MODIFIED ACTION SPECTRA OF PHOTOGEOTROPIC EQUILIBRIUM IN Phycomyces blakesleeanus MUTANTS WITH DEFECTS IN GENES madA, madB, madC, and madH

Abstract— Action spectra of photogeotropic equilibrium were measured for behavioral mutants of Phycomyces blakesleeanus with defects in the genes madB, madC and madH as well as for a double mutant defective in the genes madA and madC. The action spectra of strains C109 (madB), LI (madC) and L52 (madA madC) all lack the broad near-ultraviolet peak which extends from 347 to 386 nm in the wild type; the peaks at 414 and 491 nm are also missing in these mutants. The double mutant L52 (madA madC) shows a novel broad peak at 477 nm; the relative quantum effectiveness of L52 at 477 nm is 10 times higher than in LI (madC119). These properties of the double mutant L52 (madA madC) suggest steric interaction of the madA and the madC gene products in the photoreceptor complex. For the hypertropic mutant L84 (madH) the action spectrum and absolute sensitivity are similar to those for wild type. These results confirm and extend previous findings that multiple photoreceptors are mediating phototropism in P. blakesleeanus.     

ACTION SPECTRA OF PHOTOGEOTROPIC EQUILIBRIUM IN Phycomyces WILD TYPE AND THREE BEHAVIORAL MUTANTS

Photogeotropic equilibrium action spectra in the range from 301 to 740 nm were made for Phycomyces wild type and the three behavioral mutants C47 ( madA35 ), C109 ( madBlOl ) and LI (madCIIQ) , all of which have a raised phototropic threshold. In addition to two broad peaks at 365 and 455 nm, typical for flavins, the wild type action spectrum shows three novel peaks, which have not been observed previously. These peaks are located at 414, 491 and 650 nm. The 650 nm peak has a relative quantum efficiency of 3 × 10⁻⁸ compared to the peak at 414 nm. The wavelength dependent shapes of the fluence-response curves of the bending angle and the aiming error angle indicate more than one receptor pigment for phototropism. The shape of the action spectrum of C47 is basically unaltered in comparison to wild type. C109 and LI show substantial differences from the wild type. In the near UV two small peaks at 334 and 365 nm appear; the 414 and 491 nm peaks present in wild type and C47 are missing and two new peaks at 529 nm (not well resolved in C109) and 567 nm are found. None of the three mad mutations affects the 650 nm peak. A model of the sensory transduction chain is presented, which incorporates these and other known features.     

ACTION SPECTRA OF CATION EFFECTS ON THE FLUORESCENCE POLARIZATION AND INTENSITY IN THYLAKOIDS AT ROOM TEMPERATURE

Abstract— The degree of polarization of chlorophyll- a (Chl- a ) fluorescence is known to monitor the extent of excitation migration and/or the orientation of the photosynthetic pigment molecules. We report here the effects of cations, at room temperature, on the degree of polarization of Chl- a fluorescence, and fluorescence intensity in thylakoids as a function of excitation wavelength. Observations of maxima at 650 and 675 nm in the cation-induced changes in the excitation spectrum for fluorescence at 730 and 762 nm, and, in the action spectra for the depolarization of fluorescence lead us to suggest that the regulation of the initial distribution of excitation to photosystem II involves the better coupling of Chl- b and- a in the light harvesting complex with Chl- a in the reaction center II complex.     

WAVELENGTH DEPENDENCE OF SINGLET OXYGEN MECHANISM IN ACRIDINE ORANGE-SENSITIZED PHOTODYNAMIC ACTION IN YEAST CELLS: EXPERIMENTS WITH 470 NM

Abstract— The singlet oxygen mechanism was evaluated in terms of acridine orange-sensitized induction of gene conversion in Saccharomyces at 470 nm and by using a concentration dependent protective action of added N;. The singlet oxygen mechanism accounted for 96% of the total photodynamic efTect. This value is to be contrasted with 76% previously observed for 510 nm illumination.     

