DNA TURNOVER IN BUFFER-HELD ESCHERICHIA COLI AND ITS EFFECT ON REPAIR OF UV DAMAGE

Abstract— Continuous DNA degradation and resynthesis, without a net change in cellular DNA content, were observed in buffer-held, non-irradiated E. coli B/r. This constant DNA turnover probably involves most of the genome and reflects random sites of DNA repair due to the polA-dependent excision-resynthesis repair pathway. Under these non-growth conditions, it appears that at any given time there is a minimum of one repair site per 6.5 × 10⁶ daltons DNA, each of which is at least 160 nucleotides long.
While the amount of DNA degradation is not influenced by prior exposure to UV radiation, the synthetic activity decreases with increasing UV fluence. We suggest that when sites of DNA turnover occur opposite to cyclobutyl dipyrimidines in UV-irradiated cells, repair of the latter damage can be prevented. This implies that both beneficial and deleterious processes take place in irradiated buffer-held cells, and that cell survival depends on the delicate balance between DNA turnover and repair of UV-damage. Based on these findings, we propose a model to explain the limited repair observed during post-irradiation liquid-holding and to account for the large difference in cell survival between irradiation at low fluence rates (fluence-rate dependent recovery) and at high fluence rates followed by liquid-holding (liquid-holding recovery).     

DNA DAMAGE AND REPAIR IN HUMAN CELLS EXPOSED TO SUNLIGHT

Cultured human cells were treated with direct sunlight under conditions which minimised the hypertonic, hyperthermic and fixative effects of solar radiation. Sunlight produced similar levels of DNA strand breaks as equitoxic 254 nm UV in two fibroblast strains and a melanoma cell line, but DNA repair synthesis and inhibition of semiconservative DNA synthesis and of DNA chain elongation were significantly less for sunlight-exposed cells. DNA breaks induced by sunlight were removed more rapidly. Thus, the repair of solar damage differs considerably from 254 nm UV repair. Glass-filtered sunlight (> 320 nm) was not toxic to cells and did not induce repair synthesis but gave a low level of short-lived DNA breaks and some inhibition of DNA chain elongation; thymidine uptake was enhanced. Filtered sunlight slightly enhanced UV-induced repair synthesis and UV toxicity; photoreactivation of UV damage was not found. Attempts to transform human fibroblasts using sunlight, with or without phorbol ester, were unsuccessful.     

DNA SYNTHESIS-KINETICS, CELL DIVISION DELAY, AND POST-REPLICATION REPAIR AFTER UV IRRADIATION OF FROZEN CELLS OF E. COLI B/r

Abstract— Previous studies have shown that the relative yields of photoproducts produced in the DNA of Escherichia coli cells UV irradiated at -79°C differ from those produced at +21°C; the yield of DNA-protein cross-links was markedly enhanced at -79°C while the yield of thymine dimers was reduced. In the present studies, cells of E. coli B/r thy were frozen at -79°C, and then UV irradiated (254nm) while frozen(4.7 J m^-2), or after thawing (22 Jm^-2). Essentially the same survival, cell division delay, and DNA synthesis kinetics were observed for these two samples after irradiation, even though the UV fluence differed by a factor of ˜5. This supports previous observations that a correlation exists between the magnitude of the effects of UV radiation upon DNA synthesis kinetics and on cell survival. The weight average molecular weight of the pulse labeled DNA in the sample irradiated at +21°C was one-half that of the sample irradiated at -79°C, and complete repair of daughter-strand gaps was observed in both cases. Thus, UV-induced lesions produced in cells at -79°C (i.e. DNA-protein cross-links) appear to be amenable to post-replicational repair. While the overall DNA synthesis kinetics were the same for the two irradiation procedures, the apparent number of lesions produced per unit length of DNA was not. This suggests that each of the lesions produced in frozen cells, although apparently fewer in number, must cause a longer local delay in DNA synthesis than those lesions produced at +21°C.     

