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.     

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.     

ENHANCING EFFECT OF ASCORBATE ON TOLUIDINE BLUE-PHOTOSENSITIZATION OF YEAST CELLS

Abstract— Using toluidine blue, a potent photosensitizer with a ₁O₂ dominated mechanism in yeast cell inactivation, it was found that addition of ascorbate to the sensitizer-cell mixture during illumination enhanced the inactivation. The enhancement required the presence of oxygen in the reaction mixture. The same enhancement was observed with methylene blue and thionine but not with xanthenes (Rose Bengal and eosin Y). The consumption of O₂ and ascorbate seemed coupled in the enhancement. From the observation that the presence of ascorbate for a very short time (1 s) in the reaction mixture was enough to exhibit the same enhancement, it was concluded that the ascorbate enhancement processes are probably initiated in bulk medium, not intracellularly. The ascorbate enhancement may be a combined consequence of the high electron-accepting property of triplet toluidine blue and the strong tendency of ascorbate to act as an electron donor. The role of oxygen was not specified whether it was directly involved in the photoinactivation of cells. Addition of N J appeared to suppress the photoinacti-vation only in the higher fluence region where ascorbate had been consumed. Thus the ascorbate enhancement seems to occur under low fluence conditions and may probably be independent of the singlet oxygen mechanism.     

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.     

INACTIVATION OF Trypanosoma cruzi TRYPOMASTIGOTE FORMS IN BLOOD COMPONENTS BY PHOTODYNAMIC TREATMENT WITH PHTHALOCYANINES

Abstract— -Three phthalocyanine dyes HOSiPcOSi(CH₃)₂(CH₂)₃N(CH₃)₂ (Pc 4), HOSiPc-OSi(CH₃)₂(CH₂)₃N+(CH₃)3I- (Pc 5) and aluminum tetrasulfophthalocyanine hydroxide (AlOHPcS₄) were evaluated for their ability to inactivate the trypomastigote form of Trypanosoma cruzi in fresh frozen plasma (FFP) and red blood cell concentrates (RBCC). The compound Pc 4 was found to be highly effective in killing T. cruzi, Pc 5 less effective and AlOHPcS₄ ineffective. With FFP as the medium, a complete loss of parasite infectivity in vitro (≥5 log₁₀) was found to occur with 2 μ M Pc 4 after irradiation with red light (>600 nm) at a fiuence of 7.5 J/cm², while with RBCC as the medium, a complete loss was found to occur at a fiuence of 15 J/cm². Even without illumination, Pc 4 at 2 μ M also killed about 3.7-4.1 log₁₀ of T. cruzi in FFP during 30 min. Observed differences in T. cruzi killing by the various phthalocyanines may relate to differences in binding; Pc 4 binds to the parasites about twice as much as Pc 5. Ultrastructural analysis of treated parasites suggests that mitochondria are a primary target of this photodynamic treatment. The data indicate that Pc 4 combined with exposure to red light could be used to eliminate bloodborne T. cruzi parasites from blood components intended for transfusion. The inactivation of T. cruzi by Pc 4 in the dark suggests a possible therapeutic application.     

THE EFFECT OF IRRADIANCE ON VIRUS STERILIZATION AND PHOTODYNAMIC DAMAGE IN RED BLOOD CELLS SENSITIZED BY PHTHALOCYANINES

Abstract— Phthalocyanines are being studied as photosensitizers for virus sterilization of red blood cells (RBC). During optimization of the reaction conditions, we observed a marked effect of the irradiance on production of RBC damage. Using a broad-band light source (600–700 nm) between 5 and 80 mW/ cm², there was an inverse relationship between irradiance and rate of photohemolysis. This effect was observed with aluminum sulfonated phthalocyanine (AlPcS_n) and cationic silicon (HOSiPc-OSi[CH₃]₂ [CH₂]₃N⁺[CH₃]₃I^- phthalocyanine (Pc5) photosensitizers. The same effect occurred when the reduction of RBC negative surface charges was used as an endpoint. Under the same treatment conditions, vesicular stomatitis virus inactivation rate was unaffected by changes in the irradiance. Reduction in oxygen availability for the photochemical reaction at high irradiance could explain the effect. However, theoretical estimates suggest that oxygen depletion is minimal under our conditions. In addition, because the rate of photohemolysis at 80 mW/cm² was not increased when irradiations were carried out under an oxygen atmosphere this seems unlikely. Likewise, formation of singlet oxygen dimoles at high irradiances does not appear to be involved because the effect was unchanged when light exposure was in D₂O. While there is no ready explanation for this irradiance effect, it could be used to increase the safety margin of RBC virucidal treatment by employing exposure at high irradiance, thus minimizing the damage to RBC.     

