Repair of Ultraviolet Radiation Damage in Sensitive Mutants of Micrococcus radiodurans

Various aspects of the repair of ultraviolet (UV) radiation-induced damage were compared in wild-type Micrococcus radiodurans and two UV-sensitive mutants. Unlike the wild type, the mutants are more sensitive to radiation at 265 nm than at 280 nm. The delay in deoxyribonucleic acid (DNA) synthesis following exposure to UV is about seven times as long in the mutants as in the wild type. All three strains excise UV-induced pyrimidine dimers from their DNA, although the rate at which cytosine-thymine dimers are excised is slower in the mutants. The three strains also mend the single-strand breaks that appear in the irradiated DNA as a result of dimer excision, although the process is less efficient in the mutants. It is suggested that the increased sensitivity of the mutants to UV radiation may be caused by a partial defect in the second step of dimer excision.     

The properties of UV sensitive mutants of Escherichia coli K12 which are also refractory to colicin E2

Summary Among mutants refractory to colicin E2 at low temperatures but sensitive at high temperatures (designated Ref-II), three strains are described which are also UV sensitive. Although colicin refractivity is temperature dependent UV sensitivity is expressed at all temperatures. Although the UV sensitive lesion appears to be similar in its effects to that in Rec (recombinationless) strains, mutants specifically isolated as Rec strains are in fact more sensitive to E2 than are wild type strains. It is suggested that E2 refractivity and UV sensitivity in the mutants probably reflects the phenotypic expression of distinct although linked genes. It is also suggested that the degradation of DNA stimulated by adsorption of E2 to wild type bacteria may be caused by the same enzyme(s) which causes enhanced breakdown of DNA in some rec ^– mutants after UV irradiation.     

Genetic effects of cosmic radiation in Drosophila melanogaster]

To examine possible effects of space radiation on living organism, we have analyzedtwo types of mutations, sex-linked recessive lethal mutations and somatic mutations, in fruit fly of the species Drosophila melanogaster. Drosophila strains used were wild type strains and a radiation-sensitive strain mei-41. Two different developmental stages of samples were sent into space; young adult males to analyze sex-linked recessive lethal mutations and about 30hr-old larvae to detect somatic mutations in wing epidermal cells. For wild type and mei-41 strains each, about 200 adult male flies and about 6,000 larvae were loaded on space shuttle Endeavour. The male flies returned from space were mated to virgin female flies of a tester strain, and the presence of the lethal mutations was analyzed at F2 generation. The frequencies of sex-linked recessive lethal mutations in flight groups were 2 and 3 times higher for wild type Canton-S and mei-4 1, respectively, than those in ground control groups. Most larvae sent to space emerged as adult flies within about 10 days after the landing. The presence of wing-hair somatic mutations, which give morphological change in hairs growing on the surface of wing epidermal cells, was analyzed under microscope. In wild type strain Muller-5, the frequency of wing hair mutant spots in flight group was about 1.5-fold higher than that in ground control, and in Canton-S-derived wild type strain the frequencies were similar between the two groups. By contrast, for mei-41 strain the mutation frequency was lower in flight group than in control group. The observed higher frequency of lethal mutations in the flight group might be due to a possibility that radiation effects on reproductive cells could be greatly enhanced under micro gravity. However, if this would be the case, we do not have appropriate explanation for the apparent absence of such synergistic effects on somatic wing-hair mutation system.     

Excision Repair of Uv Radiation-Induced DNA Damage in Caenorhabditis Elegans

Radioimmunoassays were used to monitor the removal of antibody-binding sites associated with the two major UV radiation-induced DNA photoproducts [cyclobutane dimers and (6-4) photoproducts]. Unlike with cultured human cells, where (6-4) photoproducts are removed more rapidly than cyclobutane dimers, the kinetics of repair were similar for both lesions. Repair capacity in wild type diminished throughout development. The radioimmunoassays were also employed to confirm the absence of photoreactivation in C. elegans. In addition, three radiation-sensitive mutants (rad-1, rad-2, rad-7) displayed normal repair capacities. An excision defect was much more pronounced in larvae than embryos in the fourth mutant tested (rad-3). This correlates with the hypersensitivity pattern of this mutant and suggests that DNA repair may be developmentally regulated in C. elegans. The mechanism of DNA repair in C. elegans as well as the relationship between the repair of specific photoproducts and UV radiation sensitivity during development are discussed.     

Genetic control of prophage induction in haemophilus influenzae after exposure to psoralen plus near-UV light.

