LASER FLASH PHOTOKINETIC STUDIES OF ROSE BENGAL SENSITIZED PHOTODYNAMIC INTERACTIONS OF NUCLEOTIDES AND DNA

Abstract— Laser flash photolysis studies of the production of the triplet state of the xanthene dye, rose bengal (RB), have been carried out. The reactions of this state with oxygen to form singlet oxygen and the superoxide anion radical have been observed and yields measured. Quenching of RB(T₁) by oxygen leads to approximately 75% singlet oxygen and 20% superoxide. The reactivity of these species-RB(T₁), O₂(¹Δ_g) and O₂^-—with four nucleotides and DNA have been determined. Only guanine residues showed any noticeable reaction at neutral pH. At higher pH guanine rate constants increased. The consequences to biological photodynamic processes are discussed.     

EFFECT OF SODIUM AZIDE ON PHOTODYNAMIC INDUCTION OF GENETIC CHANGES IN YEAST

Abstract— In view of the increasing attention to ¹O₂ (¹Δ_g) participation in the photodynamic action, different types of genetic changes in Saccharomyces cerevisiae by acridine orange sensitization were compared with respect to the response to N₃^-, a well known quencher of ¹O₂. The induction of mitotic crossing over with respect to ade 2 locus and mitotic gene conversion at trp 5 locus were suppressed by the addition of N₃^- suggesting the involvement of ¹O₂ as a major intermediate. However, the induction of reverse mutation at ilv 1 was only slightly suppressed. These results may indicate that there are two types of photodynamic DNA damage; one is produced via ¹O₂ and the other via non-¹O₂ reaction pathway which lead to mitotic gene conversion and mitotic crossing over, and to mutation, respectively.     

DNA Damage and Apoptosis Induced by Photosensitization of 5,10,15,20-Tetrakis (N-methyl-4-pyridyl)-21H,23H-porphyrin via Singlet Oxygen Generation

Cancer photodynamic therapy (PDT) requires photosensitizers that efficiently and selectively destroy tumor cells. We investigated 5,10,15,20-tetrakis ( N -methyl-4-pyridyl)-21 H ,23 H -porphyrin (TMPyP) as a potential cancer treatment. Confocal fluorescence microscopy showed that TMPyP was localized in the nuclei, whereas 5-aminolevulinic acid (ALA)-derived protoporphyrin IX (PPIX) was localized diffusely in the cytoplasm of human leukemia (HL-60) cells. In HL-60 cells under UVA irradiation, TMPyP effectively induced apoptosis. Moreover, 8-oxo-7,8-dihydro-2'-deoxyguanosine, an oxidative product of 2'-deoxyguanosine, was accumulated in the DNA of cells treated with photoirradiated TMPyP, whereas only small amounts were observed in ALA-treated cells in the presence of UVA light. TMPyP and UVA caused extensive damage at every guanine residue in DNA fragments obtained from the human p 53 tumor suppressor gene and the c-Ha- ras -1 proto-oncogene, whereas PPIX induced little DNA damage under these conditions. Electron spin resonance spectroscopy using a singlet oxygen (¹O₂) probe and D₂O showed that photoexcited TMPyP generated ¹O₂. These results suggest that photoexcited TMPyP reacts with oxygen to generate ¹O₂, which in turn, oxidizes guanine residues. Taken together, the results demonstrated that TMPyP was localized in the nucleus where it was photosensitized to induce DNA damage, suggesting that TMPyP may have clinical utility as a nucleus-targeted PDT.     

NEAR ULTRAVIOLET AND POSTIRRADIATION DNA DEGRADATION: EFFECTS ON THE INDUCIBLE INHIBITOR OF IONIZING RADIATION-INDUCED DNA DEGRADATION

Abstract— Possible effects of near ultraviolet radiation (near UV) on DNA degradation were examined. Postirradiation DNA degradation induced by ionizing radiation in strain B_s-l ( uur-, lex- ) is shown to be inhibited by carbon monoxide (CO) and potassium cyanide (KCN) if the cells are grown on glycerol. Presumably the blockage of respiration by these agents lowers the amount of ATP in the cell. 50 kJ/m² near UV did not simulate the action of CO and KCN, indicating that at this Ruence the supply of ATP remains adequate for postirradiation DNA degradation. Near UV did not, itself, produce DNA degradation. In a strain (B/r) in which an inhibitor of postirradiation DNA degradation can be induced by both UV and ionizing radiation, near UV affects the inhibitor formation, whether administered before or after induction.     

