Photoreactivation of cells and phages injuried by ultraviolet radiation in the ecological long-wave band]

Photoreactivation (PR) was measured after inactivation by far (254 nm), middle (300-315 nm) and near (315-400 nm) UV radiation of Paramecium caudatum and 8 strains of Escherichia coli differing in PR and dark repair capability. PR volume was high and practically the same after irradiation by far and middle UV, but PR was not observed in near UV-inactivated cells of all the strains. It is proposed that pyrimidine dimers are not significant in near UV lethal lesions in cells, as near UV-irradiated phages (T7 and lambdacI 857) are not photoreactivated in undamaged host bacterial cells.     

Role of the bacterial and phage recombination systems and of DNA replication in genetic recombination of UV-irradiated phage lambda

Summary In this paper are studied in E. coli K12 the influence of the bacterial Rec and phage Red recombination systems on the rescue of the O ⁺ gene from the prophage by a superinfecting O ^- phage, UV irradiated or not. In the absence of UV irradiation the Red system produces more recombinants that does the Rec system, and its action requires DNA replication. The presence of UV lesions in the DNA facilitates the action of the Rec system, which is more efficient in this instance than the Red system and can act in the absence of DNA replication. In all cases, there is a cooperation between the two generalized recombination systems.     

Discovery of phage determinants that confer sensitivity to bacterial immune systems

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Photoreactivation and dark repair of ultraviolet light-induced pyrimidine dimers in chloroplast DNA.

A UV-specific endonuclease was used to detect ultraviolet light-induced pyrimidine dimers in chloroplast DNA of Chlamydomonas reinhardi that was specifically labeled with tritiated thymidine. All of the dimers induced by 100 J/m2 of 254 nm light are removed by photoreaction. Wild-type cells exposed to 50 J/m2 of UF light removed over 80% of the dimers from chloroplast DNA after 24 h of incubation in growth medium in the dark. A UV- sensitive mutant, UVS1, defective in the excision of pyrimidine dimers from nuclear DNA is capable of removing pyrimidine dimers from chloroplast DNA nearly as well as wild-type, suggesting that nuclear and chloroplast DNA dark-repair systems are under separate genetic control.     

Kinetics of dark repair inhibition in ultraviolet damaged DNA by substituted quinolines

The effects of chloroquine on the kinetics of the dark repair process were investigated by employing a cellular system. Lineweaver-Burke plots and Dixon plots of chloroquine inhibition, respectively, showed that there was an increase in slope with increasing concentration of inhibitor which followed an enzyme-like pattern. These results are consistent with a model for excision-repair in which chloroquine may block the excision repair pathway.     

The role of DNA polymerase beta in determining sensitivity to ionizing radiation in human tumor cells

Lethal lesions after ionizing radiation are thought to be mainly unrepaired or misrepaired DNA double-strand breaks, ultimately leading to lethal chromosome aberrations. However, studies with radioprotectors and repair inhibitors indicate that single-strand breaks, damaged nucleotides or abasic sites can also influence cell survival. This paper reports on studies to further define the role of base damage and base excision repair on the radiosensitivity of human cells. We retrovirally transduced human tumor cells with a dominant negative form of DNA polymerase β, comprising the 14 kDa DNA-binding domain of DNA polymerase β but lacking polymerase function. Radiosensitization of two human carcinoma cell lines, A549 and SQD9, was observed, achieving dose enhancement factors of 1.5–1.7. Sensitization was dependent on expression level of the dominant negative and was seen in both single cell clones and in unselected virally transduced populations. Sensitization was not due to changes in cell cycle distribution. Little or no sensitization was seen in G₁-enriched populations, indicating cell cycle specificity for the observed sensitization. These results contrast with the lack of effect seen in DNA polymerase β knockout cells, suggesting that polDN also inhibits the long patch, DNA polymerase β-independent repair pathway. These data demonstrate an important role for BER in determining sensitivity to ionizing radiation and might help identify targets for radiosensitizing tumor cells.     

The wavelength dependence of some effects of ultraviolet radiation on in vitro DNA of phage alpha

The wavelength dependence of some of the effects of ultraviolet radiation on the physicochemical properties of DNA of phage α irradiated in vitro are discussed. An analytical ultracentrifuge and a spectrophotometer were used to study (a) the breaking of individual polynucleotide strands; (b) the local denaturation; (c) the presence of a fraction of molecules resistant to denaturation; and (d) the increase in the buoyant density of irradiated DNA. All the curves show a slight variation of the radiation efficiency in the range 2600-2800 A, and a well defined peak at λ = 2880 A.     

Role of the E. coli umuC gene product in the repair of single-stranded DNA phage

The umuC product of Escherichia coli has been suggested to have a central role in SOS induced error prone replication of DNA (Kato and Shinoura 1977). To investigate this possibility, we examined the effect of umuC mutations on error prone repair of single and double-stranded DNA phages. No Weigle reactivation of M13 phage was detected in a umuC mutant. Reactivation of lambda phage was reduced but still evident. However mutagenesis occurred in both cases. These results suggest that induced error prone replication of phage DNA can occur via umuC dependent (transdimer synthesis) and umuC independent mechanisms.     

Role of recombinational repair in sensitivity to an antitumour agent that inhibits bacteriophage T4 type II DNA topoisomerase

The bacteriophage T4-encoded type II DNA topoisomerase is the major target for the antitumour agent m-AMSA (4-(9-acridinylamino)methanesulphon-m-anisidide) in phage-infected bacterial cells. Inhibition of the purified enzyme by m-AMSA results in formation of a cleavage complex that contains the enzyme covalently attached to DNA on both sides of a double-strand break. In this article, we provide evidence that this cleavage complex is responsible for inhibition of phage growth and that recombinational repair can reduce sensitivity to the antitumour agent, presumably by eliminating the complex (or some derivative thereof). First, topoisomerase-deficient mutants were shown to be resistant to m-AMSA, indicating that m-AMSA inhibits growth by inducing the cleavage complex rather than by inhibiting enzyme activity. Second, mutations in several phage genes that encode recombination proteins (uvsX, uvsY, 46 and 59) increased the sensitivity of phage T4 to m-AMSA, strongly suggesting that recombination participates in the repair of topoisomerase-mediated damage. Third, m-AMSA stimulated recombination in phage-infected bacterial cells, as would be expected from the recombinational repair of DNA damage. Finally, m-AMSA induced the production of cleavage complexes involving the T4 topoisomerase within phage-infected cells.     

Inhibition of dark repair of ultraviolet damage in DNA by caffeine and 8-chlorocaffeine. Kinetics of inhibition

Summary The inhibition of dark repair by caffeine and 8-chlorocaffeine was investigated by a cellular enzyme kinetics system. The results suggest that the caffeine and 8-chlorocaffeine act by inhibiting the excision enzyme of the dark repair system.This work was supported by National Insitutes of Health Research Grant AI-05340, the University of Kansas Research Fund, and N.I.H. Training Grant 5 T1 GM-73.