Regulation of the L-arabinose operon in strains of Escherichia coli containing ColE1-ara hybrid plasmids.

Summary Hybrid plasmids were constructed from fragments of F'ara episomes formed by the restriction endonuclease EcoRI and a linear form of the plasmid ColE1 created by cleavage with EcoRI. Hybrid plasmids were constructed containing the entire ara region or the ara region with various parts deleted. E. coli K12 host strains were constructed which contained different deletions of the ara region. The hybrid plasmids were transferred to those strains whose ara deletion complemented that of the plasmid. The initial differential rates of synthesis of L-arabinose isomerase, the product of the araA gene, were determined for the Ara⁺, plasmid containing strains. These studies demonstrated that strains containing (araO1BA)718 produce elevated levels of araC protein, suggesting the araC promoter has been altered by this deletion. Evidence is also presented which suggests that araC protein activates the ara-BAD operon to higher levels when it is present in cis rather than trans. Amplification of the products of the cloned genes is observed when compared to haploid levels in some cases.     

The regulatory region of the L-arabinose operon: a physical, genetic and physiological study.

A fine-structure physical and genetic map was constructed of a 1000 base-pair region of the l-arabinose operon of Escherichia coli. This region consists of the ara regulatory sequences contained between the araC and araB genes and portions of these flanking genes. Point mutations, Mu phage insertions, and bacterial deletions as well as arabinose-induced and basal enzyme levels in the strains were used in constructing a genetic map of the region. These ordered positions were then located more accurately by mapping the point mutations against physically located endpoints of deletions isolated on the two non-defective transducing phage λparaB114 and λparaC116. Phage possessing deletions ending in the arabinose regulatory region were isolated from indicating-plates on which deletions removing none, part, or all of either the araC or araB genes carried on the phage could be distinguished. Phage stocks were enriched for such deletions prior to plating by treatment with chelating agents and heat (Parkinson &; Huskey, 1971). Deletions into the ara region on either phage shorten the ara DNA homology region formed from heteroduplexes between λparaB114 and λparaB116. Therefore the physical locations of these deletion endpoints were determined by electron microscopy of the appropriate heteroduplexes and/or by gel electrophoresis of the central duplex following S₁ nuclease digestion (Lis &; Schleif, 1975b). 18 of the 32 deletions isolated and mapped in this region were measured physically. The space between araC and araB, containing the regulatory elements of the operon, is estimated to be about 300 base-pairs.     

New Recombination Methods for Sinorhizobium meliloti Genetics

The availability of bacterial genome sequences has created a need for improved methods for sequence-based functional analysis to facilitate moving from annotated DNA sequence to genetic materials for analyzing the roles that postulated genes play in bacterial phenotypes. A powerful cloning method that uses lambda integrase recombination to clone and manipulate DNA sequences has been adapted for use with the gram-negative α-proteobacterium Sinorhizobium meliloti in two ways that increase the utility of the system. Adding plasmid oriT sequences to a set of vehicles allows the plasmids to be transferred to S. meliloti by conjugation and also allows cloned genes to be recombined from one plasmid to another in vivo by a pentaparental mating protocol, saving considerable time and expense. In addition, vehicles that contain yeast Flp recombinase target recombination sequences allow the construction of deletion mutations where the end points of the deletions are located at the ends of the cloned genes. Several deletions were constructed in a cluster of 60 genes on the symbiotic plasmid (pSymA) of S. meliloti, predicted to code for a denitrification pathway. The mutations do not affect the ability of the bacteria to form nitrogen-fixing nodules on Medicago sativa (alfalfa) roots.     

