PHOTODYNAMIC INACTIVATION OF CHINESE HAMSTER CELLS

Abstract— Visible light exposures have been shown to kill acriflavine bound Chinese hamster cells. Such killing was enhanced when (a) dye was present in the medium during irradiation and (b) the pH of the medium was 8.5, instead of the normal 7.5 during the exposure. The induced killing could be suppressed by the presence of sodium azide during exposure. The results were taken to indicate that both DNA and non-DNA sites were involved in the cellular inactivation by visible light and that singlet oxygen was involved in the process.     

THE PHOTODYNAMIC EFFECTS ONV–79 CHINESE HAMSTER CELLS

Abstract— Holding of acriflavine sensitizedV–79 cells in growth medium before visible light exposure decreases inactivation by visible light. The decrease depended upon the period of holding, indicating that there was release of cellular dye during this period. Exposures to visible light were done in two conditions: (a) with no dye in the medium during visible light exposure (washed) and (b) with dye in the medium during exposure (unwashed). Caffeine was found to slightly increase the sensitivity of the cells to visible light in the washed condition, whereas, in the unwashed condition no such effect was observed. Interaction studies with far UV did not reveal any correlation between photodynamic damage and UV damage. Visible light exposure of acriflavine sensitized cells was found to be mutagenic, as studied from the induction of 8-azaguanine resistant mutants. Inhibition of singlet oxygen production by sodium azide suppressed the induction of mutants. All these, taken together, have been discussed with respect to the relative importance of DNA and non-DNA damage in the photodynamic action of acriflavine.     

THE USE OF SPIN LABEL OXIMETRY IN THE STUDY OF PHOTODYNAMIC INACTIVATION OF CHINESE HAMSTER OVARY CELLS

Spin label oximetry has been used to study the effects of photosensitizer hematoporphyrin on oxygen consumption in Chinese hamster ovary cells. These measurements demonstrate that, in the presence of the sensitizer, there occurs (i) an increase in total oxygen consumption during irradiation and (ii) a decrease in oxygen consumption following irradiation. These results are attributed to the effects of photosensitized oxygen consumption and decreased cellular respiration due to cell inactivation. Thus the inhibition of oxygen consumption after irradiation was shown to correlate with decreased cell survival measured in cell culture experiments. Possible mechanisms of inactivation and extensions of the oximetric approach are discussed.     

PROTECTION BY THE FLUORIDE ION AGAINST PHTHALOCYANINE-INDUCED PHOTODYNAMIC KILLING OF CHINESE HAMSTER CELLS

When a dilute F- solution was added to a culture of Chinese hamster cells that had been preincubated with an aluminium phthalocyanine sensitizer derived from AlPcCl, the photosensitivity of the cells was markedly reduced compared to control cells not treated with F-. Under the same treatment conditions, the reduction in [3H]thymidine incorporation into cellular DNA caused by light and this sensitizer and the production of DNA-protein crosslinks caused by light and this sensitizer were also inhibited by F-. In contrast, the killing of Chinese hamster cells, the reduction of thymidine incorporation by the cells, and the production of DNA-protein crosslinks in the cells caused by the combination of light and either Photofrin II or the silicon phthalocyanine HOSiPcOSi(CH3)2(CH2)3-N(CH3)2 were not inhibited by F-. We conclude that the aluminium phthalocyanine sensitizer used is largely or completely AlPc(OH)(H2O), that it is converted to a fluoro complex by F-, and that this compound probably is a less efficient generator of photochemical damage at a critical cellular target(s) than is AlPc(OH)(H2O). The inhibition of thymidine incorporation and DNA-protein crosslink formation indicates that the effects of F- can be expressed at intracellular sites. It is further concluded that the silicon phthalocyanine sensitizer and Photofrin II do not interact significantly with F-.     