Prophage S2 could be induced by psoralen plus near-UV light (PNUV) from a wild-type strain of Haemophilus influenzae, from UV light-sensitive strains uvr-1 and uvr-2 and PNUV-sensitive strains PSO1 amd PSO7, but not from a recombination-deficient strain, rec-1. The levels of prophage induction were comparable in the wild type and an ATP-dependent DNase-deficient strain, KW31, even though the PNUV-induced degradation in the latter strain was considerably lower. Prophage induction could be observed even with chloramphenicol present before, during, and 30 min after PNUV treatment.     

recA mutants of E. coli K12: A personal turning point

A first year graduate student, Ann Dee Margulies, changed my research career in 1962 by challenging me to direct her in the isolation of recombination-deficient mutants of Escherichia coli K-12. She succeeded in isolating two mutants, which conjugated with donor strains and received the donor DNA, but could not recombine that DNA with their own chromosomes. Ann Dee showed that both mutants were much more sensitive to UV radiation than was the wild type. Furthermore, she showed that one of these mutants carried a single mutation affecting both recombination and resistance. This work, published in 1965, was the first demonstration of the recA gene of E. coli. Subsequent work led to the discovery of many more recombination genes, the phenomenon of post replication-recombination repair, the invention of the SOS hypothesis and the discovery of genes encoding proteins with similar primary structure and function in all major groups of organisms. This article honors the memory of Ann Dee.     

Properties of the nonlethal recombinational repair x and y mutants of bacteriophage T4. II. DNA synthesis.

The bacteriophage T4 recombination-deficient mutants x and y exhibited decreased rates of DNA synthesis as compared to wild-type T4. Mutant-induced DNA synthesis was more sensitive to mitomycin C than was wild-type synthesis. However, DNA synthesis in mutant- and wild-type-infected cells exhibited the same sensitivity to UV light and X-irradiation. When high-specific-activity label was administered at various times postinfection, mutant DNA synthesis resembled that of wild type for 12 min. after which time mutant-induced incorporation was greatly decreased and sensitive to mitomycin C as compared to that of the wild type. Rifampin and chloramphenicol studies indicated that the gene products necessary for synthesis measured at 15 min postinfection, including those of x+ and y+ were transcribed within 2 min and translated within 8 min postinfection. Administration of chloramphenicol to mutant x- or mutant y-infected cells exactly 8 min postinfection, however, allowed for increased synthesis at 15 min that was sensitive to mitomycin C. Cells coinfected with T4+ and T4x or T4x and T4y retained a reduced mutant-type synthesis, whereas cells coinfected with T4+ and T4y exhibited a synthesis more closely resembling that of wild type.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. V. Biochemical characterization of a strain (ebony) that is UV- and X-ray sensitive and deficient in photorepair

We investigated larval sensitivity to UV and repair of UV- and X-ray-induced lesions in the DNA of the ebony strain compared to a wild-type strain (Canton S). The ebony strain was previously characterized as being more sensitive to UV-induced killing of embryos than Canton S. Also the ebony strain is more sensitive to X-rays for induction of larval killing, dominant lethals and recessive lethals. In this paper it is demonstrated that (1) ebony larvae are more sensitive to killing by UV and less proficient in photoreactivation (PR) ability than Canton S larvae; (2) the ebony strain has a defect in PR repair of endonuclease-sensitive sites induced in the DNA of primary cell cultures by UV irradiation; (3) the ebony strain has a defect in the repair of single-strand breaks induced in the DNA by X-rays (again in primary cell cultures), at least early on in the repair incubation. A rough localization of the UV sensitivity and the PR ability is presented and the possible relevance of the biochemical to the genetic results is discussed.     

Construction and analysis of a recombination-deficient (radA) mutant of Haloferax volcanii

By deleting the radA open reading frame of an extreme halophile, Haloferax volcanii , we created and characterized a recombination-deficient archaeon. This strain, Hf. volcanii DS52, has no detectable DNA recombination, is more sensitive to DNA damage by UV light and ethylmethane sulfonate, and has a slower growth rate than the wild type. These characteristics are similar to those observed in recombination mutants of Eukarya and Bacteria, and show that the radA gene belongs in the recA / RAD51 family by function as well as sequence homology. In addition, strain DS52 was not transformable by plasmids pWL102 or pUBP2 (which contain pHV2 and pHH1 replicons, respectively), although it was readily transformed by plasmids containing a pHK2 replicon, indicating a role for radA in the maintenance or replication of some halobacterial plasmids. Despite its slower growth rate, Hf. volcanii DS52 was still easy to culture and transform, and should be suitable for use in studies where a recombination-deficient background is desired.     

Isolation of the rec Mutants in Staphylococcus aureus

A histidine auxotroph (his-) of Staphylococcus aureus MS3937 and mutants sensitive to ultraviolet (UV) irradiation were obtained. The UV-sensitive mutants were found also to be sensitive to N-methyl-N'-nitro-N-nitrosoguanidine and mitomycin C, and their sensitivity was accounted for by a defect in deoxyribonucleic acid repair. Transduction of either chromosomal or plasmid markers to UV-sensitive mutants showed that these staphylococcus mutants are of the recA (reckless) type mutants as reported in Escherichia coli and Salmonella typhimurium; therefore the UV-sensitive mutants (uvr-) were renamed recombination-deficient mutants (rec-). The biochemical and genetic properties of these mutants are described, and their usefulness for studies of staphylococcal plasmids is discussed.     