THE EFFECTS OF PHOTOOXIDATION BY PROFLAVINE ON HeLa CELLS—II. DAMAGE TO DNA

Abstract— HeLa cell suspensions, prelabeled with specific [¹⁴C]-nucleosides, were treated with proflavine and irradiated with visible light (400–500 nm). The DNA was isolated from the cells (as well as from the appropriate control cells) and examined for macromolecular and molecular changes. Although the UV absorbance spectrum of DNA from irradiated HeLa cells showed no discernible change, a fluorescence spectrum (excitation/emission: 305/405) indicated a molecular change in the DNA. Isolated DNA samples were hydrolyzed with 90% formic acid and chromatographed. There were no detectable differences between the irradiated and non-irradiated profile (R _f and radioactivity) for both guanine and adenine. However, the chromatograms of thymine and cytosine showed distinct changes. There was a loss of radioactivity in the [¹⁴C]-thymidine labeled samples, while the [¹⁴C]-cytidine labeled samples indicated the formation of a new compound, containing 10% of the radioactivity, running just ahead of cytosine. These data strongly suggest the formation of a new compound resulting from the photooxidation of cytosine when nuclear DNA was sensitized by proflavine.     

PHOTOADDITION OF CHLORPROMAZINE TO GUANOSINE-5'-MONOPHOSPHATE

Abstrart—The photochemistry of chlorpromazine (CPZ) with guanosine-5'-monophosphate (GMP) was studied as a model for the photoaddition of CPZ to DNA. Irradiation of CPZ with calf thymus DNA produced a product emitting at 520 nm, whereas with GMP emission was at 495 nm. HPLC separation of photolysis mixtures of [³H]CPZ with GMP and [¹⁴C]GMP with CPZ indicated that three photoadducts were formed. One of the adducts fluoresced at 500 nm and appeared to be the product detected but not separated by Fujita et al. (Photochem. Photobiol . 1981, 34 , 101–105). A second adduct emitted at 460 nm, and the third was nonfluorescent. The photoadduct emitting at 500 nm was characterized by UV, fluorescence, and NMR to be an adduct from coupling of the C-8 position of guanine to the C-2 position of the phenothiazine ring of CPZ. The cation radical of CPZ (CPZ ⁺) does not appear to be an intermediate since enzymatically generated CPZ ⁺ formed a product that eluted with a retention time close to that of the photoadducts, but did not emit at 520 nm.     

PHOTOLYSIS OF PHOSPHODIESTER BONDS IN PLASMID DNA BY HIGH INTENSITY UV LASER IRRADIATION

Abstract— The cleavage of phosphodiester bonds in DNA exposed to high intensity UV laser pulses in aerated aqueous solution has been investigated using a krypton fluoride excimer laser (248 nm) and bacterial plasmid DNA. The dependence of strand breakage on fluence and intensity has been studied in detail and shows that the process is non-linear with respect to intensity. The relationship between the quantum yield for strand breakage and intensity shows that the strand breakage reaction involves two-photon excitation of DNA bases. The quantum yield rises with intensity from a lower value of 7 times 10^-5 until a maximum value of 4.5 times 10^-4 is attained at intensities of 10¹¹ W m^-2 and above. This value is approximately fifty-fold higher than the quantum yield for strand breakage induced by exposure to low density UV irradiation (254 nm, 12 W m^-2). DNA sequencing experiments have shown that strand breakage occurs by the specific cleavage of the phosphodiester bond which lies immediately 3' to guanine residues in the DNA, leaving some alkali-labile remnant attached to the terminal phosphate. A mechanism for DNA strand breakage which involves the generation of guanine radical cations is proposed.     