EFFECT OF UV IRRADIATION ON LETHAL INFECTION OF MICE WITH Candida albicans

Exposure of mice to UV radiation inhibits the induction and elicitation of the delayed-type hypersensitivity (DTH) response to Candida albicans. To determine whether UV irradiation also affects the pathogenesis of systemic C. albicans infection, C3H mice were exposed to a single dose of 48 kJ/m² UV-B radiation from FS40 sunlamps 5 days before or 5 days after sensitization with formalin-fixed C. albicans and challenged intravenously (i.v.) with a lethal dose of viable fungi 6 days after sensitization (11 or 1 days after UV irradiation). Exposing unsensitized mice to UV radiation 11 days before lethal challenge had no effect on survival, but the survival time of mice exposed to UV radiation 1 day before challenge was reduced by more than 50%. In the latter group, decreased survival time correlated with persistence of C. albicans in the brain and progressive growth of C. albicans in the kidneys. Sensitization of unirradiated mice with formalin-fixed C. albicans extended their survival time following lethal i.v. challenge with viable C. albicans. Exposing the mice to UV radiation 5 days before sensitization did not abrogate this beneficial effect of sensitization on survival, even though it significantly reduced the DTH response. Thus, immunity to systemic infection did not depend on the ability of the mice to exhibit a DTH response to C. albicans. The beneficial effect of sensitization on survival after lethal infection was abrogated, however, in mice exposed to UV radiation 1 day before lethal challenge with C. albicans. Furthermore, these mice were unable to contain the progressive growth of C. albicuns in the kidneys, in contrast to sensitized, unirradiated mice. The induction of cutaneous inflammation with turpentine had no effect on the survival rate of mice lethally infected with C. albicans, suggesting that inflammation alone is not sufficient to decrease the survival time of C. albicans-infected mice.     

TOXICITY, DNA DAMAGE AND INHIBITION OF DNA REPAIR SYNTHESIS IN HUMAN MELANOMA CELLS BY CONCENTRATED SUNLIGHT

A 1 m diameter water lens was used to focus solar radiation, giving an 8-fold concentration of the total spectrum and a cytocidal flux similar to that of laboratory UV sources. Survival curves for human melanoma cells were similar for sunlight and 254 nm UV, in that D _q, was usually larger than D _o. An xeroderma pigmentosum lymphoblastoid line was equally sensitive to both agents and human cell lines sensitive to ionizing radiation (lymphoblastoid lines), crosslinking agents or monofunctional alkylating agents (melanoma lines) had the same 254 nm UV and solar survival responses as appropriate control lines. Two melanoma sublines derived separately by 16 cycles of treatment with sunlight or 254 nm UV were crossresistant to both agents. In one melanoma cell line used for further studies, DNA strand breaks and DNA-protein crosslinking were induced in melanoma cells by sunlight but pyrimidine dimers (paper chromatography) and DNA interstrand crosslinking (alkaline elution) could not be detected. The solar fiuence response of DNA repair synthesis was much less than that from equitoxic 254 nm UV, reaching a maximum near the D _o value and then declining; semiconservative DNA synthesis on the other hand remained high. These effects were not due to changes in thymidine pool sizes. Solar exposure did not have a major effect on 254 nm UV-induced repair synthesis.     

ALKALINE ELUTION STUDIES OF HEMATOPORPHYRIN-DERIVATIVE PHOTOSENSITIZED DNA DAMAGE AND REPAIR IN CHINESE HAMSTER OVARY CELLS

Abstract We have used alkaline elution to study DNA damage produced by the photosensitizer hematoporphyrin derivative (HPD) in cultured Chinese hamster cells. Dosimetry was performed by measuring fluence and calculating photon absorption by intracellular HPD. HPD photosensitization causes DNA strand breakage. These breaks are repaired by the cell, although their fractional rate of repair is smaller than that for X-ray induced strand breaks at equivalent levels of strand breakage. The combined DNA polymerase inhibitors cytosine arabinoside and hydroxyurea suppress the repair of HPD-photosensitized breaks more strongly than they suppress repair of X-ray induced breaks. Addition of novobiocin to the aforementioned inhibitors causes almost total suppression of photosensitized break repair. A nucleotide excision repair system with inhibitor susceptibility similar to that of the system which removes pyrimidine dimers thus does not act upon HPD-photosensitized damage. The repair rate and inhibitor sensitivity findings together suggest biologically important differences in the chemical nature of X-ray induced and HPD-photosensitized strand breaks. In addition to strand breaks, HPD photosensitization produces covalent DNA-protein crosslinks, some of which persist through at least 90 min incubation, but which are repaired within 180 min.     

