THE ACTION SPECTRUM OF AN IN VITRO DNA PHOTOREACTIVATION SYSTEM

Abstract— The wavelength-dependence of in vitro photoreactivation of transforming DNA by yeast extract has been determined. There is an intensity-dependent lag at the beginning of the biological reaction. There is a similar lag in the splitting of thymine dimers by the yeast extract in the light, a process known to account for most or all of the increase in transforming activity of photoreactivated DNA. The most efficient wavelengths for photoreactivation are around 3550 and 3850 Å. Although the action spectrum is not very similar to flavin absorption, riboflavin at very low concentration inhibits photoreactivation, as it also inhibits a number of flavoenzymes, suggesting that the photoreactivating enzyme might be a flavoprotein.     

PHOTOREACTIVATION OF Halobacterium halobium: ACTION SPECTRUM AND ROLE OF PIGMENTATION

Abstract— An action spectrum for photoreactivation was measured with Halobacterium halobium R₁m₁ to prove a role of carotenoid pigments in photoreactivation of the bacteria. The action spectrum obtained showed a main peak at 435 nm and a minor peak at about 325 nm. The action spectrum was similar to that of Streptomyces pigment (Eker et al. , 1981) suggesting that the chromophore of the photoreactivating enzyme in Halobacterium halobium is 8-OH-5-deazaflavin. The minor peak may be due to photochemical cleavage of a pyrimidine6–4 hetero adduct. The result indicates that carotenoid pigments do not play a positive role in enhancing photoreactivation. This was confirmed also by comparing the efficiency of photoreactivation at 465 nm among three strains of Halobacterium halobium having different carotenoid pigments; R₁m₁. R₁ and W5002–1.     

ACTION SPECTRUM FOR PHOTOREACTIVATION OF ULTRAVIOLET-IRRADIATED MARSUPIAL CELLS IN TISSUE CULTURE

Abstract— An action spectrum has been determined for photoreactivation of the PtK-2 mammalian cell line of Potorous tridactylus . Maximum effectiveness occurs around 366 nm, but appreciable photo-reactivation occurs at wavelengths as long as 546 nm.     

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.     

PHOTOREACTIVATING ENZYME FROM Streptomyces griseus—VI. ACTION SPECTRUM AND KINETICS OF PHOTOREACTIVATION

Abstract— A high resolution action spectrum for photoreactivation was determined using purified photoreactivating enzyme from Streptomyces griseus. Conversion of pyrimidine dimers in UV-irradiated DNA, the substrate for photoreactivating enzyme, was measured with a Haemophilus influenzae transformation assay. A high similarity was found between action spectrum (max. at 445 nm) and the long wavelength absorption band (max. at 443 nm)of photoreactivating enzyme. In addition to the400–470 nm region considerable photoreactivation was found with wavelengths between 280 and 320 nm. No evidence was obtained for the presence of nonenzymatic photoreactivation. Comparison of in vitro and in vivo action spectra revealed that the sharp peak at 313 nm found in vivo is probably the result of counteracting photoreactivation and inactivation effects. Comparison of the action spectrum with the absorption spectrum of 8-hydroxy-10-methyl-5-deazaisoalloxazine in an aprotic dipolar solvent (which serves as a model for the 8-hydroxy-5-deazaflavin chromophore in photoreactivating enzyme) indicates the possible presence of other chromophore(s) involved in the photorepair process. From kinetic measurements and flash experiments values were obtained for the rate constants of the photoreactivation reaction. The quantum yield of photoreactivation was estimated to be approximately 1.     

ACTION SPECTRUM FOR PHOTOREACTIVATION OF ULTRAVIOLET-INDUCED MORPHOLOGICAL ABNORMALITY IN SEA URCHIN EGGS

Abstract An action spectrum was obtained for photoreactivation (PR) of morphological abnormality arising from ultraviolet (UV)-irradiation of sea urchin sperm. The wavelength dependence of PR was measured by the restoration of the formation of normal pluteus larvae after the exposure of fertilized eggs to various fluences of monochromatic PR light (313 to 500 nm). The PR action spectrum showed a maximum around 365 nm and a secondary peak somewhere above 400 nm. High PR activity beyond 400 nm wavelengths may reflect an advantageous or adaptational ability to cope with harmful effects of solar UV radiation.     