INDUCTION OF DNA-PROTEIN CROSS-LINKS IN CHINESE HAMSTER CELLS BY THE PHOTODYNAMIC ACTION OF CHLOROALUMINUM PHTHALOCYANINE AND VISIBLE LIGHT

Abstract— Chloroaluminum phthalocyanine (CAPC) is an efficient photosensitizer for the inactivation of Chinese hamster V79 cells. In order to investigate possible molecular mechanisms in the photo-dynamic action of CAPC and visible light, the induction and repair rate of two classes of DNA lesions have been determined, i.e. DNA single-strand breaks and DNA-protein cross-links. In cells pretreated with 1 μ.M CAPC, a fluence of 12 kJ/m² of red light (>600 nm) kills approximately 50% of the cells and induces 3 to 3.5 Gy-equivalents of single-strand breaks. The repair of these breaks was slower than the repair of single-strand breaks induced by -irradiation. The photodynamic action of CAPC also induces a large number of DNA-protein cross-links which, in contrast to -radiation-induced DNA-protein cross-links, do not appear to be repaired during 4 h of post-treatment incubation in fresh medium. These studies suggest that DNA may be an important target for the cytotoxicity of CAPC + red light.     

RESISTANCE TO PHOTODYNAMIC THERAPY IN RADIATION INDUCED FIBROSARCOMA-1 and CHINESE HAMSTER OVARY-MULTI-DRUG RESISTANT CELLS in vitro

A degree of resistance to photodynamic therapy (PDT) has been induced in radiation-induced fibrosarcoma-1 (RIF-1) tumor cells by repeated photodynamic treatment with Photofrin (4 or 18 h incubation) in vitro to the 0.1-1% survival level, followed by regrowth from single surviving colonies. The resistance is shown as increased cell survival in the strain designated RIF-8A, compared to the wild-type RIF-1 cells, when exposed to increasing Photofrin concentration for 18 h incubation and fixed light exposure. No difference was found between RIF-1 and RIF-8A in the uptake of Photofrin per unit cell volume at 18 h incubation. Resistance to PDT was also observed in Chinese hamster ovary-multi-drug resistant (CHO-MDR) cells compared to the wild-type CHO cells, possibly associated with decreased cellular concentration of Photofrin in the former. By contrast, the PDT-resistant RIF-8A cells did not show any cross-resistance to Adriamycin, nor was there any significant drug concentration difference between RIF-1 and RIF-8A. These findings suggest that different mechanisms are responsible for PDT-induced resistance and multi-drug resistance.     

LASER-LIGHT INDUCED CHROMOSOME ABERRATIONS IN CHINESE HAMSTER CELLS

Wild-type Chinese hamster cells CHO Kl and their radiosensitive mutant xrs5 were irradiated at 308 nm, using light pulses of a XeCl excimer laser with total energy fluences of 0.1 kj/m² to 4.08 kj/m². Chromosome-type and chromatid-type chromosome aberrations have been observed at pulse irradiances of 2.5 × 10⁷ W/m² and 1.7 × 10⁸ W/m², indicating that in mammalian cells DNA double-strand breaks occur already in this irradiance range. The results obtained with laser irradiation are compared with X-ray irradiation.     

PHOTOSENSITIZED INACTIVATION OF CHINESE HAMSTER CELLS BY PHTHALOCYANINES

Chloroaluminum phthalocyanine was found to sensitize cultured Chinese hamster cells upon exposure to white fluorescent light. Elimination of wavelengths below 370 nm did not reduce the effect significantly, indicating that the effective wavelengths were those absorbed by the Q band (600–700 nm) of phthalocyanine. The magnitude of the photosensitizing effect increased with the dye concentration and the time of its contact with the cells prior to light exposure. Although photosensitization was drastically reduced in the absence of oxygen, the lack of effect of glycerol and D₂0 during exposure suggests that neither hydroxyl radicals nor ¹O₂ are responsible for the cytotoxic response. The efficiency of the photosensitized induced cell killing did not vary with the position of the cells in the cell cycle, in contrast to exposure to X-rays. The improved spectral properties, the reported low toxicity and the selective retention by neoplasms, make phthalocyanines promising candidates for use in photodynamic therapy of cancer.     

THE FATE OF PYRIMIDINE DIMERS IN THE DNA OF ULTRAVIOLET-IRRADIATED CHINESE HAMSTER CELLS

Abstract —As an aid to understanding the relationship between dimer repair and cellular recovery, we have studied dimer removal and replication of dimer-containing DNA in Chinese hamster ovary (CHO) cells irradiated with ultraviolet light (254 nm). These investigations demonstrated that (1) dimers are not excised as polynucleotides of less than 500,000 mol. wt, (2) fractionation of the ultraviolet dose does not enhance dimer excision, (3) dimer-containing DNA is replicated in ultraviolet-irradiated CHO cells, and (4) the dimers are conserved in the replicated DNA. These findings support the proposed mechanism of bypass of photoproducts during DNA replication in mammalian cells.     

