REC A +-DEPENDENT SYNERGISM BETWEEN 365 NM AND IONIZING RADIATION IN LOG-PHASE ESCHERICHIA COLI: A MODEL FOR OXYGEN-DEPENDENT NEAR-UV INACTIVATION BY DISRUPTION OF DNA REPAIR

Abstract —The oxygen dependence of 365 nm inactivation of colony-forming ability of Escherichia coli has been investigated in two series of DNA repair-deficient K12 mutants grown to mid-exponential phase. All strains except a uvr A rec A double mutant are more sensitive to inactivation under O₂ and show a lower threshold dose. The inactivation of photoreactivating enzyme in a crude cell extract and DNA repair disruption are both reduced when irradiation is carried out under nitrogen. The rec A gene-dependent synergism between 365 nm and ionising radiation is reversible if cells are incubated in full growth medium before ionising radiation treatment. In a wildtype strain, incubation for 2.5 h in full growth medium after 10⁶ J m^-2 365 nm radiation changes a sensitised response to a protection from ionising radiation. Protection is not seen at 1.5 times 10⁶ J m^-2. A tentative model for near UV lethality in logarithmic phase cells is suggested which proposes two classes of lesions. One requires oxygen for it's induction, is rapidly fixed as a lethal event as a result of repair disruption, and is primarily responsible for cell death after aerobic 365 nm irradiation. The other lesion, possibly pyrimidine dimers, may lead to cell death under anaerobic conditions.     

STUDIES ON THE in vitro O2-DEPENDENT INACTIVATION OF NADH-GLUTAMATE SYNTHASE FROM Chlamydomonas reinhardii STIMULATED BY FLAVINS

The NADH-glutamate synthase (EC 1.4.1.14) complex from Chlamydomonas reinhardii may experience in vitro two kinds of 0₂-dependent inactivation stimulated by flavins.
A peroxide-mediated inactivation of enzyme, which affects the NADH- and MVt-glutamate synthase activities of the complex, but not the NADH-dehydrogenase activity, can be obtained by aerobic incubation of the enzyme with NAD(P)H plus flavin. This inactivation of enzyme seems to be due to a permanent modification of sulfhydryl groups near the active site for L-glutamine or 2-oxoglutarate. The addition of 10 mM dithioerythritol to inactive NADH-glutamate synthase produces a significant, but not complete, reactivation of the enzyme.
On the other hand, the NADH-glutamate synthase is highly susceptible to a photodynamic inactivation caused by singlet 0₂. Aerobic incubation of the active enzyme with flavin under illumination leads to the irreversible inactivation of all the activities associated with the enzymatic complex.     

DITHIOPHENES AS SINGLET OXYGEN SENSITIZERS

Abstract— The nematicidal compounds, 5-methyl-2,2'dithienyl, 5-phenyl-2,2'-dithienyl and 5,5'-dichloro-2,2'-dithienyl, generate singlet oxygen upon photoactivation with near-UV light. Two chloro-substituted dithienylethenes have similar properties that are farless efficient. The nematode Aphelenchus avenae was rapidly killed by the photoactivated dithienyls under aerobic but not under anaerobic conditions,indicating that nematicidal activity of these compounds is related to their sensitizing properties. Furthermore,these nematodes did not expire in the presence of these compounds maintained in the dark. Sensitizing properties were studied by following the inhibition ofglucose–6-phosphate dehydrogenase by the photoactivated compounds and protection of enzyme activity by various additions. Only singlet oxygen quenchers were effective. The enzyme was inactivated 3 to 4 times faster in D₂0 compared to H₂0.Bleaching of p-nitrosodimethylaniline in the presence of imidazole and the dithiophenes and a specific reaction with the olefin adamantylideneadamantane were additional evidence of generation of singlet oxygen by the photoactivated compounds.     