TOLUIDINE BLUE: THE MODE OF PHOTODYNAMIC ACTION IN YEAST CELLS

Abstract— Toluidine blue, a thiazine dye, was shown to have in vivo photodynamic activity through singlet oxygen (O₂¹Δ _g ) production. This was based mainly on the effective protection by N^-₃ and the marked enhancement in D₂O for the sensitized inactivation of yeast cells. The mode of the in vivo activity was, however, quite different from that of acridine orange, for which the singlet oxygen mechanism has also been proposed. The most characteristic feature in the toluidine blue-sensitization was the total lack of the induction of gene conversion (at trp 5), while the survival went down below 10%. The non-induction of genetic changes was confirmed at several pH's in the neutral region, whereas the inactivation was seen in parallel to the reported pH dependence of singlet oxygen production in vitro . Direct measurements by microspectrophotometry showed none of the toluidine blue was accumulated in the cell. It was also ascertained from acridine-sensitized induction of gene conversion that toluidine blue never interfered with the binding of acridine orange to cellular DNA. These findings suggested that the unique mode of photodynamic activity of toluidine blue is attributable to its action from outside of the cell. Furthermore, comparisons between the photodynamically treated cells (with toluidine blue) and non-treated cells with respect to the response to UV irradiation excluded certain cell functions relating to the expression of gene conversion from the possible damage sites. The photo-reactivation process of UV induced gene conversion was not disturbed by the pre-toluidine blue sensitition. In view of the foregoing results, the plasma membrane was tentatively suggested as the most likely site of damage.     

Rapid Initiation of Apoptosis by Photodynamic Therapy

Abstract— Photodynamic therapy (PDT) of neoplastic cell lines is sometimes associated with the rapid initiation of apoptosis, a mode of cell death that results in a distinct pattern of cellular and DNA fragmentation. The apoptotic response appears to be a function of both the sensitizer and the cell line. In this study, we examined photodynamic effects of several photosensitizers on murine leukemia P388 cells. Two drugs, a porphycene dimer (PcD) and tin etiopurpurin (SnET2), which localized at lysosomal sites, were tested at PDT doses that resulted in 50% loss of viability (LD₅₀), measured by the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay. An oligonucleosomal pattern of DNA degradation was observed within 1 h after irradiation. Neither sensitizer antagonized PDT-mediated internucleosomal DNA cleavage by the other. Very high PDT doses with either agent abolished this rapid internucleosomal cleavage. Exposure of cells to high concentrations of either sensitizer in the dark also resulted in rapid DNA fragmentation to nucle-osomes and nucleosome multimers; this effect was not altered by the antioxidant 6-hydroxy-2,5,7,8-tetramethyl-chroman-2-carboxylic acid (trolox), although the latter could protect cells from cytotoxicity and apoptotic effects caused by LD₅₀ PDT doses. Photodamage from two cat-ionic sensitizers, which localized at membrane sites, caused rapid DNA cleavage to 50 kb particles; however, no further fragmentation was detected after 1 h under LD₁₀, LD₅₀ or LD₉₅ PDT conditions. Moreover, the presence of either cationic sensitizer inhibited the rapid internucleosomal cleavage induced by SnET2 or PcD photodamage. The site of photodynamic action may therefore be a major determinant of the initiation and rate of progression of apoptosis.     

MECHANISM OF PHOTOINACTIVATION OF PLANT PLASMA MEMBRANE ATPASE

Abstract UV radiation at 290 and 365 nm inactivates two forms of the K⁺-stimulated ATPase associated with the plasma membrane of suspension-cultured cells of Rosa damascena . One form is 15 and 36 times more sensitive than the other to 290 and 365 nm, respectively. For both forms, the inactivation requires oxygen, is inhibited by azide and diazobicyclo(2.2.2.2)octane, but not glycerol, and is enhanced up to 7.5 times in deuterium oxide solvent. Inactivation occurs concomitantly with loss of absorbance at 290 nm. Cs⁺ and NO⁻₃, quenchers of tryptophan fluorescence, inhibit inactivation. The results suggest that inactivation involves singlet-oxygen mediated destruction of tryptophans in the ATPases.     