OVERLAPPING ACTION OF HOSTCELL REACTIVATION AND PHOTOREACTIVATION IN BACTERIA

Abstract— The photoreactivation rate of U.V. irradiated phages is decreased in u.v. irradiated bacteria. In contrast, the normal photoreactivation rate is observed if the irradiated bacteria are photoreactivated before phage infection. The decrease of the photoreactivation ratc is understood as a competing effect of the u.v. lesions in the bacterial nucleic acids for the photoreactivation enzyme. This competitive inhibition can be diminished not only by photoreactivation of the bacteria before phage infection but also by hostcell reactivation of the u.v. lesions in the bacterium. The results provide strong evidence that hostcell reactivation and photoreactivation revert the same u.v. photoproducts in bacterial nucleic acids. The experiments show that the hostcell reactivation enzyme is not induced by phage infection or by irradiation, but is normally present in the bacterial cell.     

INDUCTION OF phr GENE EXPRESSION BY PYRIMIDINE DIMERS IN Escherichia coli

The photoreactivating enzyme (PRE) is concerned with mainly two kinds of light wavelength. The PRE splits UVC (254 nm)-induced pyrimidine dimer by absorbing UVA (320–380 nm) or visible light in its chromophore. The present paper demonstrates that the phr gene expression was efficiently induced in an excision defective strain (uvrA∼) after irradiation by UVC and UVB (290-320 nm), but not by UVA and visible light. In addition, the induced activity was significantly depressed by irradiation with UVA and visible light. Therefore we conclude that the phr gene expression can be induced by pyrimidine dimers.     

INDUCTION OF UMUC+ GENE EXPRESSION IN Escherichia coli IRRADIATED BY NEAR ULTRAVIOLET LIGHT

Abstract— The induction of umu + gene expression caused by irradiation with near ultraviolet light (BLB; black light blue) was studied in Escherichia coli K-12 strains with special reference to the effects of SOS repair deficiencies. The umuC + gene expression was measured as the enzymic activity of (J-galactosidase which is regulated by the promoter of the umuC + operon carried in a plasmid DNA carrying a promoter of umuC* operon, a umuD + gene and a umuC +- lacZ + gene fusion. A high induction of the umuC + gene expression was observed in the uvrA cells in the case of BLB or UV irradiation as compared with the parental wild-type cells. Caffeine inhibited the induction of the umuC* gene expression due to BLB or UV irradiation in both strains. There was very little induction in lexA and recA mutants. In contrast with UV irradiation, there was no killing of cells by BLB irradiation in any strain (wild, uvrA, lexA and recA). Possible implications of the present experimental results were discussed.     

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.     

PHOTOREACTIVATION OF ULTRAVIOLET RADIATION DAMAGE IN DARK REPAIR DEFICIENT PHR MUTANTS OF Escherichia coli K-12

There is uncertainty in the literature concerning the genetic control of photoreactivation in E. coli. Two genetic loci, phrA and phrB have been proposed, and two photolyase molecules have been isolated, but in vivo evidence for the activity of the former is controversial. We have studied photoreactivation after 254 nm UV in a dark-repair-deficient phrB mutant and in a strain deleted at the proposed phrA locus. We show apparent photoenzymatic repair in the phrB mutant, which is abolished when the mutation is transduced into the proposed phrA deletion mutant. We conclude that there is a gene in the region of the proposed phrA locus which affects photoenzymatic repair.     