New recombination methods for Sinorhizobium meliloti genetics

The availability of bacterial genome sequences has created a need for improved methods for sequence-based functional analysis to facilitate moving from annotated DNA sequence to genetic materials for analyzing the roles that postulated genes play in bacterial phenotypes. A powerful cloning method that uses lambda integrase recombination to clone and manipulate DNA sequences has been adapted for use with the gram-negative alpha-proteobacterium Sinorhizobium meliloti in two ways that increase the utility of the system. Adding plasmid oriT sequences to a set of vehicles allows the plasmids to be transferred to S. meliloti by conjugation and also allows cloned genes to be recombined from one plasmid to another in vivo by a pentaparental mating protocol, saving considerable time and expense. In addition, vehicles that contain yeast Flp recombinase target recombination sequences allow the construction of deletion mutations where the end points of the deletions are located at the ends of the cloned genes. Several deletions were constructed in a cluster of 60 genes on the symbiotic plasmid (pSymA) of S. meliloti, predicted to code for a denitrification pathway. The mutations do not affect the ability of the bacteria to form nitrogen-fixing nodules on Medicago sativa (alfalfa) roots.     

The use of transposons to introduce well-defined deletions in plasmids: Possibilities for in vivo cloning

A method for obtaining well-defined deletions in an octopine Ti plasmid was developed. It was based on the assumption that deletions would occur between two directly repeated transposons, when both are temporarily present in one plasmid molecule. To obtain such a situation, recombination has been forced between Agrobacterium tumefaciens Ti plasmids, each carrying the transposon Tn1831 at a different position. In a number of cases, most probably when the transposons are directly repeated, deletion formation indeed occurred and at high frequency. Mutants were isolated carrying Ti plasmids with one copy of Tn1831, and the region of DNA, between the positions of the transposons in the original plasmid, deleted. Moreover, in the case that the segment of DNA, enclosed by the two transposons, harbors the requirements for autonomous replication of an R plasmid, it is shown that in vivo cloning of such a segment of the Ti plasmid on the R plasmid can be accomplished.     

Molecular mechanisms of deletion formation in Escherichia coli plasmids. I. Deletion formation mediated by long direct repeats.

Summary Derivatives of plasmid pBR327 with the tet gene interrupted by 165 pb or 401 by direct repeats were constructed. In cells harboring these plasmids, deletions which restored the wild-type tet gene gave rise to tetracycline-resistant colonies, thereby allowing a simple phenotypic test for deletion formation. The frequencies of deletions in these plasmids were measured in Escherichia coli strains proficient or deficient in general recombination. The structure of plasmid DNA isolated from tetracycline-resistant transformants was analyzed by agarose gel electrophoresis, restriction mapping and sequencing. The data presented here demonstrate that deletion formation is always associated with dimerization of plasmid DNA. Dimeric plasmids were of two types. Those which carried both a deletion and a compensating duplication were the major type in a Rec⁺ background and were rare in recA, recF, recJ and recO backgrounds. Dimers of the second type contained deletions, but no compensating duplications, and their formation was RecA-independent. The data presented demonstrate that deletion formation mediated by long direct repeats is mainly the result of unequal crossing-over between two plasmid molecules.     

Simple Method for Markerless Gene Deletion in Multidrug-Resistant Acinetobacter baumannii

The traditional markerless gene deletion technique based on overlap extension PCR has been used for generating gene deletions in multidrug-resistant Acinetobacter baumannii. However, the method is time-consuming because it requires restriction digestion of the PCR products in DNA cloning and the construction of new vectors containing a suitable antibiotic resistance cassette for the selection of A. baumannii merodiploids. Moreover, the availability of restriction sites and the selection of recombinant bacteria harboring the desired chimeric plasmid are limited, making the construction of a chimeric plasmid more difficult. We describe a rapid and easy cloning method for markerless gene deletion in A. baumannii, which has no limitation in the availability of restriction sites and allows for easy selection of the clones carrying the desired chimeric plasmid. Notably, it is not necessary to construct new vectors in our method. This method utilizes direct cloning of blunt-end DNA fragments, in which upstream and downstream regions of the target gene are fused with an antibiotic resistance cassette via overlap extension PCR and are inserted into a blunt-end suicide vector developed for blunt-end cloning. Importantly, the antibiotic resistance cassette is placed outside the downstream region in order to enable easy selection of the recombinants carrying the desired plasmid, to eliminate the antibiotic resistance cassette via homologous recombination, and to avoid the necessity of constructing new vectors. This strategy was successfully applied to functional analysis of the genes associated with iron acquisition by A. baumannii ATCC 19606 and to ompA gene deletion in other A. baumannii strains. Consequently, the proposed method is invaluable for markerless gene deletion in multidrug-resistant A. baumannii.     