PHOTO ACTIVATION OF UROCANASE IN PSEUDOMONAS PUTIDA: FACTORS INFLUENCING ACTIVATION

Abstract— –When washed cells of histidine-grown Pseudomonas putida were incubated at 8°C in darkness, urocanase activity diminished after several days; most of this lost activity could be restored by treatment of cell extracts with near-u.v. light. Sunlight and daylight were also effective for activation. Non-irradiated extract, when added to the active preparation, did not inhibit the enzyme activity. Heated and boiled extracts with or without irradiation did not catalyze the urocanase reaction nor did they change the activity of an activated extract when added to it. Photoactivation of cell extracts did not require oxygen, was not dependent on temperature and was not prevented by dialysis. Urocanase purified by gel electrophoresis was capable of light activation. It is suggested that the photoreceptor is closely associated with urocanase since it is not separated from the enzyme by dialysis or electrophoresis.     

PHOTOSENSITIZED INACTIVATION OF DNA BY MONOCHROMATIC 334-nm RADIATION IN THE PRESENCE OF 2-THIOURACIL: GENETIC ACTIVITY AND BACKBONE BREAKS

Abstract Monochromatic 334-nm radiation delivered under aerobic conditions inactivates the genetic activity (ability to transform auxotrophic recipient cells to nutritional prototrophy) of isolated transforming Bacillus subtilis DNA. The presence of superoxide dismutase (SOD), catalase, and mannitol reduces the 334-nm inactivation. The rate of inactivation of the genetic activity by 334-nm radiation is enhanced fivefold by the sensitizer 2-thiouracil (s²Ura). This enhancement is substantially reversed when the irradiations are performed in the presence of mannitol, and, to a lesser extent, SOD. Catalase slightly reduces the s²Ura enhancement of 334-nm inactivation of transforming activity. Backbone breaks induced in the same DNA by aerobic 334-nm radiation were also enhanced markedly by the presence of s²Ura; this enhancement was reversed by the presence of mannitol and, to a lesser extent, SOD during irradiation. Catalase had no effect upon s²Ura-enhanced, 334-nm-induced SSBs. Whereas DNA breakage may be responsible for a portion of the inactivation of the DNA by the photosensitized reaction between s²-Ura and 334-nm radiation, it is not the only inactivating lesion, because the yield of SSBs per lethal hit per unit length of DNA is not constant for all the irradiation conditions studied. The results support a complex role for active oxygen species in inactivation of transforming activity and DNA breakage by s²Ura-enhanced 334-nm radiation. They are also consistent with the formation of superoxide anion, hydroxyl radical, and possibly also singlet molecular oxygen, generated from ground-state molecular oxygen by reactive s²Ura in both Type I and II reactions.     

PHOTOINACTIVATION OF SPINACH NITRATE REDUCTASE SENSITIZED BY FLAVIN MONONUCLEOTIDE. EVIDENCE FOR THE INVOLVEMENT OF SINGLET OXYGEN

Abstract All the activities of the nitrate reductase complex from spinach are irreversibly inactivated by irradiation of the enzyme with blue light in the presence of flavin mononucleotide. The photoinactivation requires oxygen and is prevented by ethylenediaminetetraacetic acid and by reduced nicotinamide adenine dinucleotide, but not by superoxide dismutase plus catalase. On the other hand, the inactivation is markedly enhanced in 77% deuterated water and it is suppressed by the singlet oxygen quenchers azide, histidine and tryptophan. All these results suggest that singlet oxygen generated by light absorption by flavin mononucleotide, rather than excited flavin mononucleotide or other oxygen species, is the primary agent involved in the photooxidative inactivation of the enzyme.     

Thermal activation of photoactivatable urocanase from Pseudomonas putida

The dark inactivation of urocanase from Pseudomonas putida is caused by the formation of a sulfite adduct of the tightly bound coenzyme, nicotinamide adenine dinucleotide. Photodissociation of this adduct by UV radiation restores the enzyme activity. Based on cold exhaustive dialysis the modification reaction appeared to be irreversible. However, we now report that sulfite modification of urocanase is reversible at higher temperatures. An Arrhenius plot of the thermal activation is linear (20-38 degrees C). The activation energy for the enzyme activation is 114 kJ mol-1. The substance that is photodissociated from inactive urocanase reacts with urocanase to reform the modified enzyme indicating that sulfite is not oxidized, or otherwise changed through these processes. Nucleophiles (sulfite, hydroxylamine, hydride, cyanide) are known to inhibit urocanase by forming adducts with nicotinamide adenine dinucleotide. Urocanase inactivated by hydride or cyanide is not reactivated thermally or photochemically. Urocanase inactivated by hydroxylamine and by glycylglycine can be reactivated by a thermal reaction. In conclusion, sulfite-modified urocanase, which is formed in cells, can be reactivated not only by sunlight but also at physiological temperatures.     