ACTION SPECTRUM FOR SUBLIMINAL LIGHT CONTROL OF ADAPTATION IN Phycomyces PHOTOTROPISM

Abstract -Adaptation processes enable phototropism and other blue light responses of Phycomyces to operate over a 10-decade range of Ruencc rate. Phototropic latency, used routinely to monitor the kinetics of sensitivity recovery after a step down in fluence rate, can be shortened by application of dim light for 35 min during the early part of the latency period. This light is termed subliminal , because it does not elicit phototropism under these experimental conditions; rather, it exerts its influence on the underlying adaptation kinetics. Fluence rate-response data for this latency reduction, obtained at 17 wavelengths of subliminal light from 347 to 742 nm, showed a variety of shapes that could be fit by zero, one, or two sigmoidal components, plus a constant term. At most wavelengths, the fluence-rate threshold for latency reduction by subliminal light tended to be well below the absolute threshold for phototropism, indicating that this effect is highly sensitive. An action spectrum for the sensitivity of the subliminal light effect, derived from the fluence rate-response curves, shows major peaks around 400 and 500 nm and a broad band from 570 to 670 nm, followed by a steep absorption edge. The sensitivity in the near ultraviolet region is relatively very low. The magnitude of the latency reduction also depends strongly on wavelength with a maximum at about 450 nm. The Huence-rate response data and the action spectrum–which is markedly different from that for phototropism and other blue-light responses of Phycornyces – indicate the participation of multiple pigments, or pigment states, in the photocontrol of adaptation.     

ACTION SPECTRA FOR THE IRIDOPHORE LIGHT RESPONSE IN THE NEON TETRA

Abstract The iridophores of some fishes such as the neon tetra ( Paracheirodon innesi ) are composed of alternating layers of guanine and cytoplasm. In the dark adapted state, the guanine layers are close together and reflect violet light. After illumination these layers separate and the iridophores reflect green light. The spacing change results from a direct action of light. Dose-response curves show that more than one light sensitive mechanism are involved, but that at threshold the action spectrum fits a 461 nm porphyropsin absorbance curve.     

WAVELENGTH DEPENDENCE FOR THE INACTIVATION OF ATP IN THE VACUUM-ULTRAVIOLET REGION ABOVE 140 nm

Radiation effects were investigated on the activity and the structure of adenosine triphosphate in the wavelength range from 140 nm to 260 nm, using monochromatized synchrotron radiation from the INS-SOR storage ring. The sample was irradiated as a thin film in vacuum. The activity of adenosine triphosphate decreased sharply below 180 nm as judged by the luminescence in the luciferin-luciferase assay. From the exponential decay of function, the cross-section for inactivation was calculated to be of the order of 10^-21 m²/photon in the range from 140 to 170 nm. No decrease was detected at wavelengths of 190 nm and above. The calculated quantum yield increased as the wavelength became shorter and reached to 0.20 at 150 nm. The release of adenine at 160 nm-irradiation was detected by thin layer chromatography; no adenosine diphosphate or adenosine monophosphate occurred. Only a trace of adenine was found after 190 nm-irradiation. These results indicate that the broad absorption peak for higher excitations attributable to the base moiety around 190 nm does not cause both structural and functional changes, while the absorption by the sugar-phosphate group produces the rupture of N -glycosidic bond, and probably leads to the loss of function.     