Repair of Deoxyribonucleic Acid in Haemophilus influenzae I. X-Ray Sensitivity of Ultraviolet-sensitive Mutants and Their Behavior as Hosts to Ultraviolet-irradiated Bacteriophage and Transforming Deoxyribonucleic Acid

Seven mutants of Haemophilus influenzae were isolated by the criterion of sensitivity to ultraviolet (UV) inactivation of colony formation. These mutants and the wild type were characterized with regard to X-ray inactivation of colony formation, UV induction of division inhibition, the ability of the eight strains to act as recipients to UV-irradiated H. influenzae phage and transforming deoxyribonucleic acid (DNA), and the influence of acriflavine on the survival of UV-irradiated transforming DNA with these strains as recipients. The photoreactivable sector of transforming DNA with yeast photoreactivating enzyme was measured for the most UV-sensitive mutant and was found to be greater than that of wild type. Judged by the above criteria, the order of the strains' sensitivities shows some, but by no means complete, correlation from one type of sensitivity characterization to another, indicating that a minimum of two variables is needed to explain the differences in the strains. Acriflavine increases the UV sensitivity of transforming DNA except in the most sensitive mutant. This effect is usually, but not always, more pronounced in the case of the more UV-resistant marker. The acriflavine effect is postulated to be the result of at least two factors: (i) interference with repair of transforming DNA in the host cell, and (ii) interference with the probability of recombination between transforming DNA and host DNA.     

Somatic damage to the X chromosome of the nematode Caenorhabditis elegans induced by gamma radiation

Summary Wild-type male embryos and young larvae of the nematode Caenorhabditis elegans were more sensitive than wild-type hermaphrodites to inactivation by gamma rays; wild-type males have one X chromosome per cell (XO), whereas wild-type hermaphrodites have two (XX). Furthermore, after transformation into fertile hermaphrodites by a her-1 mutation, XO animals were more radiosensitive than XX her-1 animals; and XX animals transformed into fertile males by a tra-1 mutation did not show increased radiosensitivity. It is concluded that wild-type males are more radiosensitive than wild-type hermaphrodites because they have one X chromosome rather than two, and the predominant mode of inactivation of XO animals involves damage to the single X chromosome. No sex-specific differences in survival were observed after UV irradiation.     

The effect of radiation sensitivity and cell stage on liquid holding response in Schizosaccharomyces pombe

Summary The response of the wild type strain and 20 different radiation sensitive mutants of S. pombe to liquid holding after ultraviolet irradiation was ivestigated. Three of the sensitive mutants tested showed appreciable liquid holding recovery, as opposed to the negative liquid holding effect observed in the wild type cells. One of these mutants is reported to be recombination-deficient while the other two have a normal recombination capability. Further experiments were carried out by using G₁ cells and ascospores to test the possible role of a recombinational type of repair pathway in the failure of wild type S. pombe to show liquid holding recovery. Data from such studies indicated that the negative liquid holding effect observed in the wild type cannot be ascribed to this particular pathway. This conclusion is further supported by the observation that caffeine which is believed to inhibit mainly the recombinational repair in this yeast, did not alter the negative liquid holding effect in the wild type. This observation implies that the caffeine-sensitive repair process occurs only in a rich medium and not in the non-nutrient solution. Data have been discussed as these relate to possible cause(s) of negative liquid holding effect in this organism.     

Mutants of Yeast Sensitive to Ultraviolet Light

Six uvr mutants of Saccharomyces cerevisiae with hypersensitivity to ultraviolet (UV) light were isolated after mutagen treatment with ethylmethanesulfonate. UV sensitivity ranges from moderate to extreme, and four of the mutants are also sensitive to nitrous acid. Ranking in terms of UV sensitivity does not parallel ranking in terms of nitrous acid sensitivity. Homozygous diploid mutant strains are somewhat less sensitive than the corresponding haploids. All mutations are recessive. None of the mutants is sensitive to gamma rays, and each shows photoreactivation after UV radiation. Complementation tests and tetrad analysis indicate that each strain represents mutation in a different gene. Two of the uvr genes are linked, and two others are centromere-linked.     