Influence of non-homology between recombining DNA sequences on double-strand break repair in Saccharomyces cerevisiae

In this paper we study the influence of non-homology between plasmid and chromosomal DNA on the efficiency of recombinational repair of plasmid double-strand breaks and gaps in yeast. For this purpose we used different combinations of plasmids and yeast strains carrying various deletions within the yeast LYS2 gene. A 400 by deletion in plasmid DNA had no effect on recombinational plasmid repair. However, a 400 by deletion in chromosomal DNA dramatically reduced the efficiency of this repair mechanism, but recombinational repair of plasmids linearized by a double-strand break with cohesive ends still remained the dominant repair process. We have also studied the competition between recombination and ligation in the repair of linearized plasmids. Our experimental evidence suggests that recombinational repair is attempted but aborted if only one recombinogenic end with homology to chromosomal DNA is present in plasmid DNA. This situation results in a decreased probability of non-recombinational (i.e. ligation) repair of linearized plasmid DNA.     

Targeted deletions created in yeast vectors by recombinational excision

We have developed a simple method for creating defined deletions in yeast vectors by utilizing the ability of Saccharomyces cerevisiae to perform homologous recombination. Two complementary single-stranded oligonucleotides are designed so that the 5' and 3' halves of the resulting double-stranded oligonucleotide are homologous to the 5' and 3' side of a desired deletion junction, respectively. The sequence to be deleted is cleaved by restriction endonuclease digestion, followed by co-transformation of the linearized plasmid and the oligonucleotide into yeast. By homologous recombination in vivo, a subset of the plasmids will recircularize and simultaneously acquire the deletion as defined by the oligonucleotide.     

pIJ101, a multi-copy broad host-range Streptomyces plasmid: Functional analysis and development of DNA cloning vectors

Summary Streptomyces lividans ISP 5434 contains four small high copy number plasmids: pIJ101 (8.9 kb), pIJ102 (4.0 kb), pIJ103 (3.9 kb) and pIJ104 (4.9 kb). The three smaller species appear to be naturally occurring deletion variants of pIJ101. pIJ101 and its in vivo and in vitro derivatives were studied after transformation into S. lividans 66.pIJ101 was found to be self-transmissible by conjugation, to elicit lethal zygosis and to promote chromosomal recombination at high frequency in both S. lividans 66 and S. coelicolor A3(2). A restriction endonuclease cleavage map of pIJ101 was constructed for 11 endonucleases; sites for five others were lacking. Many variants of pIJ101 were constructed in vitro by inserting DNA fragments determining resistance to neomycin, thiostrepton or viomycin, and having BamHI termini, into MboI or BclI sites on the plasmid, sometimes with deletion of segments of plasmid DNA. The physical maps of these plasmids were related to their phenotypes in respect of lethal zygosis and transfer properties. In vivo recombination tests between pairs of variant plasmids were also done. These physical and genetic studies indicated that determinants of conjugal transfer occupy less than 2.1 kb of the plasmid. A second segment is required for spread of the plasmid within a plasmid-free culture to produce the normal lethal zygosis phenotype: insertion of foreign DNA in this region caused a marked reduction in the diameter of lethal zygosis zones. The minimum replicon was deduced to be 2.1 kb or less in size; adjacent to this region is a 0.5 kb segment which may be required for stable inheritance of the plasmid. The copy number of several derivatives of pIJ101 in S. lividans 66 was between 40 and 300 per chromosome and appeared to vary with the age or physiological state of the culture. pIJ101 derivatives have a wide host range within the genus Streptomyces: 13 out of 18 strains, of diverse species, were successfully transformed.Knowledge of dispensable DNA segments and the availability of restriction sites for the insertion of DNA, deduced from the properties of plasmids carrying the E. coli plasmid pACYC184 introduced at various sites, was used in the construction of several derivatives of pIJ101 suitable as DNA cloning vectors. These were mostly designed to be non-conjugative and to carry pairs of resistance genes for selection. They include a bifunctional shuttle vector for E. coli and Streptomyces; a Streptomyces viomycin resistance gene of this plasmid is expressed in both hosts.     