ULTRAVIOLET ACTION SPECTRA FOR PHOTOBIOLOGICAL EFFECTS IN CULTURED HUMAN LENS EPITHELIAL CELLS

Abstract— The action spectrum for cell killing by UV radiation in human lens epithelial (HLE) cells is not known. Here we report the action spectrum in the 297–365 nm region in cultured HLE cells with an extended lifespan (HLE B-3 cells) and define their usefulness as a model system for photobiological studies. Cells were irradiated with monochromatic radiation at 297, 302, 313, 325, 334 and 365 nm. Cell survival was determined using a clonogenic assay. Analysis of survival curves showed that radiation at 297 nm was six times more effective in cell killing than 302 nm radiation; 297 nm radiation was more than 260, 590, 1400 and 3000 times as effective in cell killing as 313, 325, 334 and 365 nm radiation, respectively. The action spectrum was similar in shape to that for other human epithelial cell lines and rabbit lens epithelial cells. The effect of UV radiation on crystallin synthesis was also determined at different wavelengths. To determine whether exposure to UV radiation affects the synthesis of β-crystallin, cells were exposed to sublethal fluences of UV radiation at 302 and 313 nm, labeled with [³⁵S]methionine and the newly synthesized βY-crystallin was analyzed by immunoprecipitation and western blotting using an antibody to β-crystallin. The results show a decrease in crystallin synthesis in HLE cells irradiated at 302 and 313 nm at fluences causing low cytotoxicity. The effect of radiation on membrane perturbation was determined by measuring enhancement of synthesis of prostaglandin E₂ (PGE₂). Synthesis of PGE₂ occurs at all UV wavelengths tested in the 297–365 nm region. The slope of the PGE₂ response curves was higher than that of cell killing curves in cultured HLE cells. These data show that cultured HLE cells with extended lifespan are a suitable system for investigating photobiological responses of cells to UV radiation.     

ACTION SPECTRA FOR ACCUMULATION OF INORGANIC CARBON IN THE CYANOBACTERIUM, Anabaena variabilis

Abstract— Action spectra for accumulation of inorganic carbon were obtained for Anabaena variabilis , strainM–2, in the presence and absence of photosynthetic CO₂ fixation. The action spectrum for inorganic carbon accumulation in the presence of CO₂ fixation showed a peak around 684 nm, corresponding to chlorophyll a absorption in PS 1, while that for CO₂ fixation showed a peak around 630 nm, corresponding to phycocyanin absorption in PS 2. The action spectra obtained in the presence of iodoacetamide or diuron, which inhibit CO₂ fixation, showed two peaks, one at about 684 nm and the other at 630 nm, with the 630 nm peak height 80 to 90% of the 684 nm peak. These results indicate that inorganic carbon transport in A. variabilis can be driven with near equal efficiency by energy derived from absorption in photosystem 1 alone and with energy transferred to PS 1 after absorption by PS 2.     

ACTION SPECTRA FOR LIGHT-INDUCED DE-EPOXIDATION AND EPOXIDATION OF XANTHOPHYLLS IN SPINACH LEAF*

Abstract— The action spectra for violaxanthin de-epoxidation and zeaxanthin epoxidation in New Zealand spinach leaf segments, Tetragonia expansa, were determined at equal incident quanta of 2·0 × 10¹⁵ quanta cm^-2 sec^-1. Precise action spectra were not obtained due to variable leaf activity. The de-epoxidation action spectrum had major peaks at approximately 480 and 648 nm. Blue light was slightly more effective than red light and little activity was observed beyond 700 nm. The epoxidation action spectrum showed major peaks at around 440 and 670 nm. Blue light was more effective than red light and light beyond 700 nm showed definite activity. The net result of de-epoxidation and epoxidation is a cyclic scheme, the violaxanthin cycle, which consumes O₂ and photoproducts. The action spectra indicate that the violaxanthin cycle is more active in blue than in red light and therefore could account for O₂ uptake stimulated by blue light. However, the violaxanthin cycle is not the pathway for O₂ uptake by photosynthetic system 1. It was suggested that the violaxanthin cycle may function as a pathway for the consumption of excess photoproducts generated in blue light or the conversion of these photo-products to other forms of energy.     