REPAIR OF UV DAMAGE IN ESCHERICHIA COLI UNDER NON-GROWTH CONDITIONS

Abstract. –A large difference in survival occurs between buffered suspensions of E. coli irradiated with UV radiation at a low fluence rate and those irradiated at a high fluence rate. For sufficiently large fluences, the extent of this fluence rate dependent recovery (FRR) is about two orders of magnitude greater than that which can be brought about by liquid holding recovery (LHR) following high fluence rate irradiation in most of the E. coli strains studied. LHR and FRR occur in excision resynthesis repair proficient (ERR⁺) but not ERR^- strains of E. coli , although its observation can be masked in strains with complete repair potential upon subsequent growth on nutrient plates. Accumulation of DNA strand interruptions and excision of cyclobutyl dipyrimidine occur during LHR and FRR but are more extensive for the latter. Our data suggest mat events beyond incision and excision occur during LHR and FRR, but differences in the extent of ERR during LHR and FRR cannot account for the difference in cell survival between these two phenomena.     

UV-INDUCED ALKALINE LABILE DNA DAMAGE IN HUMAN ADENOVIRUS AND ITS REPAIR AFTER INFECTION OF HUMAN CELLS

Abstract— UV-induced alkaline labile viral DNA damage was detected following irradiation of adenovirus type 2 and found to be repaired following the infection of human KB cells. Human adenovirus type 2 was irradiated with various doses of UV and subsequently used to infect human KB cells in tissue culture at approximately 2 × 10³ particles per cell. Before, and at various times after infection, the viral DNA was examined on alkaline sucrose gradients. Irradiated free virus DNA showed a dose dependent decrease in molecular weight compared to unirradiated virus DNA, indicating the presence of UV-induced alkaline labile lesions. Furthermore, an increase in the molecular weight of the irradiated virus DNA was found after infection indicating that alkaline labile lesions were removed from the viral DNA by a host mediated repair mechanism. After infection, the molecular weight of the irradiated virus DNA reached a value similar to that of unirradiated virus DNA for all the UV doses studied.     

EXCISION REPAIR IN TETRAHYMENA: EVENTS FOLLOWING REFEEDING OF STARVED UV-IRRADIATED CELLS

Abstract —Starvation of early-log-phase Tetrahymena pyriformis in non-nutrient phosphate buffer for 24 h results in a 40 per cent increase in cell number, as well as a complete cessation of DNA synthesis. Low levels of DNA synthesis are detectable between 1 and 2h after starved cells are transferred to a nutrient medium. Larger amounts of DNA synthesis are detected after the first 2 h of refeeding, and one round of replication is complete 4.5 h after refeeding. Damage, caused by sublethal doses of UV radiation (254 nm) administered just prior to refeeding, to the DNA of starved Tetrahymena appears to be corrected by an excision-repair process after refeeding of starved, irradiated cells. Changes in buoyant density of DNA synthesized, rate of DNA synthesis, and the chromatographic distribution of photoproducts were investigated following refeeding of starved, irradiated cells. Excision repair begins 1 h after refeeding and appears to be essentially complete within 7 h. During this time, thymine dimers produced by irradiation are removed. Semiconservative DNA synthesis commences 2–3 h after the first appearance of excision repair. In addition, between 3 and 8 h after refeeding, the rate of DNA synthesis in irradiated, refed cultures is much lower than the rate of DNA synthesis in unirradiated, refed cultures. Also, the specific activity in vitro of DNA polymerase from irradiated refed cells is very much greater than that of polymerase from unirradiated, refed cells.     