INVESTIGATION OF POWER ABSORPTION BY METHYLENE BLUE IN A LIGHT SCATTERING MEDIUM WITH AN INTERNAL PHOTODYNAMIC ACTINOMETER

Abstract— Power absorption by aqueous solutions of methylene blue containing high concentrations of polystyrene microspheres was measured at 650 nm, using the photosensitized inactivation of subtilisin Carlsberg as an internal actinometer. The results were analyzed with the one-dimensional diffusion approximation for a finite slab. It is shown that the power absorption is determined by two macroscopic parameters, the optical penetration depth and the linear absorption coefficient. The optical penetration depth was determined independently by measuring flux profiles with an inserted fiber-optic method. The results are in satisfactory agreement with the predictions of the diffusion model, with microsphere diameters from 0.5 to 5 μm and a wide range of scatterer and dye concentrations. The presence of the scatterers diminished the power absorbed by the dye in all cases. The predictions of one-dimensional diffusion model are compared to Kubelka-Munk theory, and shown to be equivalent for optically dense systems     

PHOTODYNAMIC INACTIVATION OF YEAST SENSITIZED BY EOSIN Y

Abstract. Wild-type diploid yeast has been irradiated with visible light in the presence of eosin Y to investigate the photodynamic inactivation of this model eukaryote. Light, eosin Y and oxygen were all required for substantial inactivation, and no dark recovery was detected. Long periods of irradiation were required for greater than 90% inactivation, corresponding to a very small low-dose quantum yield. Neither binding nor uptake of the dye by yeast was detected. Corrections for the photooxidative bleaching of eosin Y during irradiation indicate that bleaching causes a significant reduction in the apparent rate of inactivation. The results suggest that eosin Y acts as an extracellular sensitizer where the likelihood of damage to the cell envelope is enhanced.     

PHOTODYNAMIC TREATMENT OF YEAST WITH CHLOROALUMINUM-PHTHALOCYANINE: ROLE OF THE MONOMERIC FORM OF THE DYE

The effect of photodynamic treatment on the yeast Kluyveromyces marxianus with aluminum-phthalocyanines has been studied. It was found that the nonsulfonated sensitizer caused light-dependent loss of colony-forming capacity, whereas the mono- and tetrasulfonated forms did not induce loss of clonogenicity. The effect of the nonsulfonated sensitizer increased with longer preincubation periods of cells with the dye. Formation of cellattached, mostly intracellularly localized monomelic sensitizer also increased with time. The amount of cell-bound multimeric nonsulfonated phthalocyanine did not vary with time. Experiments designed to specifically increase the amount of cell-attached monomers led also to an increased photoinactivation of the cells. It is therefore concluded that the photodynamic effect of the nonsulfonated Al-phthalocyanine is mediated by the monomeric form of the dye.     

A SURVEY OF IN VIVO PHOTODYNAMIC ACTIVITY OF XANTHENES, THIAZINES, AND ACRIDINES IN YEAST CELLS

Abstract. In view of the recent interest in the possibility of a singlet oxygen mechanism playing an important role in photodynamic action, a number of different types of dyes were surveyed with respect to cell inactivation and induction of genetic changes in yeast cells. These comprise three xanthene dyes, three thiazine dyes, three acridine dyes and ethidium bromide. Rhodamine B in the first group and methylene blue in the second group were inactive under the present conditions. Both were found to be non-penetrable into the cell. However, since toluidine blue is active, non-penetrability is not a determining factor in photodynamic action. Ethidium bromide was inactive under the present conditions, even though it was penetrable into the cell. The survey showed that the dye must be bound to DNA in order to be active in the induction of a genetic change (gene conversion). All dyes which were active in either inactivation or induction or both were modified in their effectiveness both by the addition of N^-₃ (suppression) and in deuterated medium (enhancement), indicating that the sensitization mechanism involves singlet oxygen. The deuterium effect was generally observable to a lesser extent in the in vivo situation than in vitro , in particular for genetic changes by profiavine and acriflavine in which the sensitizer binds to DNA.     

