THE ROLE OF PYRIMIDINE DIMERS AND NON-DIMER DAMAGE IN THE INACTIVATION OF ESCHERICHIA COLI BY UV RADIATION

Abstract— We have quantitated the role of pyrimidine dimers and non-dimer damage in the inactivation of Escherichia coli by far-UV radiation, near-UV radiation, and triplet state sensitized near-UV radiation. The extent of photoreactivation in vivo of an excision and postreplication repair-deficient strain of E. coli after the different radiation treatments has been correlated with the relative proportion of pyrimidine dimers and non-dimer lesions produced. Using an excision deficient strain of E. coli, the susceptibility to recA ⁺ -dependent repair of the damage produced by the different radiation treatments has also been quantified.     

STUDY OF PYRIMIDINE DIMERS IN MAMMALIAN CELLS SURVIVING LOW DOSES OF ULTRAVIOLET RADIATION*

Abstract— Ultraviolet-induced pyrimidine dimers were not found to be excided from the DNA of Chinese hamster cells in small oligounucleotides. At doses whereby many cells survive the radiation, the dimers were still associates with the large polynucleotides even after 48 hr of postirradiation incubation.     

DELAY IN GROWTH AND DIVISION INDUCED BY NEAR ULTRAVIOLET RADIATION IN ESCHERICHIA COLI B AND ITS ROLE IN PHOTOPROTECTION AND LIQUID HOLDING RECOVERY

Abstract. Microscopic observations show that growth delay and division delay occur on nutrient agar after Escherichia coli B has been irradiated at 3341 Å. These effects also occur in nutrient broth.
A near u.v. action spectrum for growth delay in nutrient broth has been obtained. It shows a single peak at 3380 Å and is indistinguishable from the action spectrum for photo-protection from far u.v. (2537 Å) killing in the same organism. Furthermore, photoprotected cells show a much greater growth delay than cells that have not been photoprotected. These, as well as kinetic data, suggest that the essential action of a photoprotection treatment consists in the induction of a growth-division delay. This delay would presumably permit more time for intracellular recovery systems to operate on the far u. v. damage to nucleic acids.
Liquid holding recovery (effected by holding cells in phosphate buffer after far u. v. irradiation) shows complete overlap with photoprotection. It is concluded that photoprotection and liquid holding recovery operate on the same far u. v. damage. As with photoprotection, it is probable that the essential action of a liquid holding treatment is the induction of a growth-division delay.
No photoprotection is observed of intracellular T2 bacteriophage or of E. coli B_s-l (Hill).     

INDUCED REPAIR IN ESCHERICHIA COLI: INDUCTION BY ULTRAVIOLET LIGHT AT-79°C

Two of the phenomena associated with induced (S.O.S.) repair, namely induced inhibition of post radiation DNA degradation and induced radioresistance have been shown to be elicited by 245 nm radiation applied to E. coli cells in the frozen state at -79°C. The effect of radiation in this condition is considerably less photoreactivable than similar effects produced by exposure in the wet state. Since protein-DNA crosslinks are believed to be formed under these conditions, such consequences of UV radiation appear to be a potent inducer of induced repair.     

SINGLE-STRAND DNA BREAKS INDUCED BY 365 NM RADIATION IN ESCHERICHIA COLI STRAINS DIFFERING IN SENSITIVITY TO NEAR and FAR UV

The gene mutation nur has been shown specifically to sensitize Escherichia coli stationary phase cells to inactivation by broad spectrum near-UV (NUV) radiation. In the work reported here, E. coli strains RT1. RT2, RT3, and RT4, carrying the 4 possible combinations of recA1, recA⁺, nur , and nur⁺ , were exposed to monochromatic NUV (365 nm). The strains carrying the nur allele (RT1 and RT2) were more sensitive to inactivation by this wavelength and exhibited considerably more single strand break's (SSB's) than the strains carrying the nur⁺ allele (RT3 and RT4). As predicted, following X-irradiation the strains carrying the recA1 allele (RT1 and RT3) were more sensitive than the recA⁺ strains (RT2 and RT4). We conclude that the enhanced SSB's observed in strains RT1 and RT2 following monochromatic NUV irradiation correlated with the nur mutation and are unrelated to the recA1 mutation.     

