MEMBRANE DAMAGE CAN BE A SIGNIFICANT FACTOR IN THE INACTIVATION OF ESCHERICHIA COLI BY NEAR-ULTRAVIOLET RADIATION

Abstract A DNA repair competent strain of Escherichia coli K-12 showed sensitivity to inorganic salts (at concentrations routinely used in minimal media) after irradiation with broad spectrum near–UV radiation, at fluences that caused little inactivation when plated on complex growth medium. This effect was not observed with cells that had been exposed to 254 nm radiation. This sensitivity to minimal medium was increased by increasing the salt concentration of the medium and by increasing the pH of the medium. This sensitivity was greatly increased by adding to the medium a low concentration of commercial glassware cleaning detergent that had no effect on unirradiated cells or far-UV irradiated cells. These findings may explain the large variability often observed in near-UV radiation survival data, and demonstrate that, at least on minimal medium plates, membrane damage contributes significantly towards cell killing. This phenomenon is largely oxygen dependent.     

THE EFFECTS OF LIQUID HOLDING ON NEAR-UV(300–400 nm) IRRADIATED ESCHERICHIA COLI STRAINS DIFFERING IN NEAR AND FAR-UV RADIATION SENSITIVITY

Abstract— Stationary phase cells from four Escherichia coli strains differing in near- (nur vs. nur ₊) and far-UV (recAl vs. recA₊) radiation sensitivity were subjected to near-UV radiation (NUV) in 0.85% saline. Although the NUV-irradiated cultures yielded increased colony numbers following 24 h of liquid holding (LH), a fluctuation test for each experiment showed that the observed increases were not due to recovery but were in fact due to cell multiplication. The decline in viability observed after NUV with liquid holding using the fluctuation test was equivalent in strains RT2, 3 and 4 while the decline observed with RT1 was less marked. The discrepancy between LH involving cell densities of 10₈-10₉ and 1–4 cells/m/ can be resolved by assuming that with dense cell suspensions, NUV-induced membrane damage leads to leakage or lysis, supplying sufficient nutrients to allow growth of undamaged, surviving cells.     

AN ACTION SPECTRUM FOR ULTRAVIOLET RADIATION-INDUCED MEMBRANE DAMAGE IN Escherichia coli K-12

A wild-type Escherichia coli K-12 strain was irradiated using monochromatic radiation in the range 254 to 405 nm. A measure of the cell membrane damage induced at each wavelength was investigated by comparing cell viability after irradiation on nutrient agar and on minimal medium containing either a low or high inorganic salt concentration. An action spectrum for lethality and for cell membrane damage was then determined. From 254 to 310 nm lethality closely corresponded to the absorption spectrum of DNA, and there was no indication of membrane damage. However, above a wavelength of 310 nm, the direct absorption of radiation by DNA could not account for the sensitivity observed. Moreover, at wavelengths longer than 310 nm, cell membrane damage was induced and by an increasing factor up to a peak at 334 nm. At the longer wavelengths of 365 and 405 nm, there was a gradual decrease from the peak of damage to cell membranes induced by 334 nm radiation. These results indicate that cell membrane damage may contribute significantly to near-UV radiation-induced cell lethality in wild-type E. coli K-12.     

OXYGEN-DEPENDENCE OF NEAR UV (365 NM) LETHALITY AND THE INTERACTION OF NEAR UV AND X-RAYS IN TWO MAMMALIAN CELL LINES

Abstract— The colony-forming ability of Chinese hamster cells (V-79) and HeLa cells has been measured after near-ultraviolet (UV) irradiation, predominantly at 365 nm. To avoid the production of toxic photoproducts, cells were irradiated in an inorganic buffer rather than in tissue culture medium. Under these circumstances near-UV lethality was strongly oxygen-dependent. Both cell lines were approximately 10⁴ times more sensitive to 254 nm irradiation than to 365 nm radiation when irradiated aerobically. Pretreatment with 6 times 10⁵ Jm^-2 365 nm radiation sensitised the HeLa, but not the V-79 cell line to subsequent X-irradiation. Pretreatment of cells with 17 Jm^-2 254 nm radiation, a dose calculated to produce twenty times more pyrimidine dimers than the 365 nm dose, produced only slight sensitisa-tion to X-rays. It is suggested that the sensitisation to X-rays seen in the HeLa cells after 365 nm treatment is not the result of lesions induced in DNA by the near-UV radiation, but may reflect the disruption of DNA-repair systems.     