PHOTODYNAMIC INACTIVATION OF YEAST CELLS SENSITIZED BY HEMATOPORPHYRIN

Abstract— Yeast cells are inactivated by treatment with hematoporphyrin and light. The inactivation is mainly mediated by singlet oxygen. The quantum yield of singlet oxygen increases with increasing pH, while the efficiency of cellular inactivation decreases with increasing pH. Cells in the stationary phase are much more resistant to the treatment than cells in exponential growth. Membrane damage seems to be the main determining step in the photoinactivation.     

EFFECT OF INACTIVATION OF THE OXYGEN-EVOLVING SYSTEM ON THE THERMOLUMINESCENCE OF ISOLATED CHLOROPLASTS

Abstract— The effect of inactivation of water-splitting enzyme on the thermoluminescence of isolated chloroplasts was investigated. The inhibitory treatments used included Tris-washing, alkaline pH in the presence of the uncoupler gramicidin, incubation with a high concentration of magnesium ions and different chaotropic agents. It was found that inhibition of oxygen evolution resulted in the disappearance of the main thermoluminescence band at +20°C. The A band which appears at — 10°C and has been related to the S₄ state of the water-splitting enzyme (Inoue, 1981) was not considerably affected by the inhibition of oxygen evolution. The results presented here indicate that the participation of the S₄ state of water-splitting enzyme in the generation of the A band should be reinvestigated.     

THE MODIFICATION OF RIBONUCLEASE-A BY NEARULTRAVIOLET IRRADIATION IN THE PRESENCE OF PSORALEN

Abstract— Ribonuclease A is inactivated when irradiated under oxygen by UV-A light in the presence of psoralen. The rate of inactivation is greatly reduced by sodium azide. ascorbate or nitrogen, whereas the substrate gives only very limited protection. A ribonuclease sample modified to 40% remaining activity presented a significant modification of amino acid residues known to be sensitive to oxidation and 1.4 mol of bound psoralen per mol of protein. The secondary structure of the enzyme, as assessed by circular dicroism was not changed by irradiation; neither was aggregation of the enzyme to a higher mol wt evident. Studies on the tryptic peptides fractionated by high performance liquid chromatography showed that the photomodification occurs with very low selectivity. All the five peptides containing hystidine, tyrosine and methionine residues were greatly modified, although two, those containing histidine residues 12 and 119 in the sequence, amino acids known to be involved in the catalytic activity of ribonuclease. are modified to a greater extent. The protein bound psoralen. revealed by radioactivity in the HPLC eluate, was not found associated to only one or few peptide peaks but spread on a large zone of elution.     

The [NiFe]-hydrogenase of the cyanobacterium Synechocystis sp. PCC 6803 works bidirectionally with a bias to H2 production

Protein film electrochemistry (PFE) was utilized to characterize the catalytic activity and oxidative inactivation of a bidirectional [NiFe]-hydrogenase (HoxEFUYH) from the cyanobacterium Synechocystis sp. PCC 6803. PFE provides precise control of the redox potential of the adsorbed enzyme so that its activity can be monitored under changing experimental conditions as current. The properties of HoxEFUYH are different from those of both the standard uptake and the "oxygen-tolerant" [NiFe]-hydrogenases. First, HoxEFUYH is biased toward proton reduction as opposed to hydrogen oxidation. Second, despite being expressed under aerobic conditions in vivo, HoxEFUYH is clearly not oxygen-tolerant. Aerobic inactivation of catalytic hydrogen oxidation by HoxEFUYH is total and nearly instantaneous, producing two inactive states. However, unlike the Ni-A and Ni-B inactive states of standard [NiFe]-hydrogenases, both of these states are quickly (<90 s) reactivated by removal of oxygen and exposure to reducing conditions. Third, proton reduction continues at 25-50% of the maximal rate in the presence of 1% oxygen. Whereas most previously characterized [NiFe]-hydrogenases seem to be preferential hydrogen oxidizing catalysts, the cyanobacterial enzyme works effectively in both directions. This unusual catalytic bias as well as the ability to be quickly reactivated may be essential to fulfilling the physiological role in cyanobacteria, organisms expected to experience swings in cellular reduction potential as they switch between aerobic conditions in the light and dark anaerobic conditions. Our results suggest that the uptake [NiFe]-hydrogenases alone are not representative of the catalytic diversity of [NiFe]-hydrogenases, and the bidirectional heteromultimeric enzymes may serve as valuable models to understand the diverse mechanisms of tuning the reactivity of the hydrogen activating site.     