FORMATION OF THYMINE DIMERS IN MAMMALIAN SKIN BY ULTRAVIOLET RADIATION IN VIVO

Abstract— Ultraviolet radiation of 220–300 nm is known to produce cyclobutyl pyrimidine dimers in extracellular DNA, in bacteria, and in mammalian cells in culture. The formation in vivo of such dimers in mammalian skin has remained inferential. We report that one of the important and recognizable biologic events that occurs in mammalian skin during irradiation is the formation of thymine dimers. [³H]-labelled thymidine was applied to the epilated skin of guinea pigs to label their DNA. Animals were irradiated individually, using wavelengths of either 254, 285–350, or 320–400 nm. Immediately after irradiation, epidermis was separated from the rest of the skin and homogenized; DNA and RNA were isolated. Irradiation with wavelengths of 285–350 nm, which included the sunburn-producing spectrum (i.e., 290–320 nm), produced thymine dimers (1·7–2·6 per cent of the total [³H]-thymine incorporated into DNA). Irradiation with 254nm also produced fewer dimers (0·46–1·2 percent); and 320–400 nm produced none. The dimer could be cleaved by 250 nm radiation to form thymine. The epidermal cell damage by ultraviolet radiation, particularly by the sunburn-producing spectrum (290–320 nm), may be related to the formation of such dimers.     

USE OF METABOLIC INHIBITORS TO INVESTIGATE THE EXCISION REPAIR OF PYRIMIDINE DIMERS AND NON-DIMER DNA DAMAGES INDUCED IN HUMAN AND ICR 2A FROG CELLS BY SOLAR ULTRAVIOLET RADIATION

Abstract— ICR 2A frog and normal human skin fibroblasts were exposed to either 5 J/m² of 254 nm UV or 50 kJ/m² of the Mylar-filtered solar UV wavelengths produced by a fluorescent sunlamp. Following these approximately equitoxic treatments, cells were incubated in medium containing the DNA synthesis inhibitors hydroxyurea (HU) and 1–β-D-arabinofuranosyl cytosine (ara C) for 0–20 min (human fibroblasts) or 0–4 h (frog cells) to accumulate DNA breaks resulting from enzymatic incision during excision repair. It was found that breaks were formed in human cells at about a 200-f-old higher rate compared with the ICR 2A cells indicating a relatively low capacity for excision repair in the frog cells. In addition, the rate of DNA break formation in solar UV-irradiated cells was only one-third of the level detected in 254 nm-irradiated cells. This result is consistent with the conclusion that the pathway(s) involved in the repair of solar UV-induced DNA damages differs from the repair of lesions produced in cells exposed to 254 nm UV.     

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.     

SEQUENCE-SPECIFICITY OF THE ALKALI-SENSITIVE LESIONS INDUCED IN DNA BY HIGH-INTENSITY ULTRAVIOLET LASER RADIATION

The action of high-intensity (10(9)-10(12) W/m2) UV (266 nm) laser radiation pulses (duration ca 10 ns or ca 40 ps) on liquid aqueous solutions of DNA is known to cause not only single- but also two-quantum modification of nucleic bases. The action of hot piperidine on the laser-irradiated DNA results in non-random splitting of polynucleotide chain. Hence, at least some of the modified nucleoside residues are alkali-sensitive lesions (ASLs). The distribution of ASLs along the DNA chain shows that the position of these lesions corresponds with pyrimidines in the PyPy sequences (similar to those formed via single-quantum conversions) as well as with deoxyguanosine residues. The last ASLs result from two-quantum reactions and occur much more efficiently than the direct photo-induced cleavage of the internucleotide (phosphodiester) bond. It has been shown with fragments of plasmids pUC18, pUC19 and pBR322 (total length over 600 base pairs) that the relative efficiency of ASLs at deoxyguanosine sites depends on the primary structure context and can differ by an order of magnitude. The highest efficiency of modification is observed when a purine is 3' neighbour to the 2'-deoxyguanosine, i.e. at 5'-GPu-3' sites. However, considerable variations in the modification efficiency were also found in these sequences.     

PHOTOREPAIR OF NONADJACENT PYRIMIDINE DIMERS BY DNA PHOTOLYASE

Abstract— Photolyases reverse the harmful effects of UV light on cells by converting pyrimidine dimers (Pyr[]Pyr) into two pyrimidine monomers by utilizing near-UV and visible light. Previous work has shown that photolyase repairs T[c,s]T and T[t,s]T in DNA as well as U[]U in RNA, all of which are formed by joining the two adjacent pyrimidines in a light-dependent reaction. In this report, we show that Pyr[]Pyr formed in nonadjacent pyrimidines are also substrates for DNA photolyase.     