EFFECTIVE PHOTODYNAMIC ACTION BY RHODAMINE 123 LEADING TO PHOTOSENSITIZED KILLING OF CHINESE HAMSTER OVARY CELLS IN TISSUE CULTURE AND A PROPOSED MECHANISM

The effectiveness of rhodamine 123 (R123) as a photosensitizer of cell killing is relatively low and correlates with its inefficient production of singlet oxygen. The known selective retention of R123 in the mitochondria of epithelially derived carcinoma cells, however, is a selective feature that could lead to a more useful therapeutic ratio if photosensitizing effectiveness could be increased. Chinese hamster ovary (CHO) cells in tissue culture were therefore exposed to R123 shortly before and during illumination under conditions controlled for oxygen concentration and temperature. Effective photosensitization of cell killing, as judged by colony formation, was produced by 95% but not by 19% O₂ during illumination of cells at 5d?C or 37d?C, and this was additionally enhanced at the sublethal temperature of 42d?C. Two CHO cell lines were examined; one line, CHO-AA8, was proficient in the repair of DNA damage and the parent to the second line, CHO-EM9, that was deficient in the repair of DNA strand breaks. Cells of both lines incorporated R123 to a similar degree and were similarly photosensitized by the presence of igh oxygen concentration. Furthermore, plasma membrane damage as judged by teh exclusion of trypan blue was not observed immediately after illumination in the presence of R123, but was seen in the presence of meso-tetra-(4-sulfonatophenyl)-porphine (TPPS₄). The extent of damage to the plasma membrane by TPPS₄ was greater in the presence of 95% compared to 19% O₂ during illumination. Photodynamic action at the level of teh plasma membrane appears to contribute to photosensitization by TPPS₄ but not by R123 soon after exposure of cells to these sensitizers. It is hypothesized that photodynamic action by R123 is the primary mechanism causing the observed photosensitization of cell killing, and that mitochondria are teh site of photosensitized damage responsible for this killing.     

α-石英对离体巨噬细胞内游离Ca2+的影响

本文用荧光试剂Fura-2/AM和AR-CM-MlC阳离子测定系统研究了α-石英对离体肺泡巨噬细胞内游离Ca~(2+)的影响.结果表明:在含Ca~(2+)介质中,α-石英对巨噬细胞的毒性作用引起胞浆游离Ca~(2+)浓度的升高,α-石英剂量越大或作用时间增长,胞浆游离Ca~(2+)浓度升高越大,这种效应只能部分地被Ca~(2+)通道阻断剂异搏定所阻断.但在无Ca~(2+)介质中未观察到细胞胞浆游离Ca~(2+)浓度升高的现象.     

ADRIAMYCIN RESISTANCE IN CHINESE HAMSTER FIBROBLASTS FOLLOWING OXIDATIVE STRESS INDUCED BY PHOTODYNAMIC THERAPY

Photodynamic therapy (PDT) generates reactive oxygen species that are responsible for the initial cytotoxic events produced by this treatment. An extended (16 h) porphyrin incubation prior to light irradiation increased expression of the 75, 78 and 94 kDa glucose-regulated stress proteins (GRP), as well as the cognate form of the 70 kDa heat shock protein. However, these stress proteins were not induced following isoeffective PDT doses using a short (1 h) porphyrin incubation protocol. In the current study, Chinese hamster fibroblasts were used to examine sensitivity to adjunctive PDT and adriamycin as previous reports indicate a correlation between stress protein synthesis and a decrease in adriamycin cytotoxicity. Treatments that either induced GRP ( i.e . PDT with an extended porphyrin incubation or exposure to the calcium ionophore A23187) or did not induce GRP ( i.e . PDT with a short porphyrin incubation or UV irradiation) were followed at increasing time intervals with a 1 h adriamycin incubation. A time-dependent decrease in adriamycin cytotoxicity was observed when cells were first exposed to either of the PDT protocols or to A23187. Alterations in intracellular drug levels did not account for the change in adriamycin sensitivity. Likewise, intracellular glutathione concentrations and antioxidant enzyme activities were not significantly altered following PDT or A23187. Parameters associated with altered adriamycin sensitivity included a decrease in the percentage of S phase cells following PDT and A23187 as well as a depletion of intracellular ATP after PDT using the extended porphyrin incubation. These results demonstrate that PDT can be added to the growing list of diverse stresses producing transient resistance to adriamycin and that stress protein induction is not universally associated with all oxidative treatments inducing this resistance.     