AN ACTION SPECTRUM FOR CELL KILLING AND PYRIMIDINE DIMER FORMATION IN CHINESE HAMSTER V-79 CELLS

We have determined action spectra for pyrimidine dimer formation and loss of colony-forming ability in Chinese Hamster V-79 cells and have found a very strong correlation between the two. These data are consistent with the notion that damage to DNA is the principle cause of cell death and that the most important type of damage is the pyrimidine dimer. While the shape of the V-79 spectra mimics that of action spectra for bacteria. phage, and purified DNA, V-79 cells are about twice as sensitive to radiation at long wavelengths, relative to the sensitivity at 265 nm. However, if the action spectra are normalized to 297 nm. a wavelength included in the solar spectrum, the two sets of action spectra would coincide at wavelengths relevant to human skin-cancer. Thus an action spectrum based on microorganisms should be adequate for extrapolation to humans in terms of risk due to ozone depleteion.     

CAROTENOIDS OF Erwinia herbicola AND AN Escherichia coli HB101 STRAIN CARRYING THE Erwinia herbicola CAROTENOID GENE CLUSTER

Carotenoid pigments of Erwinia herbicola and a transformed strain of Escherichia coli carrying the carotenoid biosynthesis gene cluster of E. herbicola have been analyzed. Both organisms are capable of making essentially the same carotenoids, indicating that all of the genes required for the biosynthesis of the wild type E. herbicola carotenoids have been transformed intact into E. coli. The major products in both species of bacteria are beta-cryptoxanthin glucoside, zeaxanthin monoglucoside and zeaxanthin diglucoside. These compounds are the first example of secondary, non-allylic carotenoid glucosides. The absolute configuration 3R,3'R for zeaxanthin diglucoside was determined from its circular dichroism spectrum. Both species of bacteria also accumulate small amounts of hydrocarbon carotenes with similar cis/trans isomerization states.     

THE EXPRESSION OF ENTEROTOXIN A~-B~+ GENE OF V. cholerae IN E. coli

The cloning in E. coli of a cholerae toxin gene that is A~-B~+ has been successfully constructed by using DNA recombinant techniques. E. coli cells carrying the recombinant plasmid pMM-CTB have been shown to produce a large amount of CTB subunits which are secreted as extracellular proteins.     

SYNERGISTIC LETHALITY OF PHAGE T7 BY NEAR-UV RADIATION AND HYDROGEN PEROXIDE: AN ACTION SPECTRUM

Abstract— Ozonation of valerophenone oxime o-methyl ether (4) produced a stereoisomeric mixture of crystalline dimeric valerophenone peroxides, 5a and 5b . N-n-butyl-N-methoxybenzamide (6) and N-methoxy-N-phenylvaleramide (7) along with valerophenone (1). Thermolysis of the higher melting peroxide 5a at 170–180°C, where a chemiluminescence was visible from added perylene. gave 1 and butyl benzoate (8) in addition to small amounts of the Norrish Type 11 products of 1. i.e. acetophenone (2) and cis- and trans- 2-methyl-1-phenylcyclobutanols. Biacetyl-sensitized photolysis of 5a in benzene yielded 2 in much higher yield in addition to 1, 8, and biphenyl. These results suggest that the triplet excited state of 1 is formed by the decomposition of 1 in low yield in thermolysis and in much higher yield in sensitized photolysis. although some of the Type II products may not arise from the triplet valerophenone.     

CLONING IN Yersinia enterocolitica OF K99 ANTIGEN GENE FROM Escherichia coli

A recombinant plasmid pFS239 containing the geoe coding for K99 antigen of Escherichia coli and wide-host-range plasmid pKT230 has been cloned in E. coli C600. pFS239 has been transferred to Yersinia enterocolitica strains D29, L15 and L15 (pYV15) through triparental mating. In Y. enterocolitica transconjugants the expression of VW antigens and calcium dependence which represent the propertics associated with the virulence plastmid of Y. enterocolitica remains unchanged.     