THE EXPRESSION OF LIQUID HOLDING RECOVERY IN ULTRAVIOLET-IRRADIATED ESCHERICHIA COLI REQUIRES A DEFICIENCY IN GROWTH MEDIUM-DEPENDENT DNA REPAIR

Ultraviolet (UV) irradiated Escherichia coli K-12 recA cells (but not rec⁺ cells) show enhanced survival if they are held in buffer prior to plating for viability. To understand the role of the recA mutation in this liquid holding recovery (LHR) phenomenon, we have studied LHR in a temperature sensitive recA 200 mutant. The detection of LHR requires that the irradiated cells be recA when they are plated on growth medium, but the recA deficiency plays no role during liquid holding (LH). We conclude that it is the extreme sensitivity of recA cells in growth medium to unrepaired DNA daughter-strand gaps that magnifies the beneficial effects of the excision repair of DNA lesions during LH. Furthermore, we demonstrate a correlation between a strain's inability to perform growth medium dependent repair and its ability to express LHR. The relative amount of LHR was: recA > recF > lexA > recB > wild type (with the recB and wild-type strains showing negative LHR). Two strains did not show this correlation; the uvrD strain showed less LHR than expected from its UV radiation sensitivity, while the polA strain showed more. The molecular bases for these exceptions are explored.     

Bystander Effect Induced by UVC Radiation in Chinese hamster V79 cells

In past decades, researches on radiation‐induced bystander effect mainly focused on ionizing radiation such as α‐particle, β‐particle, X‐ray and γ‐ray. But few researches have been conducted on the ability of ultraviolet (UV) radiation‐induced bystander effect, and knowledge of UVC‐induced bystander effect is far limited. Here, we adopted medium transfer experiment to detect whether UVC could cause bystander effect in Chinese hamster V79 cells. We determined the cell viability, apoptosis rate, chromosome aberration and ultrastructure changes, respectively. Our results showed that: (1) the viability of UVC‐irradiated V79 cells declined significantly with the dosage of UVC; (2) similar to the irradiated cells, the main death type of bystander cells cultured in irradiation conditioned medium (ICMs) was also apoptosis; (3) soluble factors secreted by UVC‐irradiated cells could induce bystander effect in V79 cells; (4) cells treated with 4 h ICM collected from 90 mJ cm^?2 UVC‐irradiated cells displayed the strongest response. Our data revealed that UVC could cause bystander effect through the medium soluble factors excreted from irradiated cells and this bystander effect was a novel quantitative and kinetic response. These findings might provide a foundation to further explore the exact soluble bystander factors and detailed mechanism underlying UVC‐induced bystander effect.     

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.     

REPAIR OF NEAR-VISIBLE- and BLUE-LIGHT-INDUCED DNA SINGLE-STRAND BREAKS BY THE CHO CELL LINES AA8 and EM9

The induction of single-strand breaks (SSB) and the kinetics of SSB repair were measured in two Chinese hamster ovary cell lines irradiated with monochromatic photons of near-visible radiation (405 nm) and blue light (434 nm). The radiosensitive and UV-A-sensitive mutant line EM9 is known to repair SSB induced by ionizing radiation or 365-nm UV-A more slowly than the parent line AA8. At the 10% survival level, EM9 cells were 1.7- and 1.6-fold more sensitive than AA8 cells to 405 and 434 nm radiation, respectively. This sensitivity was not due to differences in induction of SSB because AA8 and EM9 cells accumulated the same number of initial breaks when irradiated at 0.5 degrees C with either 405 nm (5.9 SSB per MJ/m2) or 434 nm (5.1 SSB per MJ/m2), as measured by alkaline elution. When the cells repaired these SSB at 37 degrees C in full culture medium, biphasic repair kinetics were observed for both cell lines. In both phases of repair, EM9 cells repaired breaks induced by both wavelengths more slowly than did AA8 cells. The t1/2 values for the repair phases for 405-nm-induced SSB were 3.8 and 150 min for EM9, and 1.5 and 52 min for AA8; the corresponding values for repair of 434 nm breaks were 3.7 and 39 min for EM9, and 2.0 and 30 min for AA8. Because of this slower repair, EM9 cells left more SSB unrepaired after 90 min than did AA8 cells for both wavelengths.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Optimization of Inexpensive Agricultural By-Products as Raw Materials for Bacitracin Production in <Emphasis Type="Italic">Bacillus licheniformis</Emphasis> DW2

