleted symmetrical elements are not absolutely essential for R1 replication as was previously assumed though they seem to determine a more efficient origin function. Likewise, a hypothetical protein of a mol. wt. of 14 000 daltons, the major part of which would be encoded by the deleted sequences, does not seem to be of particular importance for R1-specific replication. This is the first report of an alteration in the origin region of an IncFII plasmid which affects plasmid replication without abolishing it completely.     

Separation of the minimal replication region of the F plasmid into a replication origin segment and a trans-acting segment

Summary An analysis was carried out on the replication functions within a 2.3 kilobase (kb) segment of the F plasmid which contains an origin (ori S) of replication and is capable of autonomous replication inEscherichia coli. Two separable regions were delineated for this segment: an origin region of approximately 1,140 bp in length and a segment of approximately 1,400 bp that functionsin trans to support replication of the origin region. The trans-acting segment is functional as part of an F replicon or when inserted into theE. coli chromosome. A prominent feature of the trans-acting segment is a coding sequence for a 29 K protein (Murotsu et al. 1981).     

Cloning and expression of Clostridium pasteurianum galactokinase gene in Escherichia coli K-12 and nucleotide sequence analysis of a region affecting the amount of the enzyme

The Clostridium pasteurianum galactokinase gene was cloned by complementation, of the galK locus, into Escherichia coli. Restriction enzyme analysis subcloning and Tn5 mutagenesis indicated that the gene was located on a 1.8 X 10(3) base-pair ClaI-Sau3A fragment that encoded a polypeptide of approximately 40 Mr. Although the C. pasteurianum and the E. coli galactokinases have similar subunit molecular weights, Southern hybridization analysis indicated no strong homology between their genes. Even though this clone showed a low level of galactokinase expression, the Gal+ phenotype, provided by the clostridial galactokinase, was unstable in E. coli, and the gene was frequently inactivated by the spontaneous acquisition of insertion sequences. A second clone containing this gene on a large restriction fragment was isolated by hybridization. This clone was unable to grow on galactose-containing media due to the overproduction of galactokinase. Comparison of the plasmids from these two clones revealed that the second contained an additional 300 base-pairs located at one end of the galactokinase gene. Appropriate operon fusions with a promoter-less E. coli galactokinase gene indicated that these additional 300 base-pairs had promoter activity in E. coli. The DNA sequence of this region which lies upstream of the C. pasteurianum galactokinase gene was determined and compared with that from several clones producing high, low or undetectable amounts of galactokinase. The reasons for the high and low level expression and for the instability of the C. pasteurianum galactokinase in E. coli are discussed. The presence of the galactokinase suggests that galactose is used in C. pasteurianum through the Leloir pathway via galactose 1-phosphate.     

The nucleotide sequence of the replication control region of the resistance plasmid R1drd-19

Summary The region of plasmid R1 containing the replication control genes has been sequenced using the Maxam-Gilbert method. The nucleotide sequence of two small PstI restriction fragments (a total of about 1,000 base pairs) was determined for the wildtype R1 plasmid as well as for two different copy mutants. It was found that one copy mutant has a single base substitution in the fragment which was recently shown to harbor an important inc/cop gene (Molin and Nordström 1980). Furthermore, the sequence indicates the presence of a structural gene that codes for a polypeptide of size 10,500 daltons. Possible gene products predicted from the nucleotide sequences and their role in replication control are discussed.     

Direct repetition of a 1.2 Md DNA sequence is involved in site-specific recombination by the P1 plasmid R68

R68.45, a mutant R68 plasmid, carries a 1.5 Md DNA insertion near its kanamycin-resistance region. This DNA consists of a 1.2 Md DNA repetition of neighbouring R68-DNA and a 0.3 Md “foreign” DNA fragment that is flanked by this direct DNA repeat. This fragment seems to be involved in the formation of R'68.45 plasmids. Duplication of the 1.2 Md DNA sequence is also involved in site-specific recombination events of RP4. This 1.2 Md DNA fragment has the properties of an IS sequence and is denoted IS8.     

Isolation of the origin of replication of the IncW-group plasmid pSa

The origin of replication of the IncW plasmid pSa has been cloned and the function of this origin in Escherichia coli examined. A 1.9-kb region of DNA is required for efficient autonomous replication, and a 0.47-kb fragment within this region can initiate replication only in the presence of an autonomously replicating derivative of pSa. An Mr 35,000 protein (repA) is encoded adjacent to the origin and is required for efficient initiation of replication. The derivatives examined provide information suggesting a direct role of partition factors in plasmid replication and incompatibility.     

A DNA replication origin and a replication fork barrier used in vivo in the circular plasmid pKD1

As in other yeasts, ARS-containing plasmids can be maintained extrachromosomally in Kluyveromyces lactis. Although some fragments of K. lactis DNA have ARS activity in both K. lactis and Saccharomyces cerevisiae, it appears that the sequences required for ARS activity in the two yeasts are different. As an approach to a better understanding of ARS structure and function in K. lactis, we analyzed the replication of the circular plasmid pKD1. We identified a 159-bp sequence able to promote autonomous replication of pKD1 in both yeasts; this fragments contains both a sequence related to the S. cerevisiae ARS consensus sequence and a region of 53% identity to the 40-bp sequence essential for K. lactis KARS101 function. By the analysis of in vivo replication intermediates we provide the first direct evidence that DNA replication initiates at or near the K. lactis ARS element. Replication terminates at the cisacting stability locus of pKD1, which functions as a replication fork barrier (RFB) and is necessary for proper plasmid segregation. RFB activity requires the pKDI gene products that are important for plasmid segregation, suggesting a link between DNA replication termination and plasmid segregation in a eukaryotic organism.     

