Enzymatic production of deoxyribonucleic acid double-strand breaks after ultraviolet irradiation of Escherichia coli K-12.
(49/1371)
We have observed the enzymatic production of deoxyribonucleic acid (DNA) doublestrand breaks in Escherichia coli K12 after ultraviolet irradiation. Doublestrand breaks appeared in wild-type, polA1, recB21, recA, and exrA strains after incubation in minimal medium. THE UVRA6 strain showed no evidence of double-strand breakage under the same conditions. Our data suggest that uvr+ cells, which are proficient in the incision step of excision repair, accumulate double-strand breaks in their DNA as a result of the excision repair process, i.e., arising from closely matched incisions, excision gaps, or incisions and gaps on opposite strands of the DNA twin helix. Furthermore, strains deficient in excision repair subsequent to the incision step (i.e., polA, rec, exrA) showed more double-strand breaks than the wild type strain. The results raise the possibility that a significant fraction of the lethal events in ultraviolet-irradiated, repair-proficient (uvr+) cell may be enzymatically-induced DNA double-strand breaks. (+info)
Genetic and phenotypic characterization of dnaC mutations.
(50/1371)
The dna-1, dna-2, dna-7, and dna-28 mutations, all of which are located near min 89.5 on the E. coli linkage map, have been characterized further. As previously demonstrated for dna-2 and dna-28, neither the dna-1 nor dna-7 mutation affects the ability of a strain to produce bacteriophage lambda at temperatures non-permissive for the continued replication of the bacterial chromosome. The reported temperature-sensitive inhibition of lambda production in a strain carrying dna-7 is shown to be a consequence of a thermosensitive host specificity mutation in the hsm gene and not of the dna-7 mutation. The four dna mutations are recessive to the wild type and define a single dnaC cistron according to standard complementation criteria. Unlike other characterized dnaC mutants, however, strains carrying the dnaC1 or dnaC7 alleles exhibit an abrupt cessation of deoxyribonucleic acid synthesis at 42 C that appears to be more compatible with a defect in deoxyribonucleic acid chain elongation rather than in initiation. The possibility that the apparent elongation defect is actually a composite effect of residual synthesis and deoxyribonucleic acid degradation is raised by the net deoxyribonucleic acid degradation observed in the dnaC1 strain at 42 C. Several alternative possibilities for the function of the dnaC gene product are suggested. (+info)
Canavanine-mediated depletion of polyamine pools in Escherichia coli: effect of head morphogenesis and DNA synthesis.
(51/1371)
We have found that L-canavanine inhibited the synthesis of polyamines in T4-infected Escherichia coli. These polyamines are known to be required for T4 DNA synthesis and may be involved in phage morphogenesis. The new data indicate that the inhibition of polyamine synthesis is not primarily responsible for the L-conavanine-mediated inhibition of DNA synthesis nor does it seem to be involved in the induction of lollipops. L-Canavanine does influence the relative amounts of putrescine and spermidine found in the phage particle, but it does not influence the amount of DNA phosphate neutralized by polyamines. (+info)
Growth of a capsid mutant of bacteriophage phi X174 in a temperature-sensitive strain of Escherichia coli.
(52/1371)
A capsid mutant of phiX174 is capable of forming replicative form and synthesizing single strands at the restrictive temperature in a dnaB mutant of Escherichia coli. Under similar conditions, the wild-type bacteriophage is incapable of either step in viral synthesis. (+info)
Genetic basis of toxin production and pathogenesis in Vibrio cholerae: evidence against phage conversion.