PHOTODYNAMIC THERAPY WITH PHOTOFRIN II INDUCES PROGRAMMED CELL DEATH IN CARCINOMA CELL LINES

Abstract The mode of cell death following photodynamic therapy was investigated from the perspective of programmed cell death or apoptosis. Human prostate carcinoma cells (PC3), human non-small cell lung carcinoma (H322a) and rat mammary carcinoma (MTF7) were treated by photodynamic therapy. An examination of extracted cellular DNA by gel electrophoresis showed the characteristic DNA ladder indicative of internucleosomal cleavage of DNA during apoptosis. The magnitude of the response and the photodynamic therapy dosage required to induce DNA fragmentation were different in PC3 and MTF7. The MTF7 cells responded with rapid apoptosis at the dose of light and drug that yielded 50% cell death (LD₅₀). In contrast, PC3 showed only marginal response at the LD₅₀ but had a marked response at the LD₈₅. Thus, apoptosis did not ensue as quickly in PC3 as in MTF7. The H322a cells were killed by photodynamic therapy but failed to exhibit any apoptotic response. The results also suggested that apoptosis in these cell lines has a minor requirement for de novo protein synthesis and no requirement for de novo RNA synthesis. This study indicates that although apoptosis can occur during photodynamic therapy-induced cell death, this response is not universal for all cancer cell lines.     

THE ACTION OF ULTRAVIOLET RADIATION ON THE CELL PROLIFERATION OF TWO-CELL MOUSE EMBRYOS

Abstract— The two-cell mouse embryo has a unique cell cycle of a short DNA synthesis (S) phase and an extremely long post-DNA synthesis (G₂) phase. An attempt was made to investigate the radiation biology of the long G₂ phase using UV radiation as a probe. Two cell mouse embryos, at various positions in the cell cycle, were UV-irradiated in phosphate-buffered saline. The embryos were cultured for a few hours to 3 days to assay for their cell proliferative characteristics. The embryos were most sensitive to the killing action of UV radiation in the late G₂ phase. The embryos divided more than two times after low UV fluences before dying and experienced G₂ phase delays.
These results can be contrasted to the situation in somatic cells, in which the action of UV radiation is S phase selective. One possibility is that the target for the action of UV radiation is different in two-cell mouse embryos from that in somatic cells and that the target is similar to that for X-ray effects.     

FURTHER IN VIVO STUDIES ON THE PARTICIPATION OF SINGLET OXYGEN IN THE PHOTODYNAMIC INACTIVATION AND INDUCTION OF GENETIC CHANGES IN SACCHAROMYCES CEREVISIAE

Abstract —In vivo participation of singlet excited oxygen (¹O₂, ¹Δ9) in the photodynamic inactivation and induction of genetic changes (gene conversion) in acridine orange-sensitized yeast cells was investigated by using N₃^-, an efficient ¹O₂ quencher, and D²O, a known agent for the enhancement of the lifetime of ¹O₂. The addition of N₃^- protected the cells from both photodynamic actions. From an analysis of the concentration-dependent protection, about 80% of the induction of the genetic change is explainable on the basis of ¹O₂ mechanism. The quantitative estimation of the N₃^- protection in the inactivation was not possible because of the sigmoidal nature of the inactivation curve. The replacement of H₂O with D₂O during illumination was effective in enhancing the photodynamic inactivation but almost completely ineffective for the gene conversion induction. The deuterium effect with the cell system was clearly not as large as would be expected from in vitro experiments. This, however, could be explained from the kinetic consideration that natural quenchers of ^lO₂ in the cell would mask the deuterium effect. By experiments with different cell stages it was demonstrated that these two modifying effects were dependent on the intracellular reaction environment. The conclusion is that ¹O₂ must be the major intermediate responsible for the photodynamic actions in acridine orangesensitized yeast cells.     

ACTINOMETRY IN MONOCHROMATIC FLASH PHOTOLYSIS: THE EXTINCTION COEFFICIENT OF TRIPLET BENZOPHENONE AND QUANTUM YIELD OF TRIPLET ZINC TETRAPHENYL PORPHYRIN