DNA SINGLE-STRAND LESIONS DUE TO ''SUNLIGHT'' AND UV LIGHT: A COMPARISON OF THEIR INDUCTION IN CHINESE HAMSTER AND HUMAN CELLS, AND THEIR FATE IN CHINESE HAMSTER CELLS

Abstract— It has been shown that the lethal properties of germicidal UV light (254 nm) and sunlight-simulating near UV light are qualitatively different (Elkind et al ., 1978). Further to compare these two radiations, the induction of single-strand DNA breaks (i.e. frank breaks plus alkali-labile lesions) was measured in two cell lines. Equal numbers of breaks in Chinese hamster cells require a dose of UV 5.5% of a near UV dose but in HeLa cells a UV dose of 7.6% of a near-UV dose is required. The rate of break production by these radiations is about 1/10-th of that due to X-rays when a comparison is made on an equal killing dose basis. The inventory of breaks in Chinese hamster cells was also followed and was found to be characteristically different for UV compared to near UV light. These data indicate that significant differences exist, at a molecular level, in the effects produced by ultraviolet and sunlight-simulating light, and further emphasize the need for caution in attempting to extrapolate from observed molecular or biological effects due to the former to those to be expected from the latter.     

GENETIC TOXICOLOGY OF THE PHOTOSENSITIZATION OF CHINESE HAMSTER CELLS BY PHTHALOCYANINES

Chloroaluminum phthalocyanine (CAPC) was recently shown to photosensitize cell killing in culture and tumor destruction in vivo. Because this compound is potentially useful in the photodynamic therapy of cancer, its properties as a genotoxic agent were evaluated. Applying the technique of alkaline elution to study DNA integrity, it was found that CAPC could produce single-strand breaks in the DNA of Chinese hamster cells after exposure to white fluorescent light. At equicytotoxic doses, the number of DNA strand breaks produced by CAPC photosensitization was about three times lower than that induced by X-irradiation. During incubation in growth medium after exposure to CAPC-plus-fluorescent light, cells rejoined DNA strand breaks at a rate similar to that observed after X-irradiation. Resistance to 6-thioguanine (6-TG') or to ouabain (OUA') were used as end points of mutagenic potential. Following a treatment that caused -90% cell killing, there was a slight mutagenic effect, i.e. the frequencies were increased by -40% above the background or spontaneous mutations. However, this enhancement was not statistically significant. Taken together, the foregoing, plus an earlier observation that there is no variation in the sensitivity of cells to CAPC + light through the cell cycle, lead to the inferences that DNA damage does not play a major role in cell killing and that the mutagenic potential of this treatment is small.     

GENETIC EFFECTS OF UV-B: MUTAGENICITY OF 308 nm LIGHT IN CHINESE HAMSTER V79 CELLS

Abstract —Chinese hamster V79 cells were irradiated with 254 nm (UV-C) and 308 nm (UV-B) light, emitted by a germicidal lamp and an excimer laser, respectively. Induction of mutations at two distinct genetic loci was measured by selecting colonies resistant to 6-thioguanine or to ouabain. Unlike 6-thioguanine resistance which can be presumed to be due to many different types of genetic damage, mutation to ouabain resistance seems to result from base-pair substitution events only. Much higher doses of 308 than of 254 nm radiation are required to induce equivalent numbers of mutants. However, induction of cell inactivation and 6-thioguanine resistant mutations with the two UV sources appears to be correlated, suggesting that a common mechanism, perhaps involving the induction of pyrimidine-containing dimers, is involved. The frequency of ouabain resistant mutants per lethal event is on the other hand much higher after irradiation with the 308 nm light. This latter finding further defines a part of the UV-B spectral region which seems to induce a unique kind of DNA damage which specifically results in base-pair substitution events. Action spectra studies therefore appear necessary in the definition of the mutagenic effects of UV-B radiations in mammalian cells.     