MEMBRANE LYSIS IN CHINESE HAMSTER OVARY CELLS TREATED WITH HEMATOPORPHYRIN DERIVATIVE PLUS LIGHT

Abstract Chinese hamster ovary cells in exponential growth were incubated with various concentrations of hematoporphyrin derivative (HpD). Cellular porphyrin content was determined after 2 h incubation at 37°C using [³H]-hematoporphyrin derivative. Photoactivation of cell-bound HpD by red light resulted in a family of survival curves with terminal slopes proportional to cellular HpD concentration. The degree of cellular lysis, assayed 1 h after illumination using a chromium-51 labeling technique, was also found to be related to cellular HpD concentration. The amount of 51Cr released increased with post-irradiation incubation to a level parallel to cell lethality as measured by colony formation. These data suggest that lysis of the cell membrane may be largely responsible for cellular inactivation following HpD photoirradiation.     

PHOTOTOXIC EFFECTS OF NATURALLY OCCURRING POLYACETYLENES AND α-TERTHIENYL ON HUMAN ERYTHROCYTES

Hemolysis, K⁺ leakage and acetylcholinesterase (AChE) inhibition in human erythrocytes were observed with certain naturally occurring polyacetylenes and a thiophene derivative, α-terthienyl. K' leakage, subsequent hemolysis and AChE inactivation by phenylheptatriyne (PHT), a phototoxic compound, were considerably enhanced by UV light (312–400 nm). The same was true with α-terthienyl and with certain other polyacetylenes. Oxygen enhanced AChE inactivation and hemolysis with α-terthienyl in light. With PHT, only AChE inhibition was significantly enhanced in oxygen. Falcarindiol, a non-phototoxic polyacetylene, did not inactivate this enzyme but caused hemolysis in the dark. Inhibition of AChE and hemolysis by these compounds appear to be unrelated phenomena. These results indicate that certain polyacetylenes are capable of damaging biological membranes in light, and others in dark.     

PHOTOREGULATION OF NITRATE UTILIZATION IN GREEN ALGAE AND HIGHER PLANTS*

Abstract— Nitrate reductase from eukaryotes can be reversibly inactivated, blue light being an effective activating agent both in vitro and in vivo. Hydroxylamine proved to be a powerful inactivating agent of Ankistrodesmus braunii nitrate reductase. Irradiation with blue light of NH₂OH-inactivated nitrate reductase, specially in the presence of μM amounts of FAD, promoted the recovery of the enzyme activity. Similarly, photoexcited methylene blue reactivated spinach nitrate reductase. On the other hand, in vitro nitrate reductase is highly susceptible to photodynamic inactivation caused by singlet O₂. Aerobic incubation of the active spinach enzyme with either FMN or methylene blue under either blue or red light respectively led to its irreversible inactivation. Irradiation of frozen and thawed spinach leaf discs also promoted, in situ, an irreversible inactivation of nitrate reductase, provided that 6₂ was present in the incubation mixture. Thus, either in vitro or in situ, light can cause two quite different responses of nitrate reductase, its blue light-dependent photoactivation in a flavin sensitized reaction and its photodynamic inactivation in a singlet O₂-dependent process.     

Photoactivated Lysosomal Escape of a Monofunctional PtII Complex Pt‐BDPA for Nucleus Access

A photosensitizing monofunctional Pt complex, Pt‐BDPA, was prepared with a BODIPY chromophore. Apart from its DNA binding ability, this complex displays emission at ca. 578 nm and a singlet oxygen quantum yield of 0.133. Confocal imaging revealed that this complex was sequestered in lysosomes via endocytosis in the dark, preventing its access to the nucleus. Profiting from its photoinduced ROS generation ability, this complex undergoes lysosomal escape to access the nucleus upon photoirradiation. The photoinduced ROS still cause a drop in intracellular GSH, favoring the stability of Pt‐BDPA and contributing to its nuclear DNA accessibility. This complex displayed distinct cytotoxicity to all tested tumor cell lines upon photoirradiation, and the IC₅₀ values were ca. 3–6 μm , which are distinctly lower than those found with only dark incubation (IC₅₀>50 μm ). These results are consistent with photoactivated lysosomal escape of this photosensitizing Pt complex to access the nucleus.     