Effects of ultraviolet radiation on carotenoid-containing and albino strains of Neurospora crassa

To determine the influence of carotenoids on UV sensitivity of Neurospora crassa conidia, the dose-response curves of 3 albino strains were compared to that of the wild type. In a control experiment the genetic background effects were eliminated by irradiating the wild type in which carotenoid synthesis had been inhibited by β-ionone, and comparing the dose-response curve to that of untreated wild type. All strains used had similar γ-ray survival curves and nuclei per conidium which precluded differences in UV sensitivity due to morphological differences.The albinos and β-ionone-treated strains showed a greater sensitivity (mean LD50 4.35·10³ erg/mm²) to UV irradiation than the wild type (LD50 7.30·10³ erg/mm²).     

Properties of Haemophilus influenzae mutants that are slightly recombination deficient and carry a mutation in the rec-1 gene region.

The highly recombination-deficient rec-1 mutants of Haemophilus influenzae are, as far as tested, equivalent to recA mutants of Escherichia coli. By selection for mutations in the rec-1 gene of H. influenzae, mutants designated ird (intermediary recombination-deficient) mutants were isolated; these mutants were much less recombination deficient (degree of transformability, 0.2 to 30% of wild-type value) than previously isolated rec-1 mutants (degree of transformability, 0.0001% of wild-type value). The ird mutants were more sensitive to ultraviolet irradiation and mytomycin C treatment than the wild type, but less sensitive than rec-1 mutants. Spontaneous production of phage HP1c1 by lysogenic MC11 cells and prophage induction by mitomycin C or ultraviolet irradiation were the same as in the wild type. In the ird mutants endogenous deoxyribonucleic acid was degraded both spontaneously and after ultraviolet irradiation to the same extent as in the wild type. Examination of one of the ird mutants revealed that recombination could be enhanced by ultraviolet irradiation, possibly because of an increased synthesis of the rec-1 gene product induced by ultraviolet irradiation.     

Ultraviolet Mutagenesis in Strains of <Emphasis Type="Italic">E. coli</Emphasis> deficient in DNA Polymerase

CERTAIN mutations in Escherichia coli which cause increased sensitivity to ultraviolet light (UV) drastically change the UV mutability of the sensitive strain. Strains lacking the ability to excise pyrimidine dimers, for example, exhibit greatly increased UV mutability, producing induced mutations at doses of UV far smaller than those required to induce mutations in wild type strains^{1, 2}. Mutants owing their UV sensitivity to reduced ability to perform genetic recombination, on the other hand, show reduced mutability in response to UV compared with the wild type and some (recA or exrA strains, for example) are stable to UV, producing no detectable induced mutations at any dose^3–5. Analysis of UV mutagenesis in such strains has led to the hypothesis that most UV-induced mutations in E. coli are errors in the recombinational repair of gaps in the daughter-strand which are located opposite unexcised pyrimidine dimers^{6, 7}.     

Double helicase II (uvrD)-helicase IV (helD) deletion mutants are defective in the recombination pathways of Escherichia coli.

The Escherichia coli helD (encoding helicase IV) and uvrD (encoding helicase II) genes have been deleted, independently and in combination, from the chromosome and replaced with genes encoding antibiotic resistance. Each deletion was verified by Southern blots, and the location of each deletion was confirmed by P1-mediated transduction. Cell strains containing the single and double deletions were viable, indicating that helicases II and IV are not essential for viability. Cell strains lacking helicase IV (delta helD) exhibited no increase in sensitivity to UV irradiation but were slightly more resistant to methyl methanesulfonate (MMS) than the isogenic wild-type cell strain. As expected, cell strains containing the helicase II deletion (delta uvrD) were sensitive to both UV irradiation and MMS. The introduction of the helicase IV deletion into a delta uvrD background had essentially no effect on the UV and MMS sensitivity of the cell strains analyzed. The double deletions, however, conferred a Rec- mutant phenotype for conjugational and transductional recombination in both recBC sbcB(C) and recBC sbcA backgrounds. The Rec- mutant phenotype was more profound in the recBC sbcB(C) background than in the recBC sbcA background. The recombination-deficient phenotype indicates the direct involvement of helicase II and/or helicase IV in the RecF pathway [recBC sbcB(C) background] and RecE pathway (recBC sbcA background) of recombination. The modest decrease in the recombination frequency observed in single-deletion mutants in the recBC sbcB(C) background suggests that either helicase is sufficient. In addition, helicase IV has been overexpressed in a tightly regulated system. The data suggest that even modest overexpression of helicase IV is lethal to the cell.     

Far-ultraviolet sensitivity and photoreactivation of Hirsutella thompsonii

The far-ultraviolet (FUV; 200–300 nm) sensitivity of four pathotypes of Hirsutella thompsonii, representative of three separate taxonomic varieties of the species, was investigated. The UV inactivation curves for the four strains were indistinguishable. A mutant exhibiting enhanced conidiation derived from the HTF-72 strain was more FUV sensitive than the four wild type strains (fluence enhancement factor ? 1.5). All strains were capable of efficiently photoreactivating FUV damage by a process which appeared to enzymatic.