SATURATION OF DNA REPAIR IN MAMMALIAN CELLS*

Abstract—Excision repair seems to reach a plateau in normal human cells at a 254 nm dose near 20J/m². We measured excision repair in normal human fibroblasts up to 80J/m². The four techniques used (unscheduled DNA synthesis, photolysis of BrdUrd incorporated during repair, loss of sites sensitive to a UV endonuclease from Micrococcus luteus , and loss of pyrimidine dimers from DNA) showed little difference between the two doses. Moreover, the loss of endonuclease sites in 24 h following two 20J/m² doses separated by 24 h was similar to the loss observed following one dose. Hence, we concluded that the observed plateau in excision repair is real and does not represent some inhibitory process at high doses but a true saturation of one of the, rate limiting steps in repair.     

EFFECT OF INTENSITY AND WAVELENGTH OF FLUORESCENT LIGHT ON CHROMOSOME DAMAGE IN CULTURED MOUSE CELLS

Abstract—A single 3- to 20-hr exposure of line NCTC 9266 mouse cells to cool-white fluorescent light (4.6 W/m²) produces chromatid breaks and exchanges. The effective wavelength is in the visible range and coincides with the mercury emission peak at 405 nm. Increasing light intensity from 4.6 W to 15.3 W/m² for 20 h causes a concomitant increase both in production of chromosome damage and formation of hydrogen peroxide (H₂O₂) in the serum-free medium. Cells washed free of medium and illuminated in saline for 3 h show chromosome damage to the same extent as cells illuminated in culture medium. Addition of catalase during the exposure period of 3 h eliminates the light-induced damage. We conclude that the light-induced chromatid breaks and exchanges result from H₂O₂ production within the cell and that exogenous catalase can enter the cell and prevent the damage.     

EFFECT OF LIQUID HOLDING ON THE REPAIR OF PHOTOINDUCED DAMAGES IN ACRIFLAVINE SENSITIZED ESCHERICHIA COLI CELLS

Abstract— Damage caused by visible light in the presence of acriflavine can be repaired in various strains of Escherichia coli possessing one or the other repair mechanism. The number of viable cells of the irradiated E. coli cultures increases on holding in buffer. The results of liquid holding suggest that the major role played by holding in liquid medium is the removal of dye molecules from inside the cells; this would create a favourable condition for recovery during subsequent incubation.     

DNA REPAIR IN ULTRAVIOLET LIGHT IRRADIATED HeLa CELLS AND ITS REVERSIBLE INHIBITION BY HYDROXYUREA

Abstract— –The repair of u.v. damaged DNA in HeLa cells can be detected using the alkaline sucrose gradient technique. As a result of pyrimidine dimer excision single strand breaks are produced in DNA of irradiated cells. Rejoining of these breaks occurs during an 8 hr post-irradiation incubation period and is prevented by hydroxyurea and acriflavine. The inhibition of repair by hydroxyurea can be reversed by a mixture of all 4 deoxyribonucleosides at a concentration that does not reverse the inhibition of total DNA synthesis.     

MULTIPLE EFFECTS OF FLUORESCENT LIGHT ON REPAIR OF ULTRAVIOLET-INDUCED DNA LESIONS IN CULTURED GOLDFISH CELLS

Abstract— It is known that fluorescent light illumination prior to UV irradiation (FL preillumination) of cultured fish cells increases photorepair (PR) ability. In the present study, it was found that FL preillumination also enhanced UV resistance of logarithmically growing cells in the dark. This enhancement of UV resistance differs from induction of PR because it was not suppressed by cycloheximide (CH) and it occurred immediately after FL preillumination. The effects of FL preillumination on repair of UV-induced DNA lesions in the dark were examined by an endonuclease-sensitive site assay to measure the repair of cyclobutyl pyrimidine dimers, and by enzyme-linked immunosorbent assay to quantitate the repair of (6-4) photoproducts. It was found that excision repair ability for (6-4) photoproducts in the genome overall was increased by FL preillumination. Moreover, a decrease in (6-4) photoproducts by FL illumination immediately after UV irradiation of the cells was found, the decrement being enhanced by FL preillumination with or without CH.     