Bacitracin is a broad-spectrum antibiotic used extensively as a feed additive. In this study, inexpensive agricultural by-products were used as nitrogen sources for bacitracin production. Based on both the orthogonal tests, a combination of 7% soybean meal (SBM) +2% low protein rapeseed cake (LPRC) was optimal for bacitracin production. Compared to the original formula, the titer of bacitracin increased by 20.5% reaching 910.4 U/ml in flasks. The titer of bacitracin and the ratio of bacitracin A increased by 12.4 and 6.8% in a 50-l fermentor. Furthermore, this study also explored the effects of exogenously adding different amino acids on the yield of bacitracin. The addition of Cys and Glu enhanced bacitracin production by 5.7 and 5.0%, respectively. This study provided the inexpensive nutrient inputs into efficient bacitracin production and also the insight to further research enabling better utilization of oil cakes for economic viability of the bioprocess industry.     

CELL SURFACE DAMAGE IN CULTURED MAMMALIAN CELLS WITH SYNCHROTRON RADIATION AT 160 nm

Cultured mammalian cells (HeLa) were allowed to attach onto a membrane filter and were irradiated with 160 nm synchrotron radiation. The cells then were rinsed with medium, fixed, and stained. Some of the cells became detached from the membrane filter during irradiation before post-irradiation incubation at 37°C. The cells remaining attached to the membrane filter were released by trypsinization, collected and examined for dye-exclusion ability with eosin Y. The number of stained cells was increased when the cells were irradiated at 160 nm, while no such increase was observed in cells irradiated with synchrotron radiation at 220 nm, with a low pressure Hg lamp (predominantly 254 nm), or with gamma-rays of ⁶⁰Co. These results indicated that the cell surface was injured by irradiation with synchrotron radiation at 160 nm.     

METABOLISM OF NUCLEIC ACIDS IN U.V. IRRADIATED L-STRAIN CELLS TREATED WITH NATIVE DEOXYRIBONUCLEIC ACID

Abstract— In our earlier papers we described the recovery of U.V. irradiated L-strain cells by means of nucleic acids. In an attempt to get better insight in the mechanism(s) leading to this recovery we studied the effect of native DNA on the metabolism of nucleic acids of recipient cells. In these experiments we have found that the label isologous DNA-C¹⁴ is incorporated in DNA of normal and irradiated recipient cells. The rate of DNA-C¹⁴ label incorporation in the DNA of irradiated recipient cells is slower than in the unirradiated controls. The presence of thymidine in the incubation media reduces the incorporation rate of DNA-C¹⁴. When the irradiated cells have been growing in a medium containing isologous DNA in presence of thymidine or heterologous DNA the recovery effect was not observed.     

Alteration of uracil-DNA glycosylase activity by uracil dimers in DNA

Abstract The formation of colonies in solid medium was used as a criterion of viability to determine the effect of ultraviolet radiation on Trichomonas vaginalis. Both viability (colony) counts and total cell (hemocytometer) counts were used to estimate physiological ages of cell populations to be irradiated. Washed-cell suspensions in 0.6% saline were exposed to far- (254 nm) and near-UV (300–400 nm) radiation and dose-response survival curves were constructed from colony counts. The effect of far-UV was found to be independent of growth phase with the D₀ for exponential, early stationary, and late stationary cells 2.6, 2.7, and 2.7 J/m², respectively. Survival to near-UV increased with the age of cells with the estimated D₅₀ being 216 J/m² for exponential cells, 1360 J/m² for early stationary cells, and 4200 J/m² for late stationary cells. Exponential cells of Trichomonas gallinae irradiated with near-UV had a D₅₀ of 340 J/m². T. vaginalis is highly sensitive to far-UV relative to protozoa. T. vaginalis and T. gallinae are highly sensitive to near-UV relative to other microorganisms.     

Release of Inflammatory Mediators (PGE2, IL-6) by Fenofibric Acid-Photosensitized Human Keratinocytes and Fibroblasts

Ultraviolet-A radiation has weak effects on the release of inflammatory mediators by skin cells due to the poor overlap between UVA wavelengths and the absorption spectra of the relevant chromophores of key biomole-cules. However, this situation could be very different in the presence of a photosensitizing drug. To investigate this issue, we have irradiated human skin cells (keratinocytes and fibroblasts) in the presence of fenofibric acid (the active phototoxic metabolite of fenofibrate). The results of this research show a dual effect on the production/release of inflammatory mediators: the synthesis of the proinflammatory cytokine interleukin-6 becomes strongly inhibited at photosensitizer concentrations that clearly stimulate the production of prostaglandins (PGE₂) by skin cells. We have found evidences showing that the de novo synthesis of cytokines is inhibited in photosensitized cells due to the fact that cellular mRNA is degraded. Interestingly, when the medium taken from irradiated cultures is added to nonexposed cells, a significant stimulation of cytokine synthesis is observed that can be inhibited by anti-PGE₂ antibodies. These observations may be relevant in vivo, where prostaglandins released by photosensitized skin cells could stimulate cytokine synthesis by underlying, nonirradiated cells.     