VISUALIZATION OF ULTRAVIOLET LIGHT-INDUCED THYMINE DIMERS IN DNA BY IMMUNOELECTRON MICROSCOPY

Abstract— To see the damage of DNA due to ultravoilet-B more distinctly, immunoelectron microscopic studies using a monoclonal antibody against cyclobutane-type thymine dimers were performed. As a result, we could detect the existence of thymine dimers on human genomic DNA and _pUC18 plasmid DNA visually. This technique can be useful to locate the photoproducts formed on DNA.     

ANGIOTENSIN ALTERATIONS INDUCED BY ULTRAVIOLET RADIATION*

Abstract. Angiotensin is readily inactivated by ultraviolet light presumably due to the photosensitivity of its tyrosyl and phenylalanyl residues. Alkalinity promotes and acidity delays the biological decomposition. Under conditions of oxygen exclusion (i.e. under N₂ or H₂) the rate of decomposition is further depressed and when irradiation is carried out under hydrogen a biologically active product is formed. This altered angiotensin, judging from its chromatographic migration and dialysis rate, represents a polymerized form of angiotensin. Under identical irradiation conditions, angiotensin was coupled with C¹⁴ labelled pheny-lalanine which indicates that this residue might be the photoreactive species. The production of altered forms of angiotensin by ultraviolet irradiation was discussed with respect to possible utility in anti-metabolite, antigen or tracer work.     

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.     

PHOTOSENSITIZED SPLITTING OF PYRIMIDINE DIMERS IN DNA BY INDOLE DERIVATIVES AND TRYPTOPHAN-CONTAINING PEPTIDES

Abstract —Indole derivatives, such as serotonin or the oligopeptide Lys-Trp-Lys, are able to photosensitize the splitting of thymine dimers in DNA. These indole derivatives have to be bound to DNA in order to efficiently photosensitize the splitting reaction. Serotonin may also induce the photosensitized formation of thymine-containing dimers in native DNA. In this case, an equilibrium is reached when 5 per cent of the total thymines are dimerized. In both cases (splitting and dimer formation), the formation of electron donor-acceptor complexes between either dimers or two adjacent thymine monomers, and excited indole rings, could be an intermediate step in the reactions. Thymine-dimer splitting would then result from an electron transfer reaction involving the indole ring as the electron donor. These results are discussed with respect to the mechanism of action of the photoreactivating enzyme.     

ULTRAVIOLET RADIATION INDUCED CHANGES IN MACROPHAGE ACTIVITY

Abstract— The effect of ultraviolet (UV) radiation on macrophage activity was examined. Thioglycollate-stimulated peritoneal exudate cells were collected from adult C57BL/6 mice. Ninety-five per cent of the cells adhering to plastic petri dishes were macrophages as determined by the presence of a non-specific esterase. Adherent cells were exposed to UV radiation of 0.5-13.2 J/m². Viability and phagocytosis were measured at 0, 24, 48, 72 and 96 h after exposure. A statistically significant UV exposure-dependent decrease in macrophage viability and phagocytic capacity was observed. Macrophage viability and phagocytosis also decreased as a function of time after exposure to UV radiation.     

PHOTODYNAMIC INHIBITION OF ESCHERICHIA COLI DNA POLYMERASE I BY 8-METHOXYPSORALEN PLUS NEAR ULTRAVIOLET IRRADIATION

Abstract— Morphological abnormality due to the UV irradiation of sperm and its modification by photoreactivation (PR) were studied in the sea urchin, Hemicentrotus pukherrimus. When sperm was UV-irradiated and allowed to fertilize unirradiated eggs, the effect of the UV was manifested as an abnormal morphology of embryos in the gastrula or later stages. The UV-induced morphological abnormality was prevented by photoreactivation when the fertilized eggs were illuminated with visible light. In the experiments on a stage-dependent change of PR effectiveness, it was found that an illumination sufficed to effect a nearly complete PR when applied up to the onset of the first DNA synthetic phase, while the PR effectiveness declined thereafter. Illumination after the completion of DNA synthesis had little effect for PR.