Deletion derivatives of pAgK84 and their use in the analysis of Agrobacterium plasmid functions

The 47.7-kb plasmid pAgK84, present in Agrobacterium radiobacter strain K84, confers production of a novel, highly specific, antiagrobacterial antibiotic called agrocin 84. Strain K84 is used commercially to biocontrol crown gall caused by agrocin 84-susceptible strains of Agrobacterium tumefaciens. Efficient biocontrol is dependent upon production of agrocin 84 by strain K84. Starting with a derivative of pAgK84 containing a Tn5 insertion, a series of deletion derivatives of the plasmid were isolated. The smallest of these, pJS500, contains about 8 kb of the original agrocin plasmid and localized the replication functions to between 4 and 6 o'clock on the physical map. A smaller derivative, produced by clonal rescue of a Tn5 insertion in the 4 o'clock region, further localized the minimal replication functions to a 1.5-kb region mapping between coordinates 18.1 and 19.6. Analysis of plasmid stability indicated that functions required for maintenance of the plasmid under nonselective conditions are tightly linked to the minimal replication region. This region also encodes incompatibility functions; the deletion derivatives were all incompatible with the wild-type pAgK84. The stability/replication locus of pAgK84 maps just anticlockwise from the Tra region. This region is retained fully in pAgK1026, the directed Tra⁻ derivative of pAgK84 which is now in use as the primary crown gall biocontrol agent in Australia. One of the deletion derivatives, the 15-kb pJS400, was used as a vector to clone the KpnI fragments of an octopine-type Ti plasmid. Traits known to be encoded on these fragments were expressed and properly regulated in Agrobacterium hosts. One clone, encoding the Ti plasmid replication/incompatibility region, was used to cure IncRh1 Ti plasmids from their hosts. This clone also was found to be incompatible with pAtK84b, a large plasmid encoding opine catabolism present in A. radiobacter strain K84. This indicates that the opine catabolic plasmid is closely related to the IncRh1 Ti plasmids.     

Mapping of RP4 plasmid using deletion mutants of pAS8 hybrid (RP4-ColE1)

Summary We used the hybrid plasmid pAS8 in order to conduct the genetic analysis of RP4 plasmid. The presence of two replicons in the hybrid plasmid permitted to expand the spectrum of deletion mutants of RP4 isolated, which are capable to autonomous replication. The shortening of the hybrid plasmid was achieved by P22 transduction, by induction of deletion mutants using mitomycin C, as well as by selection of Tra^- mutants on the basis of resistance of cells to P-specific phages. These techniques have lead to isolation of clones possessing different combinations of plasmid resistance determinants.Comparison of phenotypic characteristics of deletion plasmids pAS9, pAS10, pAS11, pAS12 and pAS10-2 permitted to propose the map for pAS8 plasmid with the following sequence of markers: trakan-ColE1-amp-tet...Heteroduplex analysis of deletion mutants of pAS8 permitted to construct a physical map and to elaborate in greater detail the functional map of RP4 plasmid. The correlation between the ability of mutants to replicate in polA (TS) strain at nonpermissive conditions and the length of the deleted segment permitted to map rep genes of RP4 on a region with coordinates 9.8–17.3 kb. A relationship between the manifestation of incompatibility of mutants with Inc P-1 plasmids and the length of deletions points out that inc genes are located on DNA region with coordinates 2.1–9.8 kb. The analysis of replication of deletion mutants and the manifestation of incompatibility just as of the data about the size of appropriate deletions permitted to make the conclusion about the functional and genetic independence of the replication control and incompatibility control in RP4 plasmid.     