THE EFFECT OF PHOTODYNAMIC TREATMENT OF YEAST WITH THE SENSITIZER CHLOROALUMINUM PHTHALOCYANINE ON VARIOUS CELLULAR PARAMETERS

Photodynamic treatment of Kluyveromyces marxianus with chloroaluminum-phthalocyanine resulted in loss of clonogenicity. Several parameters were studied to identify targets that could be related to loss of colony-forming capacity. Inhibition of various plasma membrane-bound processes was observed, such as substrate transport and plasma membrane ATPase activity. Moreover, K+ loss from the cells was observed. Photodynamic treatment also reduced the activity of various enzymes involved in energy metabolism, thereby decreasing the cellular ATP level. It will be discussed however that none of these processes is likely to be related directly to loss of clonogenicity. Treatment with phthalocyanine and light resulted in a strong inhibition of the incorporation of 14C-phenylalanine in trichloracetic acid-precipitable material. The induction of the β-galactoside utilization system was also strongly inhibited. The latter two processes did not recover during incubation, subsequent to photodynamic treatment. It is concluded that photodynamically induced inhibition of protein synthesis is a critical factor contributing to the loss of clonogenicity.     

PHOTODYNAMIC DESTRUCTION OF LYSOSOMES MEDIATED BY NILE BLUE PHOTOSENSITIZERS

Previous studies have established that a number of Nile blue derivatives are potent photosensitizers and that they are localized primarily in the lysosomes. The present study examines whether the lysosome is a main target of the photocytotoxic action mediated by these sensitizers. Chosen for this study were NBS-61 and sat-NBS, which represented, respectively, derivatives with high and moderate degrees of lysosomal selectivity. Overall results indicated that both derivatives are very effective in mediating a photodestruction of lysosomes. This is indicated by the light-and drug-dose-dependent losses of acid phosphatase staining particles, reduction of hexosaminidase in the lysosomecontaining subcellular fraction, and impairment of the lysosomes to take up and sequester acndine orange. Ultrastructurally, swollen and ruptured lysosomes were seen as one of the first evidences of cell damage mediated by these photosensitizers. However, the study also showed that sat-NBS, which is less lysosomal selective, was less effective in mediating lysosomal destruction. Also, the degree of lysosomal destruction mediated by sat-NBS did not parallel the degree of cytotoxicity generated. This implies that for derivatives that are not exclusively localized in the lysosome, other subcellular sites may also be damaged by the photodynamic action and may play a role in the photocytotoxic process.     

INACTIVATION AND MUTAGENESIS OF Herpes VIRUS BY PHOTODYNAMIC TREATMENT WITH THERAPEUTIC DYES

Dyes which photosensitize membranes may be clinically useful for photodynamic treatment (PDT) of Herpes simplex virus (HSV) infections. It is important to determine whether the enveloped HSV can be inactivated via membrane damage without affecting the genetic material. Selection of appropriate PDT conditions, including the choice of dye, could minimize viral mutagenesis. We determined the mutagenesis caused by PDT employing three membrane-photosensitizing dyes of potential use in cancer photochemotherapy (Photofrin II, polyhematoporphyrin esters, zinc phthalocyanine tetrasulfonates) and a DNA-photosensitizing dye (proflavine sulfate). The effects were compared to those caused by exposure of HSV to ultraviolet radiation (UV). The procedure consisted of incubating HSV with microgram/ml (microM) concentrations of the dye, irradiating the samples with broad spectrum visible/near-UV radiation (Daylight fluorescent lamps) and assaying the survival of the treated HSV. Zinc phthalocyanine was the most potent dye per absorbed photon for inactivating HSV. In parallel with determination of survival, progeny of the surviving virus were grown for determination of mutagenesis. The progeny virus was harvested and subsequently assayed in the presence and absence of 40 micrograms/ml iododeoxycytidine (ICrd) to determine the frequency of mutation to ICrd resistance. Mutation frequencies were determined for progeny from the 1-4% survival level. For PDT with each membrane-photosensitizing dye, only zinc phthalocyanine increased the mutation frequency over the untreated control. This increase was less than 2-fold. Proflavine increased the mutation frequency 2-3 fold over the untreated control. Ultraviolet produced a 15-20 fold increase over the untreated control.(ABSTRACT TRUNCATED AT 250 WORDS)     

EFFECT OF PHOSPHATE AND CHLORIDE ON THE PHOTODYNAMIC INACTIVATION OF YEAST CELLS

Abstract— Yeast cells are inactivated by treatment with hematoporphyrin and light. The inactivation, which is mediated by singlet oxygen (¹O₂), is enhanced by the presence of phosphate and chloride. Neither phosphate nor chloride has any influence on the yield of ¹O₂. Possible mechanisms for the enhancement are briefly discussed.     