AN ACTION SPECTRUM FOR BLUE AND NEAR ULTRAVIOLET IN ACTIVATION OF Propionibacterium acnes; WITH EMPHASIS ON A POSSIBLE PORPHYRIN PHOTOSENSITIZATION

— Propionibacterium acnes (P. acnes ), grown on Eagles medium with different pH. were irradiated with monochromatic light in the range 320 to 440 nm. Different pH leads to different porphyrin concentrations in the cells. The light sensitivity of the bacteria was estimated from the reduction in their ability to form colonies after radiation. The sensitivity was highest for the lowest wavelength (320 nm). and decreased continuously with increasing wavelength up to 380 nm. In the region between 380 and 440 nm there was a second maximum (at 415 nm) which corresponds to the maximum absorption ol the fluorescing porphyrins in P. acnes . The sensitivity to 415 nm light was found to be dependent on the endogenous porphyrin concentration in the cells. while the sensitivity to 320 nm radiation was independent of the amount of porphyrin present. These results indicate that porphyrins produced by the bacteria are important for the light sensitivity of these bacteria.     

Liquid-holding effects in U.V.-irradiated phage T3

Abstract— Holding complexes of u.v.-irradiated (254 nm) T3 phage in E. coli B/r cells for several hours at 37°C in buffer, or broth with chloramphenicol, affects the phage survival in at least two different ways: (1) by enhancing excision repair, resulting under certain conditions in liquid-holding recovery (LHR), and (2) by destroying the phage (holding inactivation). LHR is most apparent in buffer containing 20 μg ml^-1 chloramphenicol (CAP). It is expressed by as much as a 10–fold increase in the fraction of complexes that display host-cell reactivation (resulting from excision repair), but the percentage of u.v. lesions repaired within repair-proficient complexes is slightly decreased. LHR is not observed if T3 infects the repair-deficient strain B_s-1. Holding inactivation is readily observed with unirradiated phage complexes in broth containing CAP. The response of irradiated-phage complexes to liquid-holding conditions is more complex: holding inactivation is less effective for irradiated than for unirradiated phage DNA (i.e. the irradiated DNA is to some extent ‘protected’), and processes leading to LHR are superimposed. Thus under certain holding conditions one observes the paradoxical phenomenon that the viable titer of irradiated phage is several times higher than that of unirradiated phage. The nature of holding inactivation is not known, nor is the mechanism by which irradiated DNA is partially protected against it. Holding inactivation does not require protein synthesis; it is rather enhanced at high CAP concentration and seems to be favored by otherwise active cell metabolism. At high CAP concentrations (200–400 μg ml^-1, as compared to 20 μg ml^-1) irradiated-phage complexes show neither LHR nor protection against holding inactivation. Likewise they fail to undergo some step by which the phage DNA becomes insensitive to repair inhibition by caffeine.     

RECOVERY OF SUBCHROMOSOMAL DNA SYNTHESIS IN SYNCHRONOUS V-79 CHINESE HAMSTER CELLS AFTER ULTRAVIOLET LIGHT EXPOSURE

Abstract— Previous work obtained from Chinese hamster V-79 cells indicated that, immediately following exposure, UV-induced lesions acted as blocks to elongation of nascent strands, but gradually lost that ability over a 10 h period after exposure to 10 J/m². The work reported herein attempted to examine possible cell cycle mediated alterations in the recovery of DNA synthesis. Kinetic incorporation of radiolabeled thymidine studies indicated that there may have been a more rapid recovery of DNA synthesis in cells irradiated in G₁ or G₂ vs cells irradiated in S phase. DNA fiber autoradiograms prepared from synchronous cells indicated that after irradiation in any phase of the cell cycle, the length of newly synthesized DNA was equal to control lengths 1 h after exposure to 5.0 J/m² (or 1 h after entering S phase for cells irradiated in G₁ or G₂). This observed recovery was not solely due to an excision process. No cell cycle mediated difference in the number of dimers induced or removed as a function of cell cycle position was observed. These results appear to be consistent with a continuum of effects, with initiation effects dominating the response at low fluences, gapped synthesis at intermediate fluences and elongation inhibition at high fluences. The fluences at which each event dominates may be cell-line specific.     