Role of the IS50 R proteins in the promotion and control of Tn5 transposition

IS50R, the inverted repeat sequence of Tn5 which is responsible for supplying functions that promote and control Tn5 transposition, encodes two polypeptides that differ at their N terminus. Frameshift, in-frame deletion, nonsense, and missense mutations within the N terminus of protein 1 (which is not present in protein 2) were isolated and characterized. The properties of these mutations demonstrate that protein 1 is absolutely required for Tn5 transposition. None of these mutations affected the inhibitory activity of IS50, confirming that protein 2 is sufficient to mediate inhibition of Tn5 transposition. The effects on transposition of increasing the amount of protein 2 (the inhibitor) relative to protein 1 (the transposase) were also analyzed. Relatively large amounts of protein 2 were required to see a significant decrease in the transposition frequency of an element. In addition, varying the co-ordinate synthesis of the IS50 R proteins over a 30-fold range had little effect on the transposition frequency. These studies suggest that neither the wild-type synthesis rate of protein 2 relative to protein 1 nor the amount of synthesis of both IS50 R proteins is the only factor responsible for controlling the transposition frequency of a wild-type Tn5 element in Escherichia coli.     

The nucleotide sequence of a DNA fragment from the replication origin of the antibiotic resistance factor R1drd19

Summary The recombinant plasmid pRK101 contains a DNA fragment which carries the complete replication origin of the antibiotic resistance factor R1drd-19 inserted into the vector plasmid pBR322. In a spontaneously arising mutant of this plasmid (pRK 103) a deletion of about 215 base pairs (bp) has been detected by heteroduplex analysis and mapping with restriction endonucleases. Essential parts of the replication origin must be located in the deleted sequence. The deletion mutant pRK103, in contrast to its parent plasmid pRK101 is not replicated under the control of the R1 replicon, even when the R1 factor or copy mutants of it are present within the same cell. These latter plasmids can complement a plasmid-specific protein not coded by pRK101 but essential for R1-directed replication. The nucleotide sequence of a 252 bp HpaII fragment covering about 170–200 bp of the deletion was determined. This piece of DNA is rich in G and C and contains a series of small palindromes, symmetrically arranged repeated sequences and short selfcomplementary structures which may be of significance for the initiation of the DNA replication. The possibility that the sequenced DNA fragment comprises a major part of the replication origin of R1drd-19 is discussed.     

Site-specific recA-independent recombination (fusion) of pMB8-related replicons in Escherichia coli in the region of the replication origins

Escherichia coli recA+ and recA- cells were co-transformed with a mixture of pMB9 (Tcr) and pST8-26 (Apr, pBR325 derivative) plasmid DNAs followed by selection on plates containing both tetracycline and ampicillin. A set of stable Tcr Apr derivatives was isolated from these transformants. Many of the stable Tcr Apr segregants contained fused pMB9::pST8-26 plasmids with lengths that were about 0.8 kb longer than the sum of the lengths of the parental plasmids; one plasmid (pTF8) was about 1.5 kb shorter. The fusion was not stimulated by UV irradiation of co-transformants and occurred both in recA+ and recA- genetic backgrounds. Restriction analysis of the fused plasmids showed the two replicons were in the same relative orientation, and also indicated unique points of fusion in most cases (in 9 out of 10) which are localised within the 1.6-kb regions around the replication origins (RO). Because the fusion of plasmids of the type used in this study was not described before we have tentatively named it RO-fusion (Replication-Origin-fusion).     

Insertion of an R1 plasmid into the origin of replication of the E. coli chromosome: random timing of replication of the hybrid chromosome

A 16 bp BgI II fragment was deleted in vitro from the minimal origin of replication of the Escherichia coli chromosome, oriC, and was replaced by a 10 kb R1 miniplasmid, pKN1562, containing the basic R1 replicon and a kanamycin resistance gene. The deletion-insertion was transferred by homologous recombination into the chromosome of a dnaA(ts) strain. P1 transduction separated the origin "mutation" from the dnaA46 allele. Integration of mini-R1 into oriC was verified by Southern blotting and by analysis of the R1 incompatibility phenotype. It was possible to isolate normal R1 miniplasmids from the integrated R1. Chromosome replication was initiated at random times after a short delay. The constructed strains grew 20%-30% slower than the wild type and showed more heterogeneous cell sizes.     

A plasmid cloning system utilizing replication and packaging functions of the filamentous bacteriophage fd

DNA cloning vectors were developed which utilize the replication origin (ori) of bacteriophage fd for their propagation. These vectors depend on the expression of viral gene 2 that was inserted into phage lambda, which in turn was integrated into the host genome. The constitutive expression of gene 2 in the host cells is sufficient for the propagation of at least 100 pfd plasmids per cell. In addition to the fd ori, the pfd vectors carry various antibiotic-resistance genes and unique restriction sites. Some of these vectors have no homologies to commonly used pBR plasmids or to lambda DNA. The nucleotide sequence of the vectors can be deduced from published sequences. Large DNA inserts can be stably propagated in pfd vectors; these are more stable than similar DNA fragments cloned in intact genomes of filamentous bacteriophage. Inclusion of phage sequences required for efficient phage packaging and infection with a helper phage resulted in formation of phage particles containing single-stranded plasmid genomes. Growth at 42 degrees C without selective pressure results in loss of pfd plasmids.