WAVELENGTH DEPENDENCE FOR AMT CROSSLINKING OF pBR322 DNA

Abstract The wavelength dependence for 4'aminomethyl-4,5',8-trimethylpsoralen crosslinking of a linearized plasmid DNA (pBR322) by narrow band UV-A light (298–382 nm) has been determined. Maximal levels of crosslinking occurred with light in the 322–346 nm range. Crosslinks were shown to be photoreversible by shorter wavelength photons (298 and 310 nm). The correlation between the wavelength dependence for crosslink formation and the optimal wavelength for most psoralen action spectra further supports the notion that crosslinks are the major lesion responsible for the effectiveness of psoralen plus ultraviolet A therapies.     

α-TERTHIENYL PHOTOSENSITIZES DAMAGE TO pBR322 DNA

alpha-Terthienyl photosensitizes single strand breaks in pBR322 DNA. Almost identical results were observed under oxygen and under argon. In the presence of oxygen, this DNA nicking was enhanced by histidine and was not affected by superoxide dismutase, catalase, or the antioxidant BHT. Although chemical damage to DNA treated with alpha-terthienyl plus near-UV was clearly demonstrated in vitro, transformation in E. coli with this damaged pBR322 DNA still took place. Likewise, Haemophilus influenzae DNA transforming activity was not significantly decreased by photosensitization with alpha-terthienyl.     

Effects of tritiated water on the DNA of plasmid pBR 322

In an attempt to shed light on the influence of tritiated water for DNA we have investigated the damage with a simple plasmid DNA, pBR 322. The survival of covalently closed circular (CCC DNA) form was directly followed by agarose of gel electrophoresis. It was found that the survival percentage of DNA in tritiated water was observed almost the same as the irradiation of X-rays at the same absorbed doses. For the irradiation of gamma-rays, on the other hand, the decay rate was larger than those of both tritiated water and X-rays. The yields percentage of the broken pieces of DNA in tritiated water, X-rays and gamma-rays were found to be 43, 38 and 33% at 10(4) rad of the absorbed dose. It may be considered that the degree of danger in tritiated water is quite larger than of gamma-rays. It was also found that the dose rate effect was not observed in the case of tritiated water, X-rays and gamma-rays irradiation.     

PHOTOSENSITIZATION OF SINGLE-STRAND BREAKS IN pBR322 DNA BY ROSE BENGAL

Rose bengal photosensitized the formation of frank single-strand breaks (SSBs) in double-stranded, supercoiled pBR322 DNA as measured by neutral agarose electrophoresis. The yield of SSBs followed first order kinetics with respect to light fluence and dye concentration. The efficiency of cleavage was more than 20 times greater in an argon atmosphere than in an oxygen atmosphere. The quantum yield in an air atmosphere was 1.7 (+/- 0.3) X 10(-8). Sodium azide quenched the cleavage more efficiently in an oxygen atmosphere than when the oxygen concentration was reduced. Isopropanol and mannitol were poor quenchers; ribose-5-phosphate and guanosine-5'-monophosphate did not quench the cleavage. Substituting D2O for H2O increased the yield of SSBs in both oxygen and oxygen-depleted atmospheres. The results are consistent with initiation of cleavage by reaction of the triplet state of rose bengal (or a radical derived from it) with DNA. In the presence of oxygen, an additional mechanism is introduced.     

Photosensitized cleavage and cross-linking of pBR322 DNA with khellin and visnagin

The naturally occuring furanochromones khellin and visnagin have received considerable attention, largely because of their vasodilatory properties and of their ability (particularly that of khellin) to induce skin pigmentation upon ultraviolet light treatment of patients suffering from vitiligo. There are conflicting statements in the literature on whether or not they are capable of cross-linking DNA photochemically. Supercoiled and linear pBR322 DNA was used to probe this reaction. The results showed that both khellin and, to a greater extent, visnagin photosensitized DNA cross-linking. In addition, both photosensitizers induced extensive DNA cleavage.     

SKIN CANCER AND ULTRAVIOLET RADIATION

Abstract. A new model is presented for the calculation of the increased incidence of non-melanoma skin cancer in Caucasians resulting from ozone reduction. The model postulates that the probability of first incidence of such skin cancer is distributed log-normally as a function of total accumulated lifetime dose of harmful ultraviolet radiation. The effect on skin cancer incidence of an increase in harmful ultraviolet radiation due to ozone reduction can then be calculated directly from the extent to which each individual's lifetime accumulated dose is thereby increased. The result of such a perturbation, on average, would be to cause skin cancer to appear at a slightly earlier age. Since skin cancer is predominantly a disease of the elderly, this shift to younger ages has the effect, when integrated over the entire population, of increasing the overall total incidence of skin cancer.     