THE USE OF TETRAZOLIUM SALTS TO DETERMINE SITES OF DAMAGE TO THE MITOCHONDRIAL ELECTRON TRANSPORT CHAIN IN INTACT CELLS FOLLOWING in vitro PHOTODYNAMIC THERAPY WITH PHOTOFRIN II

Abstract A method is described utilizing the tetrazolium salts neotetrazolium chloride (NTC), triphenyltetrazolium chloride (TTC), C,N-diphenyl-N'-4,5-dimethylthiazol-2-yltetrazolium bromide (MTT) and various substrates to elucidate damage to the mitochondrial electron transport chain of intact cells following in vitro photodynamic therapy (PDT). Using this methodology, a portion of the dark toxicity manifested by Photofrin II (PII) was found to occur prior to entry of electrons into the transport chain through Complex I, as evidenced by the fact that the inhibition of MTT reduction was reversible by the addition of malic acid to the culture media. A second site of dark toxicity was found to be Complex IV (cytochrome oxidase). After photoirradiation of the cells, Complex I was found to be affected since malic acid could no longer reverse the inhibition of MTT reduction but it could be reversed by the addition of succinic acid, whose electrons enter the transport chain at Complex II. A second and more sensitive site of photoirradiation damage was found to be Complex IV. A region near cytochrome C was also affected by photoirradiation but appreciably less so than noted for Complexes I and IV. A kinetic analysis of MTT and TTC reduction following photoirradiation indicated that MTT reduction was sustained at a normal rate for 1 h after which it slowed down and eventually plateaued. In contrast, TTC reduction was found to be inhibited almost immediately indicating Complex IV is extremely susceptible to photoirradiation damage. Compared to other assays of mitochondrial function requiring subcellular fractionation, the use of tetrazolium salts is simpler to perform and can be done using physiologically relevant conditions.     

PHOTODYNAMIC TREATMENT OF HERPES SIMPLEX VIRUS INFECTION IN VITRO

Abstract— The effects of photodynamic action on in vitro herpes simplex virus infections of CV-1 monkey kidney fibroblasts or human skin fibroblasts were determined using proflavine sulfate and white fluorescent lamps. Photodynamic treatment of confluent cell monolayers prior to virus infection inactivated cell capacity, i.e. the capacity of the treated cells to support subsequent virus growth as measured by plaque formation. The capacity of human cells was more sensitive to inactivation than the capacity of monkey cells when 6 μM proflavine was used. Treated cell monolayers recovered the capacity to support virus plaque formation when virus infection was delayed four days after the treatment. Experiments in which the photodynamically treated monolayers were infected with UV-irradiated virus demonstrated that this treatment induced Weigle reactivation in both types of cells. This reactivation occurred for virus infection just after treatment or 4 days later. A Luria-Latarjet-type experiment was also performed in which cultures infected with unirradiated virus were photodynamically treated at different times after the start of infection. The results showed that for the first several hours of the virus infection the infected cultures were more sensitive to inactivation by photodynamic treatment than cell capacity. By the end of the eclipse period the infected cultures were less sensitive to inactivation than cell capacity. Results from extracellular inactivation of virus grown in monkey cells at 6 μM proflavine indicated that at physiological pH the virus has a sensitivity to photodynamic inactivation similar to that for inactivation of cell capacity. The combined data indicated that photodynamic treatment of the cell before or after virus infection could prevent virus growth. Thus, photodynamic inactivation of infected and uninfected cells may be as important as inactivation of virus particles when considering possible mechanisms in clinical photodynamic therapy for herpes simplex.     

