Preparation of covalently closed and open circular DNA molecules of phage lambda

DNA polymerase I and recBC enzyme support the covalent closing of hydrogen-bonded lambda DNA circles in extracts of Escherichia coli cells

The covalent closing of hydrogen-bonded lambda DNA circles in Escherichia coli extract was observed to require DNA polymerase I, recBC enzyme and ATP. This covalent closing activity was lost in strains harbouring a mutation in one of the genes responsible for production of the enzymes mentioned above, and was recovered by combining these mutant extracts. ATP could be replaced with dATP, but not appreciably with any of the other nucleoside triphosphates. High concentrations of ATP inhibited the closure. K+ or NH4+ (0.2M) was required for optimal activity and NMN was a strong inhibitor.

Intramolecular transposition and inversion in plasmid R6K

Selection was made in Escherichia coli K-12 recA hosts carrying plasmid R6K for ampicillin hyperresistance. Twenty-two selected strains were found to carry mutant plasmids, which, from electron microscopy and restriction enzyme analysis, were concluded to arise by a duplication of transposon Tn2660, which confers ampicillin resistance, in all cases the duplicate transposon being in an inverted orientation with respect to the resident Tn2660. A mutant of R6K, pSJC301, which was temperature sensitive for ampicillin resistance was produced by in vitro hydroxylamine treatment of R6K deoxyribonucleic acid. A plasmid hybrid, pSJC102, was constructed by cloning the EcoRI R6K fragment carrying the wild-type beta-lactamase gene into the EcoRI site of ColE1. pSJC301 and pSJC102 were transformed into the same recA host strain to form a stable biplasmid strain. Ampicillin-hyperresistant mutants were selected from this strain and screened for plasmids with a duplication of transposon Tn2660, which occurred with equal frequency in either pSJC301 or pSJC102; of 12 characterized, all were inverse repeats of the resident transposon. All six Tn2660 inserts into pSJC301 determined temperature-sensitive ampicillin resistance, and all six inserts into pSJC102 determined wild-type ampicillin resistance, from which it was inferred that transposition of a duplicate Tn2660 occurs predominantly as an intramolecular event, at least in the multicopy R6K plasmid. In all 28 insertion mutants of R6K, there was an inversion of the deoxyribonucleic acid between the two transposons, whereas in only one of six insertion mutants of pSJC102, inversion had occurred. These results are discussed in terms of current models of transposition.

Physical characterization of plasmids determining synthesis of a microcin which inhibits methionine synthesis in Escherichia coli

Plasmid deoxyribonucleic acid (DNA) isolated from each of three antibiotic-resistant clinical strains of Escherichia coli producing the same microcin showed multiple bands upon agarose gel electrophoresis. Transformants selected either for microcin resistance or ampicillin resistance yielded plasmid DNA corresponding in size to only one of the multiple bands. Plasmids, isolated from all three hosts, which determined microcin resistance and microcin production measured about 4 megadaltons by sucrose density, restriction enzyme, and contour length analyses; cleavage of the DNAs by each of eight restriction enzymes showed the same response, and DNA-DNA hybridization indicated complete homology. The antibiotic resistance plasmids of the three host strains were uniformly larger, were of different sizes, and showed different restriction enzyme cleavage patterns. One of these R plasmids (pCP106) also determined the synthesis of the same microcin, and DNA-DNA hybridization studies indicated an approximate 2.4-megadalton homology with the 4-megadalton microcin plasmid pCP101. The microcin plasmids were present at approximately 20 copies per genome equivalent and were nonconjugative, whereas the R plasmids had a copy number of about 1, were conjugative, and could mobilize the microcin plasmid. Microcin plasmid pCP101 showed replication properties similar to those of a number of small multicopy plasmids such as ColE1.

Map location of the Escherichia coli origin of replication

Working with restriction fragments obtained directly from the Escherichia coli K12 chromosome, the EcoRI-HindIII restriction map of the section of the chromosome containing the replication origin has been extended by 14 kilobase pairs (kb) to cover 56 kb. Within this newly mapped portion, the ilv and rrnC cistrons have been identified by (1) hybridization of individual restriction fragmanents to the ilv-transducing phage lambdadilv5 and (2) a comparison of the restriction map of this region with the EcoRI map of lambda dilv5 and the Hind III map of the plasmid pJC110, a ColEl-ilv hybrid. The replication origin is located approximately 30 kb from the ilvE gene and 20 kb from the rrnC 16S rRNA cistron. This places the origin near 82.7 min on the genetic map, close to uncA.

Transfer-deficient mutants of the narrow-host-range plasmid R91-5 of Pseudomonas aeruginosa

Three methods have been successful in the isolation of transfer-deficient mutants of the narrow-host-range R plasmid R91-5 of Pseudomonas aeruginosa: (i) selection for donor-specific phage resistance; (ii) direct screening after mutagenic treatment with either ethyl methane sulfonate or N-methyl-N'-nitro-N-nitrosoguanidine; (iii) in vitro mutagenesis of plasmid DNA by hydroxylamine followed by transformation and direct screening. The majority of transfer-deficient mutants were donor-specific phage resistant, supporting the view that sex pili and other surface components are essential for conjugal transfer (since the phages PRD1 and PR4 adsorb to these sites). Some of the transfer-deficient mutants were also unable to inhibit the replication of phage G101 or lost entry exclusion or both phenotypes. The ability to revert these pleiotropic mutants to wild type implicates the latter two functions in R91-5 transfer. Suppressor mutations in P. aeruginosa enabled the detection of suppressor-sensitive, transfer-deficient mutants. Such mutants should prove useful in conjugational complementation tests for the identification of the transfer cistrons of R91-5.