THE EFFECTS OF ULTRAVIOLET AND VISIBLE RADIATION ON MOUSE ASCITES TUMOUR CELLS

Abstract— Effects of ultraviolet and visible radiation on the viability of Landschutz ascites tumour cells have been tested by growing control and treated tumour samples in adult mice. The tumour cells were irradiated as a dilute suspension in isotonic buffered salt solution, and were equilibrated at 0°C with oxygen or with nitrogen before irradiation.
Tumour cell proliferation was measured by a variety of techniques. The preferred assay-method was the growth of solid tumours in the axillae and groins of mice after sub-cutaneous inoculation of varying dilutions of treated or control ascites tumour cells. The immune response of the mice to the injected cells was reduced by whole body irradiation with a 300r dose of x-rays two days before inoculation. Results were calculated from parallel line assays using the reciprocal of the delay in appearance of the solid tumours up to 30 days post-innoculation. This reciprocal (1/T) was linearly related to the logarithm of the number of cells inoculated.
Photoreactivation has been demonstrated for this system, in which both U.V. and visible radiations were absorbed by the same cells. Light delivered alone in oxygen or in nitrogen was without effect on cell-viability, but it increased cell-survival after u.v.-irradiation in nitrogen and decreased survival after u.v.-irradiation in oxygen. Ultraviolet radiation alone was not significantly more lethal in oxygen than in nitrogen. A further observation in this work was an interaction between irradiated and control tumour cells injected into the same animal.
It is suggested that the radiation used may affect the antigenic character of the tumour cells as well as their reproductive capadity.     

m-THPC-Mediated Photodynamic Therapy (PDT) Does Not Induce Resistance to Chemotherapy, Radiotherapy or PDT on Human Breast Cancer Cells In Vitro

Photodynamic therapy (PDT) uses laser light to activate a photosensitizer that has been absorbed preferentially by cancer cells after systemic administration. A photo-toxic reaction ensues resulting in cell death and tissue necrosis. Some cells, however, may survive PDT. This study was performed to determine if surviving human breast cancer cells (MCF-7) can become resistant to PDT, chemotherapy or radiotherapy. The MCF-7 cells were cultured under standard conditions prior to being exposed to the photosensitizer, 5,10,15,20-meta-tet-ra(hydroxyphenyl)chlorin (zn-THPC), for 24 h and then irradiated with laser light (652 nm). Surviving cells were allowed to regrow by allowing a 2 week interval between each additional PDT. After the third and final treatment, colony formation assays were used to evaluate the sensitivity of cultured cells to ionizing radiation and PDT and the ATP cell viability assay tested in vitro chemosen-sitivity. Flow cytometry was used to analyze the cell cycle. No alterations in the cell cycle were observed after three cycles of PDT with m-THPC. Similar responses to chemotherapy and ionizing radiation were seen in control and treatment groups. The m-THPC-sensitized PDT did not induce resistance to subsequent cycles of PDT, chemo- or radiotherapy. Photodynamic therapy with m-THPC may represent a novel adjunctive treatment of breast cancer that may be combined with surgery, chemotherapy or ionizing radiation.     

USE OF THE DYE HOECHST 33258 TO INCREASE THE PHOTOSENSITIVITY OF BROMODEOXYURIDINE-CONTAINING CELLULAR SLIME MOLDS

The photosensitivity of amoebae of Dictyostelium discoideum to near-ultraviolet light (near-UV; 365 nm peak) was investigated following growth in 5-bromodeoxyuridine (BrdUrd) and treatment with the dye Hoeschst 33258. Cell killing was studied as a function of dye-treatment time and concentration, and BrdUrd incorporation time and concentration. For example, cells grown for 13 h in 50 μg BrdUrd/ml and then treated for 1 h in 10 μg dye/ml were reduced to 10% survival by a near-UV exposure of 0.8 min. Combinations of any two of the three factors (BrdUrd, dye, near-UV) were ineffective for killing. The sensitivity of the cells to near-UV decreased rapidly as the holding time between the end of the dye treatment and the start of the UV exposure was increased.