(53/1371)
The pathogenicity of Vibrio cholerae strains "cured" of "Kappa-type" phage was not significantly altered relative to that of their "Kappa" lysogenic parental strains. Unlike Corynebacterium diphtheriae, the capacity of V. cholerae to produce exotoxin was not stimulated as a consequence of active phage multiplication. Toxin production in cultures in which Kappa-type phage multiplication was initiated either by inducing Kappa lysogens or by infecting naturally occurring or "cured" Kappa-sensitive strains was greatly reduced compared to normally growing control cultures. Kappa-sensitive El Tor strain Mak 757 and a Kappa lysogen derived from it did not differ in their capacity to colonize ligated rabbit ileal loops nor in their sensitivites to ultraviolet radiation, acidic pH, or osmotic shock. We conclude that Kappa-type phages do not directly affect the pathogenicity of these V. cholerae strains. (+info)
Detection of nonintegrated plasmid deoxyribonucleic acid in the folded chromosome of Escherichia coli: physiochemical approach to studying the unit of segregation.
(54/1371)
Physiocochemical evidence presented indicates plasmid deoxyribonucleic acid (DNA) can associate with host chromosome without linear insertion of the former into the latter. This conclusion is based on the observation that covalently closed circular (CCC) plasmid DNA can cosediment with undegraded host chromosome in a neutral sucrose gradient. When F plus bacteria are lysed under conditions that preserve chromosome, approximately 90% of CCC F sex factor plasmid (about 1% of the total DNA) is found in folded chromosomes sedimenting at rates between 1,500 and 4,000s. The remaining 10% of the CCC F DNA sediments at the rate (80S) indicative of the free CCC plasmid form. Reconstruction experiments in which 80S, CCC F DNA is added to F plus or F minus bacteria before cell lysis show that exogenous F DNA does not associate with folded chromosomes. In F plus bacteria, F plasmid is harbored at a level of one or two copies per chromosomal equivalent. In bacteria producing colicin E1, the genetic determinant of this colicin, the Col E1 plasmid, is harbored at levels of 10 to 13 copies per chromosomal equivalent; yet, greater than 90% of these plasmids do not cosediment with the 1,800S species of folded chromosome. However, preliminary evidence suggests one or two Col E1 plasmids may associate with the 1,800S folded chromosome. Based on evidence presented in this and other papers, we postulate F plasmid can link to folded chromosome because the physicochemical structure of the plasmid resembles a supercoiled region of the chromosome and, therefore, is able to interact with the ribonucleic acid that stabilizes the folded chromosome structure. Implications of this model for F plasmid replication and segregation are discussed. (+info)
Polynucleotide sequence relationships among Ent plasmids and the relationship between Ent and other plasmids.
(55/1371)
Deoxyribonucleic acid-deoxyribonucleic acid hybridization studies reveal that the plasmids coding for the production of heat stable and heat labile enteroxtoxins of Escherichia coli, regardless of their origin, have a majority of their polynucleotide sequences in common, but are not related in any significant way to those plasmids coding for the synthesis of only ST toxin. The heat stable and heat labile plasmids also share a significant degree of their polynucleotide sequences with plasmids of the FI and FII incompatibility groups, but not with R factors belonging to the I, N, W, P, or X incompatibility groups. (+info)
Sedimentation analysis of deoxyribonucleic acid from thymine-starved Escherichia coli.
(56/1371)
During thymine starvation, strand breaks accumulate in the chromosomal deoxyribonucleic acid (DNA) of Escherichia coli. This effect occurs to a varying extent in different strains and is particularly enhanced in strains deficient in DNA polymerase I. The inhibition of ribonucleic acid or protein synthesis suppresses the accumulation of strand breaks. In a polA strain, rifampin is more effective than chloramphenicol or puromycin in suppressing strand break accumulation. To a certain extent the pehenomenon othymineless death correlates with the appearance of strand breaks. Although the killing can not be explained by the bulk of strand breaks, it is possible that some of them represent lethal events. On the basis of our observations we proposed the following model. (i) Transcription may be accompanied by single-strand breaks in DNA. (ii) DNA polymerase I is involved in the efficient repair of these breaks. (iii) Thymine deprivation results in the accumulation of unrepaired breaks. (iv) Polymerase I-mediated repair is less affected by thymine deprivation than are the alternative pathways because it closes the breaks with short patches, requiring less thymine. (+info)