A CLIMATOLOGY OF SUNBURNING ULTRAVIOLET RADIATION

Abstract— Data are presented from 14 sites where continuous measurements of the sun's shortest ultraviolet radiation reaching the earth's surface have been made for four or more years. Average daily dose per month and its variability from year to year is shown for each station. Some of the many influences affecting these measurements can be discerned by station intercomparisons. No consistent long term change in solar UV-B radiation reaching the ground is evident.     

LONGWAVE ULTRAVIOLET RADIATION (UVA)-INDUCED ALTERATION OF EPIDERMAL DNA SYNTHESIS

Abstract— Longwave ultraviolet radiation(UVA–320–400nm) is known to induce inflammation, pigmentation and tumor production in mammalian skin. The mechanisms by which such radiation induces these biologic phenomena are poorly defined. In an effort to broaden our knowledge in this area, we examined the effect of UVA on DNA biosynthesis in Hartley strain albino guinea pig skin. The animals were irradiated with selected doses of solar simulated UVA, and DNA was assayed by [³H]thymidine incorporation into epidermal DNA by autoradiography. These studies revealed that UVA inhibited DNA synthesis in a dose dependent manner between 40 and 80 J cm^-2 at 3 h post-irradiation. This inhibition was followed by a stimulation of synthesis at 5 h and a second inhibition/ stimulation at 8 and 24 h, respectively. Although the mechanism of alteration is undefined, our data suggest that UVA has profound effects on DNA biosynthesis in mammalian epidermis.     

MOLECULAR MECHANISMS OF ULTRAVIOLET RADIATION CARCINOGENESIS

UV radiation is a potent DNA damaging agent and a known inducer of skin cancer in experimental animals. There is excellent scientific evidence to indicate that most non-melanoma human skin cancers are induced by repeated exposure to sunlight. UV radiation is unique in that it induces DNA damage that differs from the lesions induced by any other carcinogen. The prevalence of skin cancer on sun-exposed body sites in individuals with the inherited disorder XP suggests that defective repair of UV-induced DNA damage can lead to cancer induction. Carcinogenesis in the skin, as elsewhere, is a multistep process in which a series of genetic and epigenetic events leads to the emergence of a clone of cells that have escaped normal growth control mechanisms. The principal candidates that are involved in these events are oncogenes and tumor suppressor genes. Oncogenes display a positive effect on transformation, whereas tumor suppressor genes have an essentially negative effect, blocking transformation. Activated ras oncogenes have been identified in human skin cancers. In most cases, the mutations in the ras oncogenes have been localized to pyrimidine-rich sequences, which indicates that these sites are probably the targets for UV-induced DNA damage and subsequent mutation and transformation. The finding that activation of ras oncogenes in benign and self-regressing keratoacanthomas in both humans and in animals indicates that they play a role in the early stages of carcinogenesis (Corominas et al., 1989; Kumar et al., 1990). Since cancers do not arise immediately after exposure to physical or chemical carcinogens, ras oncogenes must remain latent for long periods of time. Tumor growth and progression into the more malignant stages may require additional events involving activation of other oncogenes or deletion of growth suppressor genes. In addition, amplification of proto-oncogenes or other genes may also be involved in tumor induction or progression. In contrast to the few studies that implicate the involvement of oncogenes in UV carcinogenesis, the role of tumor suppressor genes in UV carcinogenesis is unknown. Since cancer-prone individuals, particularly XP patients, lack one or more repair pathways, one can speculate that DNA repair enzymes would confer susceptibility to both spontaneous and environmentally induced cancers. Another potential candidate that can function as a tumor suppressor gene is the normal c-Ha-ras gene. Spandidos and Wilkie (1988) have shown that the normal c-Ha-ras gene can suppress transformation induced by the mutated ras gene.(ABSTRACT TRUNCATED AT 400 WORDS)     

Protection of plasmid pBR322 DNA by flavonoids against single-strand breaks induced by singlet molecular oxygen

Flavonoids, the dominant colouring pigments of plants, as well as the related polyphenol tannic acid significantly inhibit single-strand breaks in plasmid pBR322 DNA induced by singlet molecular oxygen (¹O₂). This reactive species of oxygen was generated in an aqueous buffer system by the thermal dissociation of the endoperoxide of 3,3′-(1,4-naphthylene)dipropionate. Among the antioxidants examined, myricetin showed the highest protective ability, followed by tannic acid, (+) catechin, rutin, fisetin, luteolin and apigenin, when the inhibitory abilities were compared at 90 min after incubation. The protective abilities of these compounds were both time and concentration dependent. At equimolar concentrations (100 μM) the antioxidant effect of myricetin was better than that of other known antioxidants such as lipoate, -tocopherol and β-carotene. Data, when analysed in relation to the structures of various compounds, showed a rough correlation with protective abilities. Owing to the abundance of these compounds in our normal diet, they may play significant roles in preventing oxidative damage resulting from potentially deleterious ¹O₂.     

