RECOVERY FROM DAMAGE INDUCED BY ACRIDINE PLUS NEAR-ULTRAVIOLET LIGHT IN ESCHERICHIA COLI

Abstract— Escherichia coli cells treated with sublethal doses of acridine plus near-UV light exhibit an effective split-dose recovery response that requires an incubation period of about 30–45 min. Studies of the metabolic requirements for split-dose recovery revealed the following: (a) DNA synthesis is not required for split-dose recovery; (b) inhibition of electron transport or protein synthesis reduces the efficiency of split-dose recovery by about one-half; (c) inhibition of phospholipid synthesis or cell wall synthesis completely eliminates the split-dose recovery response. These results suggest an involvement of membrane repair mechanisms in response to damage by acridine plus near-UV light. Additional evidence for such a process was provided by more direct assays for membrane recovery. It was found that cells treated with sublethal doses of acridine plus near-UV light are sensitive to low concentrations of detergents, and lose that sensitivity upon incubation. Likewise, treated cells are susceptible to lethal osmotic shock, but can recover from this susceptibility if incubated after treatment but prior to exposure to low osmotic conditions. Based on accumulating evidence, we propose that E. coli cells are capable of repairing membrane damage resulting from exposure to acridine plus near-UV light.     

GROWTH DELAY INDUCED IN ESCHERICHIA COLI BY NEAR-ULTRAVIOLET RADIATION: RELATIONSHIP TO MEMBRANE TRANSPORT FUNCTIONS*

Abstract— Rates of leucíne transport, oxygen utilization, and glucose and succinate uptake were determined in cultures of Escherichia coli B/r before and after exposure to near-UV light. Within experimental errors, rates of uptake of glucose and of succinate were proportional to growth rate at all times during the recovery or growth delay period following near-UV exposure and the same proportionality was maintained in unexposed cultures. However, rates of leucine uptake and incorporation and of oxygen utilization were not related to growth rate in a simple fashion. The results suggest that inhibition of carbon source transport is a fundamental component, and may be a primary mechanism, in growth delay induced by near-UV radiation.     

MUTATIONAL INTERACTIONS BETWEEN NEAR-UV RADIATION AND DNA DAMAGING AGENTS IN Escherichia coli: THE ROLE OF NEAR-UV-INDUCED MODIFICATIONS IN GROWTH AND MACROMOLECULAR SYNTHESIS

Abstract— The mutational interactions between near-ultraviolet (near-UV, 334 nm, 365 nm) radiation and DNA damaging agents (far-UV (254 nm) and ethyl-methanesulphonate (EMS)) were studied in strains of Escherichia coli B/r trp thy with different susceptibilities to near-UV-induced growth delay (wild-type, rel and srd ). Far-UV induced reversion to tryptophan independence is reduced while forward mutation to streptomycin is enhanced by prior exposure of the rel+ srd+ strains to near-UV radiation. The observed interactions are reduced ( rel ) or absent ( srd ) in the two mutant strains as are the corresponding growth and macromolecular synthesis delays normally observed after near-UV treatment. Quantitatively, the degree of interaction induced by near-UV pre-treatment correlates closely with the degree of protein synthesis inhibition. We propose a mechanism for the contrasting interactions at the two genetic loci based on the different pathways by which pre-mutagenic lesions may be processed. The primary chromophore for the mutational interactions would appear to be 4-thiouracil-containing transfer RNA.     

LEAKAGE OF 86Rb+ AFTER ULTRAVIOLET IRRADIATION OF Escherichia coli K-12

Abstract— Stationary phase cultures of a DNA repair proficient Escherichia coli K-12 strain showed a release of intracellular material as assessed by three different methods (260 nm absorption; [methyl-³H]thymidine leakage and ⁸⁶Rb⁺ leakage) after broad-band (Black-Light Blue) near-UV radiation but not after far-UV (254 nm) radiation. As a control response for membrane damage to cells, this leakage of intracellular material was also determined by each method after mild-heat (52°C) treatment of E. coli K-12. An action spectrum for the release of ⁸⁶Rb⁺ from E. coli K-12 after irradiation with monochromatic wavelengths, from 254 to 405 nm, is also presented. The action spectrum for lethality (F₃₇ values) obtained for this strain, shows that leakage of ⁸⁶Rb⁺ occurs at fluences equivalent to or slightly less than fluences causing inactivation at wavelengths above 305 nm. In contrast, at wavelengths below 305 nm, leakage of ⁸⁶Rb⁺ from irradiated cells can be induced but only at fluences significantly greater than was required to cause cell inactivation. These results indicate, therefore, that near-UV radiation can induce a damaging effect on the cell's permeability barrier which may be significant in causing the death of the cell, whereas the effect is not significant in causing the death of cells by far-UV radiation where DNA damage is known to be the main cause of lethality.     