ACTION SPECTRA FOR ULTRAVIOLET KILLING AND PHOTOREACTIVATION IN THE BLUE-GREEN ALGA AGMENELLUM QUADRUPLICATUM

Abstract— The action spectrum for photoreactivation has been determined in a coccoid blue-green alga, Agmenellum quadruplicatum. The spectrum is rather similar to that recorded for Streptomyces griseus conidia, with some suggestion of a little more structure. The action spectrum suggests possible carotenoid involvement; however, no other evidence for this could be found. The action spectrum for u.v. killing is also broad with some evidence of fine structure. The possible implication of tetrahydropteridines or c -phycocyanin as chromophores in the region 240–300 nm, along with DNA, is pointed out.     

THE ACTION SPECTRA FOR PHOTOREACTIVATION AND PHOTOREPAIR IN ICR 2A FROG CELLS

Abstract— Action spectra for photoreactivation (enhancement of colony forming ability) and photorepair (monomerization of pyrimidine dimers in DNA) were obtained for ICR 2A frog cells over the334–577 lira range. These spectra were very similar with peaks at 435 nm and little effectiveness at wavele.     

PHOTOCHEMISTRY OF TYPE I ACID-SOLUBLE CALF SKIN COLLAGEN: DEPENDENCE ON EXCITATION WAVELENGTH

Although previous studies have demonstrated that the predominant photochemistry of type I collagen under 254 nm irradiation may be attributed either to direct absorption by tyrosine/phenylalanine or to peptide bonds, direct collagen photochemistry via solar UV wavelengths is much more likely to involve several age- and tissue-related photolabile collagen fluorophores that absorb in the latter region. In this study, we compare and contrast results obtained from irradiation of a commercial preparation of acid-soluble calf skin type I collagen in solution with UVC (primarily 254 nm), UVA (335–400nm) and broad-band solar-simulating radiation (SSR; 290^1–00nm). Excitation spectroscopy and analysis of photochemically induced disappearance of fluorescence (fluorescence fading) indicates that this preparation has at least four photolabile fluorescent chromophores. In addition to tyrosine and L-3,4-dihydroxyphenylalanine, our sample contains two other fluorophores. Chromophore I, with emission maximum at 360 nm, appears to be derived from interacting aromatic moieties in close mutual proximity. Chromophore II, with broad emission at430–435 nm, may be composed of one or more age-related molecules. Collagen fluorescence fading kinetics are sensitive to excitation wavelength and to conformation. Under UVC, chromophore I fluorescence disappears with second-order kinetics, indicating a reaction between two proximal like molecules. Adherence to second-order kinetics is abrogated by prior denaturation of the collagen sample. A new broad, weak fluorescence band at400–420 nm, attributable to dityrosine, forms under UVC, but not under solar radiation. This band is photolabile to UVA and UVB wavelengths. Amino acid analysis indicates significant destruction of aromatic amino acids under UVC, but not under UVA or SSR. When properly understood, collagen fluorescence fading phenomena may act as a sensitive molecular probe of structure, conformation and reactivity.     

EFFECT OF INTENSITY AND WAVELENGTH OF FLUORESCENT LIGHT ON CHROMOSOME DAMAGE IN CULTURED MOUSE CELLS

Abstract—A single 3- to 20-hr exposure of line NCTC 9266 mouse cells to cool-white fluorescent light (4.6 W/m²) produces chromatid breaks and exchanges. The effective wavelength is in the visible range and coincides with the mercury emission peak at 405 nm. Increasing light intensity from 4.6 W to 15.3 W/m² for 20 h causes a concomitant increase both in production of chromosome damage and formation of hydrogen peroxide (H₂O₂) in the serum-free medium. Cells washed free of medium and illuminated in saline for 3 h show chromosome damage to the same extent as cells illuminated in culture medium. Addition of catalase during the exposure period of 3 h eliminates the light-induced damage. We conclude that the light-induced chromatid breaks and exchanges result from H₂O₂ production within the cell and that exogenous catalase can enter the cell and prevent the damage.     