PYRIMIDINE DIMERS INDUCED IN ESCHERICHIA COLI DNA BY ULTRAVIOLET RADIATION PRESENT IN SUNLIGHT

Abstract— Escherichia coli DNA was irradiated with various wavelengths of monochromatic UV light from 254 to 320 nm, and the relative yields of the different cyclobutane pyrimidine dimers determined. Cytosine–thymine dimers (C < > T) were more frequent than thymine dimers (T < > T) at low fluences of 300 and 313 nm light, whereas the reverse was true at either longer or shorter wavelengths. Thus, in the solar UV range deemed responsible for skin cancer (i.e. 295–315 nm), C < > T are probably more important than T < > T.     

ULTRAVIOLET LIGHT IRRADIATION OF DEFINED-SEQUENCE DNA UNDER CONDITIONS OF CHEMICAL PHOTOSENSITIZATION

Abstract— The formation of cyclobutane pyrimidine dimers and UV light-induced (6-4) products was examined under conditions of triplet state photosensitization. DNA fragments of defined sequence were irradiated with 313 nm light in the presence of either acetone qr silver ion. UV irradiation in the presence of both silver ion and acetone enhanced the formation of TT cyclobutane dimers, yet no (6-4) photoproducts were formed at appreciable levels. When photoproduct formation was also measured in pyrimidine dinucleotides, only cyclobutane dimers were formed when the dinucleotides were exposed to 313 nm light in the presence of photosensitizer. The relative distribution of each type of cyclobutane dimer formed was compared for DNA fragments that were irradiated with 254, 313, or 313 nm UV light in the presence of acetone. The dimer distribution for DNA irradiated with 254 and 313 nm UV light were very similar, whereas the distribution for DNA irradiated with 313 nm light in the presence of acetone favored TT dimers. Alkaline labile lesions at guanine sites were also seen when DNA was irradiated with 313 nm light in the presence of acetone.     

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.     

SOLAR ULTRAVIOLET RADIATION AT THE EARTH'S SURFACE

The biologically effective ultraviolet irradiance at the earth's surface varies with the elevation of the sun, the atmospheric ozone amount, and with the abundance of scatterers and absorbers of natural and anthropogenic origin. Taken alone, the reported decrease in column ozone over the Northern Hemisphere between 1969 and 1986 implies an increase in erythemal irradiance at the ground of four percent or less during summer. However, an increase in tropospheric absorption, arising from polluting gases or particulates over localized areas, could more than offset the predicted enhancement in radiation. Any such extra absorption is likely to be highly regional in nature and does not imply that a decrease in erythemal radiation has occurred on a global basis. The Antarctic 'ozone hole' represents a special case in which a portion of the earth has experienced ultraviolet radiation levels during spring that are far in excess of those which prevailed prior to the present decade.     

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.     

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.     

MIDDLE ULTRAVIOLET RADIATION REACHING THE OCEAN SURFACE*

Abstract— Direct measurements of the downwelling spectral irradiance in the middle UV (280–340 nm) have been made for a range of solar zenith angles (20°-70°). These measurements were made for a marine atmosphere at equatorial latitudes. We fit these data to two semi-empirical analytic representations, from which quantitative calculations of spectral irradiance in the middle UV incident at the ocean surface can be made. The formulae accommodate variation in wavelength, solar zenith angle, ozone thickness, aerosol thickness and surface albedo. Our purpose is to provide marine photobiologists and photochemists with a basis for estimating middle UV radiation levels reaching the ocean surface and the approximate changes caused by manmade alterations of the ozone layer.     

DNA NICKING BY ULTRAVIOLET RADIATION IS ENHANCED IN THE PRESENCE OF IRON and OF OXYGEN

Double-stranded covalently closed circular supercoiled DNA (ccc DNA) from plasmid pUK 9 was irradiated in vitro at denned wavelengths in the UV region (290, 313 and 365 nm). The nicking was monitored by electrophoresis on agarose gels, ethidium staining and densitometric quantitation of supercoiled and relaxed moieties. At the explored wavelengths, the dose required for introducing one nick per million phosphodiester bonds diminishes with increased concentration of added ferric iron, whereas the effect of cupric iron is practically negligible. Adding metal chelators or bubbling argon prior to the irradiation results in a dramatic increase in the dose required for introducing one nick per million phosphodiester bonds. Taken together, these results seem to indicate that iron and oxygen play a role as cofactors in the UV-induced nicking of ccc DNA in vitro.