The roles of the rel+ gene and of 4-thiouridine in killing and photoprotection of Escherichia coli by near-ultraviolet radiation

Abstract— Photoprotection is a reduction in response to far-UV (190–300. nm) radiation in cells that have been previously exposed to longer wavelengths. It has been proposed that photoprotection operates by means of a growth delay that permits more time for dark repair. Growth delay in Escherichia coli utilizes 4-thiouridine (⁴Srd) in transfer RNA as a chromophore and it requires the rel⁺ gene, which exerts a stringent control upon RNA synthesis. Mutants that were either rel or ⁴Srd^? were isolated from E. coli B, utilizing a near-UV-induced growth-delay selection technique. The rel mutants, which undergo little growth delay after near-UV irradiation, show only 50% as much photoprotection as wild types, while ⁴Srd^? mutants show no photoprotection at all. Thus, photoprotection appears to utilize ⁴Srd as its sole chromophore in E. coli B and B/r, and no more than 50% of photoprotection in these strains can be a result of near-UV-induced growth delay.     

ROLES OF THE RELA+ GENE AND OF 4-THIOURIDINE IN NEAR-ULTRAVIOLET (334 nm) RADIATION INHIBITION OF INDUCED SYNTHESIS OF TRYPTOPHANASE IN ESCHERICHIA COLI B/r

Abstract— Near-ultraviolet radiation (near UV; 300–380 nm) is known to inhibit the induced synthesis of tryptophanase by tryptophan in Escherichia coli , showing an action spectrum similar to that for near-UV-induced growth delay. The present work shows that a rel A mutant of E. coli B/r exhibits 50% as much monochromatic near-UV (334 nm) inhibition of tryptophanase induction as the wild type, and that a mutant lacking 4-thiouridine, an unusual nucleoside in tRNA, exhibits < 10% as much inhibition of tryptophanase induction. These findings indicate that 4-thiouridine is almost the sole chromophore for this effect in E. coli B/r, but that only 50% of the effect operates by a mechanism utilizing the rel A ⁺ gene product; growth delay appears not to be primarily involved.     

DEPENDENCE ON STAGE OF GROWTH OF MAMMALIAN CELL SENSITIVITY TO NEAR-UV IRRADIATION*

Abstract The variable sensitivity of exponentially growing mouse myeloma cells (66.2 subclone of MPC11) to monochromatic near-UV (365 nm) radiation was studied by determination of the relative cloning efficiency (i.e. survival) of cells in soft agar. Maximum sensitivity of the cells to near-UV light was found during the middle and late stages of exponential growth when the survival was only one-tenth of that during the early stage of growth. In addition, the shapes of near-UV survival curves changed with the stage of the cells irradiated. These data indicate that stages of growth can substantially alter the response of mammalian cells to near-UV radiation. These data further suggest the importance of testing the response of the cells throughout the growth employed in the experimental procedure.     

ACTION SPECTRUM FOR GROWTH DELAY INDUCED BY NEAR-ULTRAVIOLET LIGHT IN E. coli B/r K*

Abstract— The action spectrum for growth delay induced by near-uv light was determined for Escherichia coli B/r growing in a defined medium. This spectrum agrees with and extends that determined earlier by Jagger and his co-workers for E. coli B growing in nutrient broth. The extended spectrum is indistinguishable from the absorption spectrum for 4-thiouridine above 320 nm, but deviates significantly at wavelengths shorter than this from the spectrum for 8–13 link formation in transfer RNA containing 4-thiouridine at position 8. These results extend the evidence that 4-thiouridine in transfer RNA is the chromophore for near-UV induction of growth delay, but weaken the case for linkage of a pyrimidine at position 13 in transfer RNA as the mechanism of growth delay.     

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.     

MEASUREMENT OF DNA CROSSLINKS BY S1 NUCLEASE: INDUCTION AND REPAIR IN PSORALEN-PLUS-360 nm LIGHT TREATED ESCHERICHIA COLI

Abstract—DNA crosslinks in Escherichia coli cells. exposed to 4.5',8-trimethylpsoralen plus 360 nm light, were measured using a rapid and sensitive new approach. The assay is based on the specificity of S₁ nuclease from Aspergillus oryzae to single-stranded DNA. Bacterial cells were lysed and the DNA denatured by alkali. Following acid neutralization. crosslinked DNA undergoes spontaneous renaturation and is rendered S₁-nuclease resistant and therefore acid-precipitable. The single-stranded fraction after denaturation by alkali decreases with increasing near UV light exposure in the presence of TMP following first order kinetics. The kinetics were faster when exposure was at 4°C rather than at 20°C. This suggests that excision of crosslinks occurs during exposure at the higher temperature. Indeed. since the rate of DNA crosslinking in a uvr B mutant which is excision-deficient was higher than in wild type bacteria at 4°C, some excision must have occurred even in the cold. DNA from excision-proficient cells incubated at 37°C following exposure to TMP-plus-near UV at 4° showed a greater single stranded fraction than that from non-incubated cells. This indicates repair of DNA crosslinks. which proceeded with a half-time of 8 min at 37°C and was unaffected by substitution of thymine in DNA by 5-bromouracil.     