THE USE OF TETRAZOLIUM SALTS TO DETERMINE SITES OF DAMAGE TO THE MITOCHONDRIAL ELECTRON TRANSPORT CHAIN IN INTACT CELLS FOLLOWING in vitro: PHOTODYNAMIC THERAPY WITH PHOTOFRIN II

Abstract: A method is described utilizing the tetrazolium salts neotetrazolium chloride (NTC), triphenyltetrazolium chloride (TTC), C, N -diphenyl- N' -4,5-dimethylthiazol-2-yrtetrazolium bromide (MTT) and various substrates to elucidate damage to the mitochondrial electron transport chain of intact cells following in vitro photodynamic therapy (PDT). Using this methodology, a portion of the dark toxicity manifested by Photofrin II (PII) was found to occur prior to entry of electrons into the transport chain through Complex I, as evidenced by the fact that the inhibition of MTT reduction was reversible by the addition of malic acid to the culture media. A second site of dark toxicity was found to be Complex IV (cytochrome oxidase). After photoirradiation of the cells, Complex I was found to be affected since malic acid could no longer reverse the inhibition of MTT reduction but it could be reversed by the addition of succinic acid, whose electrons enter the transport chain at Complex II. A second and more sensitive site of photoirradiation damage was found to be Complex IV. A region near cytochrome C was also affected by photoirradiation but appreciably less so than noted for Complexes I and IV. A kinetic analysis of MTT and TTC reduction following photoirradiation indicated that MTT reduction was sustained at a normal rate for 1 h after which it slowed down and eventually plateaued. In contrast, TTC reduction was found to be inhibited almost immediately indicating Complex IV is extremely susceptible to photoirradiation damage. Compared to other assays of mitochondrial function requiring subcellular fractionation, the use of tetrazolium salts is simpler to perform and can be done using physiologically relevant conditions.     

PHOTODYNAMIC INACTIVATION OF LYSOZYME BY EOSIN

Abstract— It has been demonstrated that singlet oxygen is the major oxidizing entity in the photo-dynamic inactivation of hen egg white lysozyme by eosin, using D₂O to enhance the solvent-induced decay lifetime, and azide ion as a specific scavenger. Two regimes of inactivation can be distinguished depending on whether the sensitizer is free or complexed to the enzyme. The kinetic analysis for free dye sensitization, based on photostationary measurements and inactivation quantum yields, indicates that at least 1 in 15 singlet oxygen interactions with lysozyme leads to loss of lytic activity. The direct attack of triplet eosin makes a lesser overall contribution in air-saturated solutions, where 1 in 4 reactions induces inactivation. Lysozyme binds 1 eosin molecule from pH 4 to 12, leading to almost total quenching of the tryptophyl residue fluorescence without inhibition of the enzymic activity. The inactivation quantum yields indicate that singlet oxygen generated from the bound dye is the inactivating agent, but the dominant attack takes place with the complexed fraction of lysozyme molecules. The tryptophyl residue loss is the same or smaller in changing from H₂O to D₂O despite the 5–10 times increase in quantum yield, indicating that singlet oxygen inactivates also by reacting with residues other than tryptophan. The photochemical and fluorescence results are consistent with the the identification of tryptophyl site 108 with the eosin binding site and a reaction target for singlet oxygen. In a re-examination of earlier work on eosin-sensitized photo-oxidation of I", it has been found that singlet oxygen is the oxidizing agent in aerobic solutions.     

Inactivation of phospholipase C from Bacillus cereus by a carboxyl group modifying reagent.

Phospholipase C from Bacillus cereus was inactivated by incubation with either of the carboxyl reagents, a water-soluble carbodimide plus a nucleophile or Woodward's reagent K. With the former reagent, the incorporation into the enzyme of the first mol of nucleophile caused a 4-5-fold increase in the Km for dihexanoyllecithin with no significant effect on the Vm. The second mol of nucleophile incorporated caused no further change in Km but destroyed most of the catalytic activity. Modification of the enzyme by carbodiimide plus nucleophile did not alter the relative activity of the enzyme towards micelles and monomolecularly dispersed solutions of diheptanoyllecithin. Furthermore, inactivation by this reagent did not significantly decrease the ability of the enzyme to bind to a substrate-based affinity gel. It was concluded that phospholipase C contains a single carboxyl group that is essential for catalytic activity. The enzyme also contains a total of 4-5 reactive/exposed carboxyl groups.