QUANTUM YIELDS FOR LASER PHOTOCYCLIZATION OF BILIRUBIN IN THE PRESENCE OF HUMAN SERUM ALBUMIN. DEPENDENCE OF QUANTUM YIELD ON EXCITATION WAVELENGTH

The quantum yield for laser photocyclization of bilirubin to lumirubin in the presence of human serum albumin (phi LR) was measured at five monochromatic excitation wavelengths in the range 450-530 nm. Solutions used were optically thin throughout the wavelength range and precautions were taken to exclude contributions from photocyclization of bilirubin XIII alpha impurities. The values obtained (7.2-18 x 10(-4] were lower than those previously reported and showed the following wavelength dependence: 457.9 less than 488.0 less than 501.7 less than 514.5 approximately equal to 528.7. However, the rate of lumirubin formation, normalized to constant fluence, decreased with wavelength over the same wavelength range and no evidence was found that photoisomerization of bilirubin to lumirubin is faster with green (514.5 or 528.7 nm) than with blue (457.9 or 488.0 nm) light. The stereoselectivity of the configurational isomerization of bilirubin to 4Z,15E and 4E,15Z isomers also was studied. This reaction became less regioselective for the 4Z,15E isomer with increasing wavelength. The observed wavelength dependence of phi LR and of the [4E,15Z]: [4Z,15E] ratio at photoequilibrium are consistent with an exciton coupling model in which intramolecular energy transfer can occur between the two pyrromethenone chromophores of the bilirubin molecule in the excited state. Relative rates of lumirubin formation in vivo at different excitation wavelengths and constant fluence were estimated for different optical thicknesses and for different skin thicknesses. These estimates suggest that the recently reported clinical equivalence of blue and green phototherapy lights probably reflects the marked variation of skin transmittance with wavelength more than wavelength-dependent photochemistry. The calculations also indicated that the optimal wavelength for phototherapy is probably on the long wavelength side of the bilirubin absorption maximum.     

PROTEIN-RNA CROSSLINKS IN RIBOSOMES: ULTRAVIOLET ACTION SPECTRA. COMPARISON WITH INACTIVATION ACTION SPECTRUM

Abstract— RNA-protein crosslinking by UV of different wavelengths was studied in 70S E. coli ribosomes by three techniques: sucrose gradient centrifugation in the presence of sodium dodecyl sulfate (SDS), RNA solubilization in LiCI-urea concentrated solutions and RNA adsorption on nitrocellulose filters in the presence of SDS.
The centrifugational technique shows that the crosslinking reaction occurs in two steps, the first one corresponding to the fixation of a few protein molecules on 16 or 23 s RNAs and the second one corresponding to extensive RNA-protein crosslinking so that most protein molecules are no longer released by SDS from 30S and 50S subunits.
The initial rates for the first step of crosslinking were evaluated by the solubilization and adsorption techniques at 7 (or 6) wavelengths of irradiation between 223 and 290 mm. The action spectrum for RNA solubilization in LiCl-urea is perturbed at 223 nm by the breakage of protein chains. The action spectrum for retention on nitrocellulose filters seems to be exempt of this defect. It corresponds at high wavelengths to a nucleic chromophore and at low wavelengths to a proteic one. This means that RNA-protein crosslinking may occur through RNA and protein excitation. The similarity between the action spectrum for RNA retention on nitrocellulose filters and the action spectrum for inactivation of ribosomal synthesis activity suggests that RNA-protein crosslinking may be responsible for inactivation of ribosomes by UV.     