Site specific recombination involved in the generation of small plasmids

Summary The physical structures of seven small plasmids, Rsc10, Rsc11, Rsc12, Rsc13, Rsc15, Rsc10-1 and pEM1 were analyzed. Molecular lengths of these plasmids were determined to range from 7.65 to 19.8 kilobases or kb. Electron microscope heteroduplex analysis of these plasmids show that the plasmids were all derived from pKN102 (86.3kb) in a complicated process that takes place by a series of deletion and, in some cases, transposition events. Rsc10 and Rsc11 were each formed by a simple deletion event from the parental plasmid. The physical structures of Rsc13 and pEM1 suggest that these plasmids must have been derived by a single and two successive deletion events from Rsc11. In the formation of these plasmids, all the deletions occured at the ends of the transposon, Tn3, which confers ampicillin resistance (amp) to the plasmid, or at the ends of the insertion sequence, IS1. Rsc15 was assumed to be formed in a two step process. The first step was a deletion event to form Rsc10-1 which occurs at one end of the IS1 present in pKN102. At first, the deletion event leaves out the ampicillin gene but in the second step Tn3 is transposed to the newly formed plasmid, Rsc10-1. Rsc12 is believed to have been formed in a similar fashion; first, a series of deletions and second, the transposition of Tn3.Studies on these small plasmids enabled us to also map the regions of the replication genes and ampicillin resistance on pKN102.     

In vivo transfer of chromosomal mutations onto multicopy plasmids utilizing polA strains: Cloning of an ompR 2 mutation in Escherichia coli K-12

Abstract We have devised a simple in vivo scheme for moving chromosomal mutations onto multicopy plasmids in Escherichia coli K-12. A plasmid clone of the relevant wild-type gene is first integrated into the chromosome of a PolA⁻ strain carrying the desired mutation. The plasmid cointegrate formed is then resolved by P1 transduction to a PolA⁺ host. A certain fraction of these transductants will have the mutant allele on the plasmid. Employing this scheme we cloned an ompR 2 mutation onto a multicopy plasmid. To show that the plasmid actually contained the ompR 2 mutation, this allele was introduced back into the chromosome by the gene replacement technique of Gutterson and Koshland [1] and shown to be indistinguishable from the original ompR 2 by genetic mapping and phenotype.     

The araC regulatory gene mRNA contains a leader sequence

Summary An estimation of the size of the araC gene in Escherichia coli B/r was made by sub-cloning restriction fragments of the araC-containing hybrid plasmid pTB1 into the plasmid pBR322. Plasmids which contained a functional araC gene were identified by genetic complementation tests. DNA sequence analysis of the promoter-proximal region of the araC gene revealed that araC mRNA contains a 150 nucleotide leader.     

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.     

In vitro construction of plasmids which result in overproduction of the protein product of the araC gene of Escherichia coli.

Summary Derivatives of the Escherichia coli drug resistance plasmid pMB-9 were constructed which contain the promotor from the lactose operon of E. coli fused to the araC gene of E. coli. E. coli possessing these plasmids contain about 50 times as much of the araC gene product as do cells with a wild-type araC gene and promotor.     

Roles of double-strand breaks, nicks, and gaps in stimulating deletions of CTG.CAG repeats by intramolecular DNA repair

A series of plasmids harboring CTG.CAG repeats with double-strand breaks (DSB), single-strand nicks, or single-strand gaps (15 or 30 nucleotides) within the repeat regions were used to determine their capacity to induce genetic instabilities. These plasmids were introduced into Escherichia coli in the presence of a second plasmid containing a sequence that could support homologous recombination repair between the two plasmids. The transfer of a point mutation from the second to the first plasmid was used to monitor homologous recombination (gene conversion). Only DSBs increased the overall genetic instability. This instability took place by intramolecular repair, which was not dependent on RuvA. Double-strand break-induced instabilities were partially stabilized by a mutation in recF. Gaps of 30 nt formed a distinct 30 nt deletion product, whereas single strand nicks and gaps of 15 nt did not induce expansions or deletions. Formation of this deletion product required the CTG.CAG repeats to be present in the single-stranded region and was stimulated by E.coli DNA ligase, but was not dependent upon the RecFOR pathway. Models are presented to explain the intramolecular repair-induced instabilities and the formation of the 30 nt deletion product.