REDUCTION BY NEAR-ULTRAVIOLET (334 nm) LIGHT OF E. COLI CAPACITY FOR PHAGE GROWTH DEPENDS UPON THE rel GENE AND 4-THIOURIDINE

Abstract— Near-ultraviolet radiation (near UV; 300–380 nm) has long been known to produce a transient reduction of the capacity of bacteria to support phage growth. The present work shows that, at high fluenœs (40–100 kJ/m²), 85% of 334-nm-induced reduction of capacity in Escherichia coli B/r requires the rel gene; that is, it results from rel -gene activity caused by the near-UV treatment. This rel -gene activity leads to (1) a bacterial growth delay and concomitantly lowered bacterial metabolism, and (2) a parallel delay in phage development, with a considerable depression of burst size. We propose that the observed effects on phage development are a consequence primarily of the lowered bacterial metabolism, but they may also result partly from a direct inhibition of phage DNA synthesis by the rel gene product, these effects together leading to the observed reduction of capacity in a rel ⁺ strain. The remaining 15% of capacity reduction, observed in a rel strain, has an unknown mechanism, but does appear to involve a delay in phage development.
At least 95% of the total capacity reduction observed in the rel ⁺ strain in the range 40–100 kJ/m² requires the presence of 4-thiouridine, an unusual base in E. coli transfer RNA, which is presumably both the chromophore and the target for near-UV-induced capacity reduction.     

EFFECT OF FAR-UV AND NEAR-UV RADIATION ON THE CELL SURFACE CHARGE OF THE PROTOZOAN

Abstract— Cell electrophoresis was used to detect the effect of far-UV or near-UV radiation on the cell surface charge of the pathogenic protozoan Tritrichomonas foerus . Either far-UV or near-UV radiation interfered with the surface charge of T. foetus at fluences which inhibited cell growth by 50%. Both UV-radiations induced a significant decrease on surface charge of T. foetus , as evaluated by measurement of its electrophoretic mobility (EPM). Determinations of EPM of protozoa in solution of low ionic strength indicated that the decrease in the EPM induced by far-UV is much less pronounced than that observed for near-UV or control cells.     

RECOVERY OF Escherichia coli K-12 FROM NEAR-ULTRAVIOLET RADIATION-INDUCED MEMBRANE DAMAGE

Abstract A wild-type Escherichia coli K-12 strain was irradiated with broad-band near-ultraviolet radiation (from Black-Light Blue fluorescent lamps) and after holding at 37°C for various times in a complex recovery medium, was assessed for viability on either complex medium (YENB) or minimal medium containing a high inorganic salt content. A near-ultraviolet radiation fluence was used which reduced the surviving fraction to approximately 10% when assessing for viability on the complex medium plates. A near-ultraviolet radiation induced sensitivity to inorganic salt was observed which was largely recoverable by holding treated cells in a complex recovery medium. The majority of the recovery process occurred in the initial 2 h post-irradiation holding period. No inhibition of the recovery process was produced by adding chloramphenicol (40 μg/m l ) or penicillin G (11 units/m l ) to the recovery medium, indicating that neither protein synthesis nor cell wall synthesis, respectively, were required for recovery. However, by adding bacitracin, an antibiotic which acts in part by inhibiting membrane synthesis, to the recovery medium, an effect on recovery from salt sensitivity was observed. At the concentrations of bacitracin used (0.6 and 0.2 units/m l ), little or no effect was observed on unirradiated cells, but both concentrations decreased the amount of recovery of irradiated cells. These results demonstrate that recovery from near-ultraviolet radiation-induced salt sensitivity occurs, it is independent of cell growth and the effect of bacitracin suggests that membrane synthesis may be required for recovery.     

IN SITU HYDROGEN PEROXIDE PRODUCTION MAY ACCOUNT FOR A PORTION OF NUV (300–400 nm) INACTIVATION OF STATIONARY PHASE Escherichia coli

Abstract— Pre-irradiation of stationary phase cells of Escherichia coli K-12 with broadband near-UV radiation potentiates the lethal effects of subsequent exposure to near-UV radiation plus hydrogen peroxide. Identical fluences failed to modulate killing due to far-UV radiation. These data indicate that biologically revelant levels of hydrogen peroxide may be generated in situ upon the near-UV irradiation of cells.     