ACTION SPECTRA FOR LETHALITY IN RECOMBINATION-LESS STRAINS OF SALMONELLA TYPHIMURIUM AND ESCHERICHIA COLI*

Abstract— Action spectra for lethality of both stationary and exponentially growing cells of recombinationless (recA) mutants of Salmonella typhimurium and Escherichia coli were obtained. Maximum sensitivity was observed at 260nm which corresponds to the maximum absorbance of DNA. However, a shoulder occurred in the 280–300 nm range that departed significantly from the absorption spectrum of DNA. At wavelengths longer than 320nm, the shapes of inactivation curves departed significantly from those at wavelengths shorter than 320nm and survival curves at wavelengths longer than 320nm had a large shoulder. A small peak or shoulder occurred in the 330–340nm region of the action spectra. The special sensitivity of recA mutants to broad spectrum near-UV radiation may be due to synergistic effects of different wavelengths. Parallels between the inactivation of recA mutants and the induction of a photoproduct of l -tryptophan toxic for recA mutants (now known to be H₂O₂) suggest that H₂O₂ photoproduct from endogenous tryptophan may be involved in the high sensitivity of these strains to broad spectrum near-UV radiation.     

THE TEMPERATURE DEPENDENCE OF Pfr ACTION GOVERNS THE UPPER TEMPERATURE LIMIT FOR GERMINATION IN LETTUCE

In most cultivars of lettuce (Lactuca saliva L,), red light acting through the red/far-red reversible phytochrome system promotes full germination within the20–30°C range, but at progressively higher temperatures germination declines sharply. The relationship between this upper ternperature limit for germination and the temperature dependence of phytochrome action was investigated in Grand Rapids lettuce. In fresh seeds the GT₅₀ (temperature giving half maximal germination) was ca 29–30°C. In these seeds, escape from far-red reversibility did not occur at 35°C, a temperature above the GT₅₀, but occurred rapidly at 27°C, a temperature below the upper limit. Increasing periods of dark pretreatment at high temperature (35°C) or increasing concentrations of the germination inhibitor coumarin caused a progressive decline in the GT₅₀, Escape from photoreversibility did not occur at 27°C in seeds in which the GT₅₀ had been reduced to less than 25°C by coumarin or by prolonged high temperature pretreatment. These results indicate that there is a close correlation between the position of the upper temperature limit for germination, and the temperature dependence of phytochrome action. We conclude that factors that alter the upper temperature limit for germination do so by changing the temperature dependence of phytochrome action.     

WAVELENGTH DEPENDENCE OF INACTIVATION and MUTAGENESIS IN HAPLOID YEAST CELLS OF DIFFERENT SENSITIVITIES

The wavelength dependence of inactivation and mutagenesis in the range between 254 and 313 nm was investigated in haploid cells of the yeast Saccharomyces cerevisiae. The action spectra for a wild type and an excision deficient mutant essentially corresponded to those for bacteria and mammalian cells. There were, however, minor differences. The ratio of mutagenic to lethal action decreased with increasing wavelength in the wild type, but remained constant in the excision deficient mutant. This is discussed in terms of error-prone and erro-free repair. For both inactivation and mutagensis, photorcactivability was lower with longer wavelengths in the wild type, but did not change in the excision deficient mutant. Implications for the role of pyrimidine dimers are considered.     

PHOTOINDUCED OXYGEN CONSUMPTION IN MELANIN SYSTEMS–II. ACTION SPECTRA and QUANTUM YIELDS FOR PHEOMELANINS

Abstract— Photoinduced oxygen consumption in systems containing synthetic and natural pheomelanins has been studied by ESR spectroscopy using a nitroxide spin probe to monitor oxygen concentration. Action spectra and quantum yields have been determined for melanin from 5-S-cysteinyldopa and for pheomelanins extracted from red human hair and red chicken feathers. For comparison, data also were obtained for eumelanins from black hair and black feathers. The action spectrum for oxygen consumption by cysteinyldopa melanin is closely related to that previously obtained for eumelanins except that it shows slightly less efficiency at intermediate wavelengths (ca. 300–400 nm). Action spectra for the natural pheomelanins resemble either that for cysteinyldopa melanin or that for eumelanin. In general pheomelanins are no more effective than eumelanins in promoting oxygen consumption, i.e. they are no more susceptible to net photooxidation.