ACTION SPECTRUM AND THRESHOLD SENSITIVITY OF ENTRAINMENT OF ORCADIAN RUNNING ACTIVITY IN THE COCKROACH PERIPLANETA AMERICANA

Abstract— The interaction between the compound eye and the circadian timing system for running activity in the cockroach, Periplaneta americana , has been investigated by measuring the action spectrum for entrainment of such behavior by imposed photic stimuli. Test wavelengths were selected which spanned the spectral range of the dichromatic retina of this insect and intensities of such lights for which half of a population of animals failed to be entrained (threshold) were determined. Stimuli were presented either with a 12:12 light–dark regime or for 12h/day on a continuous background of orange light. The latter procedure altered the balance of sensitivity in the two groups of color receptors in the eye. A comparison of the resulting action spectra and the spectral sensitivities of receptors and visual interneurons measured under similar conditions suggest that the entrainment mechanism is dominated by the receptor group most sensitive to long wavelength light. Furthermore, the eye-clock mechanism shows an extraordinarily high sensitivity to such stimuli. We estimate that a mean flux of about 5 photons/eye/s is sufficient to entrain the behavior. The implications of these results are discussed.     

LIGHT-INDUCED SYNTHESIS OF ANTHOCYANIN IN CARROT CELLS IN SUSPENSION—IV. THE ACTION SPECTRUM

Abstract— Using carrot cell suspension in 2,4-dichlorophenoxyacetic acid (2,4-D)-depleted culture medium, fluence-response curves for the formation of anthocyanin were determined at various wavelengths from 250 to 800 nm. In the fluence-response curves at wavelengths between 260 and 330 nm, the response showed a sharp fluence-dependent increase after the fluence exceeded threshold level at the respective wavelength. Such a sharp increase in response was not observed by light at 450 nm or longer wavelengths, although the response obtained by higher fluence of such light was always higher than that in the dark control. Action spectra determined at the sharp increasing phase of the response showed the single peak at 280 nm which equals the absorption maximum of UV-B photoreceptor.
Although red (R)-light alone had a minor effect on anthocyanin accumulation, it modulated the action of UV-B light. That is, when carrot cells were irradiated with R-light either before or after UV-B irradiation, anthocyanin formation was greatly enhanced above the level enhanced by UV-B light alone. The most effective wavelength for this enhancement was 660 nm. The effect of R-light on the anthocyanin formation of the UV-B irradiated cells was reversed by immediately following it with far-red light, suggesting the involvement of phytochrome in the R-effect.     

AN ACTION SPECTRUM FOR ULTRAVIOLET INDUCED ELASTOSIS IN HAIRLESS MICE: QUANTIFICATION OF ELASTOSIS BY IMAGE ANALYSIS

To determine an action spectrum for ultraviolet (UV)-induced elastosis, four groups of 24 albino hairless mice each were exposed to four different spectra emitted by a xenon arc solar simulator fitted with cut-off filters (Schott WG 320, 335, 345, and 360). These filters progressively removed more of the shorter wavelengths until, in the final spectrum, only long wavelength UVA (greater than 335 nm) remained. Exposures continued up to 62 weeks. A fifth group of mice served as controls. Skin biopsies were taken at pre-determined dose points and were processed for light microscopy. Elastosis was quantified by computerized image analysis, yielding dose-response curves for each spectrum. The total energy required for a 50% increase in elastic tissue compared to controls was determined graphically for each spectrum. These were: WG 320, 65 J/cm2; WG 335, 865 J/cm2; WG 345, 1230 J/cm2; and WG 360, 2000 J/cm2. Our results were tested against published action spectra for erythema, photocarcinogenesis and elastosis. The erythema spectrum was the most predictive for elastosis except that the longer UVA wavelengths were less effective for elastosis than for erythema. Solar simulating radiation (WG 320 filter) with its UVB component was the most effective in inducing elastosis. Full spectrum UVA (WG 345) required 20 times more energy while long wavelength UVA (WG 360) required 30 times more energy to induce equivalent elastosis.