LIPID PEROXIDATION AND OTHER MEMBRANE DAMAGE PRODUCED IN Escherichia coli K1060 BY NEAR-UV RADIATION AND DEUTERIUM OXIDE

Abstract— With accumulating evidence that the membrane is an important site for near-UV inactivating events, we have investigated the effects of near-UV radiation on the unsaturated fatty acid auxotroph E. coli K1060 following incorporation into the membrane phospholipids of fatty acids with varying degrees of unsaturation. Sensitivity, lipid peroxidation and membrane damage, as determined by ⁸⁶Rb⁺ leakage, have been found to increase with increasing unsaturation in log-phase cells. Similar experiments carried out in D₂O also show an increase in sensitivity, lipid peroxidation and membrane damage, indicating that singlet oxygen may be responsible for such near-UV-radiation-induced damage     

POSSIBLE INVOLVEMENT OF MEMBRANE DAMAGE IN THE IN ACTIVATION BY BROAD-BAND NEAR-UV RADIATION IN Saccharomyces cerevisiae CELLS

Multiple cellular effects of near-UV radiation (300-380 nm) on inactivation, disruption of the permeability barrier and induction of gene conversion at the trp 5 locus were simultaneously measured in the same culture of a diploid strain of the yeast Saccharomyces cerevisiae in order to assess the critical lethal damage. Inactivation of exponential phase cells in water appeared to be closely related to the disruption of the permeability barrier. Inactivation and membrane damage were remarkably oxygen dependent, whereas the induction of genetic changes was very low and dependent much less on oxygen. The dependence on the temperature for inactivation and membrane damage was both low, conforming with the expectation that the processes are mainly photochemical and not enzymatic. These features are very contrasted with the characteristics of far-UV radiation effects. Possible involvement of membrane damage in near-UV inactivation of exponential phase yeast cells is discussed.     

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.     

FORMATION BY HYDROGEN PEROXIDE OR 254 nm RADIATION OF A NEAR-UV CHROMOPHORE FROM PEPTIDE-BOUND CYSTEINE

Abstract Treatment of glutathione or N-acetylcysteinamide in water with hydrogen peroxide, or with 254 nm radiation together with molecular oxygen, results in the formation of a near-UV chromophore having maximal absorption at 305 nm. From examination of related compounds, it is apparent that the N-acylcysteinamide residue is the key element required for generation of the 305 nm chromophore. The structure of this near-UV chromophore is stable to base but unstable in aqueous acid, is relatively sensitive to oxidation by hydrogen peroxide but is only very slowly reduced by sodium borohydride and displays good thermal stability at 50°C.     

Action spectra for modification of Escherichia coli B/r menaquinone by near-ultraviolet and visible radiations (313-578 nm)

–Menaquinone-8 (MQ-8) was irradiated in vivo in Escherichia coli B/r and in vitro after extraction from E. coli B/r, using monochromatic radiation in the range 313–578 nm. Within experimental error, the action spectra for loss of chromatographic mobility after irradiation in vivo and in vitro agree with each other and with the absorption spectrum of pure MQ-8. The MQ-8 is extremely sensitive to near-UV light (300–380 nm), showing an F₃₇in vivo at 334 nm of 1.3 kj/m², a value 15 times lower than that required for growth delay, and 150 times lower than that for killing, of E. coli B/r. The quantum yield for this reaction in vivo at 334 nm has the very high value of 0.26. The high sensitivity of MQ-8 suggests involvement in near-UV-induced effects on the plasma membrane.     

IMPAIRMENT OF RED CELL MEMBRANE CYTOSKELETON BY PROTOPORPHYRIN-IX: LIGHT AND DARK EFFECTS

Abstract— Membrane cytoskeletons were separated by use of TritonX–100 from freshly isolated red cells, fixed with glutaraldehyde and their morphology was followed by scanning electron microscopy. At 37°C and pH 6.5 cytoskeletons retained cell-like shapes for at least 2 h, but at higher pH values, they lost stability after 30 min, appearing as amorphous protein material. Irradiation in the presence of1–20 μ M protoporphyrin-IX at pH 6.5 caused crosslinking of the proteins when organized as cytoskeletons, but not when separated. Scanning electron microscopy also revealed that the cytoskeletal proteins conserved their cell-like shape even at pH values higher than 7.0. It was concluded that illumination in the presence of porphyrin causes membrane rigidity by crosslinking of the cytoskeletal proteins, and their sensitivity to crosslinking is the result of their mutual arrangement in the membrane. At concentrations higher than 100 μ M protoporphyrin-IX induced, even in the absence of light, the opposite effect, namely dissociation of the cytoskeletal proteins. The data suggest that the changes observed in this study provide an explanation for both dark and light induced injuries of red cells in porphyria disorders.