Abstract— The extinction coefficient ε_T, of triplet benzophenone in benzene has been directly determined by absolute measurements of absorbed energy and triplet absorbance, Δ D ⁰_T, under demonstrably linear conditions where incident excitation energy, E ₀, and ground state absorbance, A ₀, are both extrapolated to zero. The result, 7220 ± 320 M ^-1 cm^-1 at 530 nm, validates and slightly corrects many measurements relative to benzophenone of triplet extinction coefficients made by the energy transfer technique, and of triplet yields obtained by the comparative method.
As E ₀ and A ₀ both decrease, Δ D ⁰_T becomes proportional to their product. In this situation, the ratio R = (1/ A ₀)(dΔ D ⁰_T/d E ₀) = (ε_T - ε_G)φ_T. Measurements of R , referred to benzophenone, give (ε_T - ε_G)φ_T for any substance, without necessity for absolute energy calibration.
Both absolute and relative laser flash measurements on zinc tetraphenyl porphyrin (ε_T - ε_G at 470 nm = 7.3 × 10⁴ M ^-1 cm^-1) give φ_T= 0.83 ± 0.04.     

THE 518-mμ ABSORBANCE CHANGE AND ITS RELATION TO THE PHOTOSYNTHETIC PROCESS

Abstract— A study of the 518-mμ light-induced absorbance change in green cells and a comparison with photosynthetic O₂ evolution were made. The effect of various chemical agents was also investigated. On the one hand, no antagonistic two-light effect was observed on the absorbance change, and DCMU had only a partial inhibitory effect on it. On the other hand, it was possible to observe in some cases an indirect kinetic relationship between O₂ evolution and 518-mμ change. It is suggested that probably at least two substances absorb around 518-mμ, one ( X _I) belonging to system I and another ( X _II) to system II. The existence and the function of X _I are hypothetical and the identity of X _II with the first photoproduct of system II is yet not well established.     

INACTIVATION OF THE ACCEPTOR SIDE AND DEGRADATION OF THE D1 PROTEIN OF PHOTOSYSTEM II BY SINGLET OXYGEN PHOTOGENERATED FROM THE OUTSIDE

Abstract— The possible association of photodynamic sensitization with photoinhibition damage to the photosystem II complex (PS II) has been investigated using isolated intact thylakoids from pea leaves. For this study singlet oxygen (¹O₂), photoproduced by endogenous chromophores that are independent of the function of PS II, was assumed to be the major reactive intermediate involved in the photoinhibition process. When thylakoid samples preincubated with rose bengal were subjected to exposure to relatively weak green light (500–600 nm) under aerobic conditions, PS II was severely damaged. The pattern of the rose bengal-sensitized inhibition of PS II was similar to that of high light-induced damage to PS II: (1) the secondary quinone (Q_B)-dependent electron transfer through PS II is inactivated much faster than the Q_B-independent electron flow, (2) PS II activity is lost prior to degradation of the D1 protein, (3) diuron, an herbicide that binds to the Q_B domain on the D1 protein, prevents D1 degradation, and (4) PS II is damaged to a greater extent by the deuteration of thylakoid suspensions but to a lesser extent by the presence of histidine. Furthermore, it was observed that destroying thylakoid Fe-S centers resulted in a marked reduction of high light-induced PS II damage. These results may suggest that the primary processes of photoinhibition are mediated by ¹O₂ and that Fe-S centers, which are located in some membrane components, but not in PS II, play an important role in photogenerating the activated oxygen immediately responsible for the initiation of photodamage to PS II.     

ON THE NATURE OF THE INTERMEDIATE ELECTRON ACCEPTOR (A1) IN THE PHOTOSYSTEM I REACTION CENTER

Abstract— A sodium dodecyl sulfate-Photosystem I (PSI) complex has been prepared and characterized with respect to its electron acceptors. Component X and iron-sulfur centers A and B are absent from this preparation but the intermediate electron acceptor (A₁) is present. Flash-induced absorbance changes at 25°C show charge separation, followed by a back-reaction with a half-time of 5 µs. The spectrum of the flash-induced change from 350 to 550 nm indicates a contribution from the intermediate electron acceptor, A₁, as well as from P700⁺. EPR studies show that A₁ is associated with a free-radical signal having a g-value of 2.0025 and a linewidth of 12 gauss. A, would appear to be associated with a monomeric form of either Chi α or pheophytin a.     