SITES OF PHOTODYNAMICALLY INDUCED DNA REPAIR IN HUMAN CELLS

Abstract Human REH cells were incubated with the photosensitizers meso -tetra(4-sulfonatophenyl)porphyrin (TSPP=TPPS₄) or meso -tetra(3-hydroxyphenyl)porphyrin (3-THPP). The relatively hydrophilic TSPP was partly found in the cytoplasm and partly in the nuclei, whereas the lipophilic 3-THPP was found apparently in membranes and not inside the nuclei. After illumination, sites of DNA repair were labeled by means of a monoclonal antibody against proliferating cell nuclear antigen (PCNA) bound in the nuclei. The amount of bound PCNA in non-S-phase cells was proportional to the light dose. The bound PCNA was homogeneously distributed in the nuclei 0.5 h after photodynamic treatment (PDT) with TSPP. In contrast, for cells given PDT with 3-THPP, the periphery of the nuclei was selectively labeled, indicating that the initial DNA damage was localized close to the sensitizer at the nuclear membrane.     

EFFECT OF NEAR-ULTRAVIOLET IRRADIATION ON PLANARIA*

Abstract— Near-UV radiation in the UV-B range prevented regeneration of segments of the turbellarian worm, Planaria. and reduced survival of intact animals as a direct function of the fluence supplied. Survival was photoperiod dependent suggesting dark-repair capacity. Near-UV radiation induced melanogenesis     

IMPAIRED REPAIR OF UVC-INDUCED DNA DAMAGE IN L5178Y-R CELLS: SEDIMENTATION STUDIES WITH THE USE OF 5''-BROMODEOXYURIDINE PHOTOLYSIS

Abstract Relative to their L5178Y-S counterparts, L5178Y-R cells have an impaired capacity to form patches in DNA after exposure to UVC radiation. The photolysis of 5'-bromodeoxyuridine (BrdUrd) incorporated into DNA was used to estimate the number of 'repair patches'formed in response to a 254 nm UV (UVC) exposure. L5178Y-S cells, typical of rodent cell lines, formed a small number of patches in exposed DNA (1-2 patches per 1 times 10⁸ dalton during a 6 h recovery after an exposure of 20 J/m²). In contrast, DNA extracted from L5178Y-R cells exposed to UVC and subsequently incubated with BrdUrd for 6 h showed no evidence of BrdUrd incorporation indicating no capacity to form sites of repair (fewer than 0.5 sites of BrdUrd incorporation per 1 times 10⁸ dalton). Moreover, in L5178Y-R cells high fluences of UVC caused an extensive DNA degradation. Such degradation was not observed in L5178Y-S cells during the 24-h post-exposure period. These results are consistent with the notion that L5178Y-R cells have a reduced capacity to repair DNA damage induced by UVC radiation.     

辐照亚硫酸纸浆结晶度的研究

<正> 纤维素分子中含有大量的羟基,易形成氢键,是结晶性很高的聚合物,无论在研究工作和工业生产中,这一性质都受到高度重视。纤维素在辐照场中的结晶行为,也是被研究的重点。从已发表的研究结果看,辐照纤维素的结晶行为有很大的差别,据有关文章报道,在γ射线和电子束射线的辐照场中,纤维素的结晶结构没有变化。例如,美国     

SENSITIVITY OF MONONUCLEAR CELLS TO UV RADIATION: EFFECT ON SUBSEQUENT STIMULATION WITH PHYTOHEMAGGLUTININ

The ability of peripheral blood mononuclear cells to incorporate ³[H] thymidine into nuclear DNA following stimulation by phytohemagglutinin is reduced by prior exposure to UV radiation in vitro : the reduction is dose and wavelength dependent. The doses required to affect this function of mononuclear cells are higher than the doses required to reduce trypan blue dye exclusion, so that following exposure to radiation populations of cells that are unable to exclude trypan blue dye are still capable of responding to phytohemagglutinin. This finding indicates that trypan blue dye exclusion may not accurately reflect the viability of cells after exposure to UV radiation.