ALKALINE ELUTION STUDIES OF HEMATOPORPHYRIN-DERIVATIVE PHOTOSENSITIZED DNA DAMAGE AND REPAIR IN CHINESE HAMSTER OVARY CELLS

Abstract We have used alkaline elution to study DNA damage produced by the photosensitizer hematoporphyrin derivative (HPD) in cultured Chinese hamster cells. Dosimetry was performed by measuring fluence and calculating photon absorption by intracellular HPD. HPD photosensitization causes DNA strand breakage. These breaks are repaired by the cell, although their fractional rate of repair is smaller than that for X-ray induced strand breaks at equivalent levels of strand breakage. The combined DNA polymerase inhibitors cytosine arabinoside and hydroxyurea suppress the repair of HPD-photosensitized breaks more strongly than they suppress repair of X-ray induced breaks. Addition of novobiocin to the aforementioned inhibitors causes almost total suppression of photosensitized break repair. A nucleotide excision repair system with inhibitor susceptibility similar to that of the system which removes pyrimidine dimers thus does not act upon HPD-photosensitized damage. The repair rate and inhibitor sensitivity findings together suggest biologically important differences in the chemical nature of X-ray induced and HPD-photosensitized strand breaks. In addition to strand breaks, HPD photosensitization produces covalent DNA-protein crosslinks, some of which persist through at least 90 min incubation, but which are repaired within 180 min.     

PHOTOINACTIVATION OF CHINESE HAMSTER CELLS BY HEMATOPORPHYRIN DERIVATIVE AND RED LIGHT

Abstract— The use of hematoporphyrin derivative (HpD) has previously been demonstrated to be beneficial in clinical cancer therapy. This paper describes cell culture studies used to examine HpD phototherapy in Chinese hamster ovary cells (line CHO). Survival curves have been obtained for both direct HpD toxicity and HpD induced photoinactivation. Examination of HpD induced photoinactivation as a function of stage in the cell growth cycle has also been performed, as has the quantitative measurement of HpD uptake in cells (using ³H-HpD) as a function of cellular incubation time, serum concentration in the incubation medium, and cell cycle position. In the absence of light, no toxicity was observed for HpD incubation levels of up to 400 μg/m/ when incubations times were 3 h or less. Exposure of cells to light alone (> 590 nm, 4.0 mW/cm²) for 9 min was also found to be completely nontoxic. Survival curves obtained for exponentially growing cells labeled with various concentrations of HpD and subsequently illuminated with red light exhibited a threshold or shoulder region at short exposure times followed by exponential killing at longer exposure times. The cell cycle response curves for HpD induced photoinactivation of synchronized CHO cells was nearly flat, indicating no variation in sensitivity for cells treated at time periods from 6 to 15 h after mitosis. Additon of serum to the incubation medium resulted in improved plating efficiency and reproducible survival curves but decreased cellular uptake of HpD.     

PHOTODYNAMIC EFFECTS OF HEMATOPORPHYRIN DERIVATIVE ON THE UPTAKE OF RHODAMINE 123 BY MITOCHONDRIA OF INTACT MURINE L929 FIBROBLASTS AND CHINESE HAMSTER OVARY Kl CELLS

Abstract— It was shown that the cationic fluorescence probe rhodamine 123 accumulates in mitochondria of murine L929 fibroblasts and Chinese hamster ovary Kl epithelial cells due to the driving force of both plasma membrane and mitochondrial membrane potentials. Photodynamic treatment of L929 cells with hematoporphyrin derivative resulted in an increased uptake of rhodamine 123 and a diminished uptake of 1,1,3,3,3',3'-hexamethylindocarbocyanine iodide. This indicates a considerably increased mitochondrial membrane potential, which most likely is the result of a direct or secondary inhibition of the ATP-synthetase, and a decreased plasma membrane potential. The oxygen consumption rate and the ATP level decreased due to photodynamic treatment. Post-incubation of L929 cells subsequent to photodynamic treatment revealed that the uptake of rhodamine 123. the ATP content and the oxygen consumption rate were restored. For all parameters similar results were obtained with CHO-K1 cells, with the exception that during post-incubation the intracellular ATP content remained at the level reached after illumination. These results indicate that photodynamically induced disturbance of mitochondrial functions and the ATP level are not crucial for the loss of clonogenicity of L929 cells. In CHO-K1 cells however, the continuously lowered ATP level may have detrimental consequences for cell survival. The photodynamic stimulation of the rhodamine 123 uptake may be a rather general phenomenon. Because rhodamine 123 exhibits a much higher toxicity towards carcinoma cells than towards other cells, a synergistic interaction between this drug and photodynamic therapy (PDT) may be anticipated, if PDT also stimulates mitochondrial rhodamine 123 accumulation in carcinoma in vivo.