DNA LESIONS AND DNA DEGRADATION IN MOUSE LYMPHOMA L5178Y CELLS AFTER PHOTODYNAMIC TREATMENT SENSITIZED BY CHLOROALUMINUM PHTHALOCYANINE

Two closely related strains of mouse lymphoma L5178Y cells, LY-R and LY-S, have been found to differ in their sensitivity to the cytotoxic effects of photodynamic treatment (PDT) with chloroaluminum phthalocyanine (CAPC) and red light. Strain LY-R is more sensitive to photodynamic cell killing than strain LY-S. Differences in uptake of CAPC could not account for the differences in cytotoxic effects. There was no marked difference between the two strains in the induction of single-strand breaks (which includes frank single-strand breaks and alkali-labile lesions), but substantially more DNA-protein cross-links were formed in strain LY-R by CAPC and light. Repair of single-strand breaks proceeded with similar kinetics in both strains for the first 30 min post-irradiation, suggesting that these lesions are not responsible for the differential sensitivity of the two strains to the lethal effects of photodynamic treatment. Thereafter, alkaline elution revealed the presence of increasing DNA strand breakage in strain LY-R. DNA degradation, as measured by the conversion of prelabeled [14C] DNA to acid-soluble radioactivity, was more rapid and extensive in strain LY-R.     

甲苯胺蓝指示反应动力学光度法测定痕量钌

在磷酸和热水浴中 ,钌 (Ⅲ )对高碘酸钾氧化甲苯胺蓝的反应具有催化作用 ,据此建立了测定钌的新催化光度法。钌在 0～ 0 .0 5 0 μg/ 2 5ml范围内与催化反应速率有良好的线性关系 ,检出限为 5 .5 3× 10 - 5μg·ml- 1。对 0 .0 30 μg/ 2 5ml钌 (Ⅲ )测定的相对标准偏差为 2 .0 % (n =11)。该催化反应对钌 (Ⅲ )和甲苯胺蓝分别为一级反应 ,其表观活化能为 5 0 .2 6kJ·mol- 1。试验了 4 0多种共存离子的影响 ,大多数的常见离子不干扰。该方法用于岩矿和冶金产品中钌的测定 ,相对标准偏差为 2 .1%～ 2 .4 % ,标准加入回收率为 10 0 .1%～ 10 5 .4 %。     

STRESS PROTEIN EXPRESSION IN MURINE TUMOR CELLS FOLLOWING PHOTODYNAMIC THERAPY WITH BENZOPORPHYRIN DERIVATIVE

Abstract— Photodynamic therapy (PDT) has been proven as a method of tumor eradication and is currently being used clinically to treat a wide variety of malignancies. Although it is understood that the interaction of light and sensitizer results in the production of potentially damaging oxygen species, the mechanism by which tumors are destroyed has yet to be defined fully. Using a new porphyrin sensitizer, benzoporphyrin derivative(BPD), we examined protein expression in murine tumor cells following treatment as an indication of molecular changes to target tissue concurrent with PDT-mediated damage. In order to assess the relevance of the results obtained using an in vitro PDT model, metabolic labeling of proteins synthesized subsequent to PDT was performed both in tumor cells grown and treated in tissue culture dishes and in cells explanted from PDT-treated solid tumors. We observed that the oxidative stress associated with PDT-resulted in the induction of a number or proteins corresponding to a set of heat-shock or stress proteins, and that the pattern of expression was similar when tumor cells were treated in vitro and in vivo . These results support the use of in vitro models in the dissection of the molecular erects of PDT and provide the foundation for future experiments that will examine the role of the immune system in tumor eradication by PDT.     

PHOTODYNAMIC DAMAGE AND ITS REPAIR IN Vibrio cholerae

Abstract— Repair of photodynamic damage induced by acriflavine and visible light has been examined in three strains of Vibrio cholerae differing in their capabilities to repair ultraviolet (UV) light induced DN A damage. Excision repair deficient wild type cells of strain 154 are more sensitive to photodynamic treatment compared to repair proficient cells of strain 569B. However, no difference in their capabilities to repair of damage following photodynamic treatment can be detected. No single-strand breaks in the irradiated cell DNA are observed when the cell survival is more than 10%. Single-strand breaks observed at cell survival less than 5% are not dark repairable even in excision repair proficient wild type cells. Repair of membrane damage can partially account for the recovery observed at low doses. In contrast, radiation-sensitive mutant 569B_s cells which lack both excision and medium-dependent dark repair for UV-lesions are most efficient in repairing damage induced by photodynamic treatment.