CHANGES IN TRANSMISSION CHARACTERISTICS OF POLYMETHYLMETHACRYLATE AND CELLULOSE (III) ACETATE DURING EXPOSURE TO ULTRAVIOLET LIGHT

Abstract— Ultraviolet-transparent polymethylmethacrylate (PMMA) and cellulose (III) acetate (CA) (often used as a cut-off filter in UVB [280–320 nm] biological effect studies) were exposed to a 20 W Philips TL 12 lamp to examine changes in transmission characteristics due to UVB exposure. Transmission of UVB and biologically weighted UVB (UV_BE(DNA)) through PMMA were similar, 88.3 and 83.5%, respectively. The absorption characteristics of PMMA did not change with time at any of the UV irradiance levels applied. However, transmission of UVB and UVB_BE(DNA)) through new CA differed considerably: 59% versus only 11%, respectively. Also, spectral absorption characteristics changed with time due to degradation of CA, at a rate that was dependent on the incident UVB irradiance. The decrease in transmission through CA of both UVB and UV_BE(DNA) can be described by exponential functions. The CA that was wrapped around the UV lamp showed dramatic changes in UV absorption over the first few hours of use. However, when CA was placed at a longer distance from the light source initial degradation was less. It is concluded that PMMA can be applied in UV effect studies as a reasonable alternative for quartz. The CA should, however, be used with care, because the large transmission decreases that were observed strongly hamper an accurate calculation of (biologically weighted) UVB dose rates.     

PULSED RADIATION STUDIES OF PHOTODYNAMIC SENSITISERS: THE NATURE OF DHE

Abstract Laser flash photolysis has previously been used to study the nature of DHE via measurements of photophysical parameters which are dependent on the molecular weight of the system being studied. These results to date allow only a lower limit to be established for DHE which imply that in some environments such as detergents more than two porphyrin units are linked. We have now determined the triplet extinction coefficient of DHE by the pulse radiolysis technique via an energy transfer method which allows the triplet extinction of DHE to be estimated independent of the molecular weight. The combined techniques allow the actual molecular weight of DHE to be established at about 4200. Laser flash techniques have also now been used to determine, for a number of potential photodynamic sensitisers, the quantum yield of triplet state formation (θ_T) and, using the direct luminescence of singlet oxygen at 1270 nm, the quantum yield of singlet oxygen formation (θ_δ). For many of the porphyrins studied θ_δ is less than θ_T. For DHE itself there is a substantial increase in θ_δ in detergent compared to buffer. The θ_δ yields for a number of related systems including 'simple'systems such as haematoporphyrin, for linked porphyrin-chlorin systems, (including DHE in which the end porphyrin is reduced to a chlorin–DHEC), and for phthalocyanines are compared. For the DHEC the θ_δ is close to that of DHE itself which may imply that such chlorins could be of use in photodynamic therapy (PDT).     

MECHANISMS FOR DYE-MEDIATED PHOTODYNAMIC ACTION: SINGLET OXYGEN PRODUCTION, DEOXYGUANOSINE OXIDATION AND PHAGE INACTIVATING EFFICIENCIES

Abstract The production of singlet oxygen (¹O₂) upon irradiation of several dyes in aqueous solution at pH 9.0, was quantitatively analyzed on the basis of the appearance of stable nitroxide radicals using the amine 2,2,6,6-tetramethyl-4-piperidone as ¹O₂ acceptor. The dyes were checked for purity, their concentrations uniformized in terms of absorbance values and a correction factor was introduced which took into account the amount of photons absorbed. The rates of ¹O₂ production (in arbitrary units per min) were: 71 with rose Bengal, 70 with methylene blue, 61 with eosin Y, 18 with thiopyronine, 10 with proflavine and 9 with acridine yellow. Production of ¹O₂ was not observed with 9-aminoacridine, acridine orange, quinacrine and ethidium bromide. Irradiated lumichrome initiated, with the same amine, another type of reaction. The rates of two other photoreactions were also determined under similar experimental conditions by following (i) the deoxyguanosine decomposition in which case the reaction was found to be less sensitive but largely parallel to the ¹O₂ production and (ii) the bacteriophage ØX174 inactivation in which case the dyes showed differences in their relative efficiencies. The proteinic capsid of the phage appeared as an effective impermeability barrier towards externally generated ¹O₂. Moreover, some of the dyes studied intercalated into the phage DNA, a process known to favor radicalar reactions.