John Van Steveninck

Toxicity of organotin compounds for polymorphonuclear leukocytes: The effect on phagocytosis and exocytosis

Phagocytosis and concomitant release of enzymes by rabbit polymorphonuclear leukocytes (PMNs) are inhibited by micromolar concentrations of triphenyltin and tributyltin; inhibition by triethyltin occurs at higher concentrations. Chemotactic peptide-induced exocytosis is inhibited at the same concentrations as phagocytosis. Tributyltin causes cell lysis at slightly higher concentrations as required for inhibition of phagocytosis and exocytosis. The organotin compounds have little effect on ATP level in PMNs, which makes an effect on metabolic energy providing processes unlikely. The increase of Ca2+-permeability of the plasma membrane, induced by chemotactic peptide, is inhibited by the organotin compounds. Inhibition of exocytosis by triphenyltin can be counteracted by a number of sulfhydryl compounds. The results suggest that the organotin compounds interfere with PMN function in an early phase of cell activation, where all functions have a common pathway, and where vulnerable sulfhydryl groups play a pivotal role.

Photodynamic treatment of yeast cells with the dye Toluidine blue : all-or-none loss of plasma membrane barrier properties

Photodynamic treatment of Kluyveromyces marxianus with the sensitizer Toluidine blue leads to the loss of colony forming capacity. In this paper, the influence of this treatment on the barrier properties of the plasma membrane has been studied. Photodynamic treatment with the dye Toluidine blue resulted in efflux of potassium ions and E260-absorbing material. Moreover, cells became stainable with erythrosine. It is concluded that the permeability change induced by photodynamic treatment proceeds in an all-or-none fashion. Treatment of this yeast strain, with the dye and light, also induced a diminution of the cell volume. This process is most likely not coupled to the cellular potassium content, but rather to the integrity of the vacuole. These data suggest that the vacuole has an important function in the maintenance of cell volume. Finally, it was observed that the loss of cell viability was not induced by the all-or-none loss of barrier properties.

Inhibition of lipid peroxidation by disulfiram and diethyldithiocarbamate does not prevent hepatotoxin-induced cell death in isolated rat hepatocytes. A study with allyl alcohol, tert-butyl hydroperoxide, diethyl maleate, bromoisovalerylurea and carbon tetrachloride

The relationship between lipid peroxidation and cell death, induced by a number of hepatotoxins, was studied in isolated rat hepatocytes. Disulfiram (DSF) and diethyldithiocarbamate (DDC) completely prevented lipid peroxidation, induced by allyl alcohol, tert-butyl hydroperoxide (t-BHP), diethyl maleate (DEM), bromoisovalerylurea (BIU) and carbon tetrachloride (CCl4). Lipid peroxidation was measured by the formation of both thiobarbituric acid positive material and conjugated dienes. However, DSF and DDC did not protect against cell death, induced by these hepatotoxins. In the presence of DSF or DDC, cell death occurred even earlier in time. We conclude that cell death can occur in the absence of lipid peroxidation. Therefore, lipid peroxidation is not a requisite for the induction of cell death.

INTRACELLULAR DAMAGE IN YEAST CELLS CAUSED BY PHOTODYNAMIC TREATMENT WITH TOLUIDINE BLUE

Abstract— The positively charged photosensitizer toluidine blue (TB) can induce loss of clonogenicity in Kluyveromyces marxianus. Previous studies have revealed that, as a consequence of the localization of this dye at the cell surface, photodynamic action results in extensive damage at the level of the plasma membrane. In this paper, a study is reported on the effect of photodynamic treatment with TB on intracellular enzymes. It is shown that treatment with TB and light resulted in the inhibition of alcohol dehydrogenase, cytochrome c oxidase, glyceraldehyde‐3‐phosphate dehydrogenase and hexokinase. Photodynamic treatment also lowered the ATP levels. The ATP levels could be partially restored in the presence of glucose but not with ethanol. Toluidine blue binding experiments revealed that photodynamic treatment caused a rapid increase in the amount of cell‐associated dye. Moreover, it also appeared that this treatment decreased the binding of TB to the cell surface. It is concluded that TB enters the cell during the first minutes of illumination, whereafter intracellular enzymes are inactivated. The data indicate that photodynamic damage of intracellular sites contributes to the loss of viability.

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.

Relationship between photodynamically induced damage to various cellular parameters and loss of clonogenicity in different cell types with hematoporphyrin derivative as sensitizer

The possible causal relationship between various forms of photodynamically inflicted damage and reproductive cell death of cultivated cells was evaluated according to three criteria. The probability for the existence of such a relationship is high, when the particular form of cellular damage (i) exhibits a dose-effect curve, comparable to the dose-effect curve of loss of clonogenicity, (ii) is not readily repairable during further incubation of the treated cells and (iii) varies in a way comparable to the loss of clonogenicity under varying experimental conditions. According to these criteria it could be shown that many forms of photodynamically inflicted cellular damage are presumably not directly involved in loss of clonogenicity. Only for a few kinds of cellular damage studied in the present investigations was the probability for a causal relationship with reproductive cell death much higher. For L929 fibroblasts this is either an inhibition of the Na+/K(+)-ATPase activity, or a relatively slight DNA damage combined with a strong inhibition of DNA excision repair. For T24 human bladder carcinoma cells the kinds of cellular damage that may be causally related to reproductive cell death are again inhibition of Na+/K(+)-ATPase activity, inhibition of amino-acid (AIB and glycine) transport activity or impairment of mitochondrial function. Finally, for CHO cells, inhibition of leucine and phenylalanine transport and impairment of mitochondrial function may be crucial for loss of clonogenicity. These results indicate that the pathways leading to photodynamically induced reproductive cell death may be quite different for different cell types.

Inhibition of transport systems in yeast by photodynamic treatment with Toluidine blue

Photodynamic treatment of yeast with the sensitizer Toluidine blue results in loss of cell viability. In previous investigations it was suggested that plasma membrane damage might be responsible for the loss of colony forming capacity. In this context the influence of photodynamic treatment on transmembrane transport systems was studied. It appeared that the uptake of the sugars glucose, lactose and galactose, the amino acids arginine, phenylalanine, glycine and aspartic acid and of the inorganic compound phosphate was inhibited by photodynamic treatment. The different elements of the energy providing system necessary for active transport, viz. the plasma membrane ATPase and the protonmotive force, were not significantly affected by Toluidine blue and light, indicating that inhibition of transport is not caused by a reduction of the membrane potential or the transmembrane pH gradient. These observations suggest that the transport carriers themselves were damaged by treatment with Toluidine blue and light. This could be confirmed in experiments, in which the lactose and galactose transport proteins of treated and untreated cells were reconstituted in plasma membrane vesicles. It appeared that the carriers, obtained from photodynamically treated Kluyveromyces marxianus cell, had lost their transport capacity.

Effect of Fluoride on Inhibition of Plasma Membrane Functions in Chinese Hamster Ovary Cells Photosensitized by Aluminum Phthalocyanine

Fluoride inhibits photohemolysis induced by chloroaluminum phthalocyanine tetrasulfonate (AlPcS4) when it is added to dye-loaded human erythrocytes prior to light exposure (E. Ben-Hur, A. Freud, A. Canfi, and A. Livne, Int. J. Radiat. Biol. 59, 797-806, 1991). This is due to formation of a complex of F- with Al3+, leading to selective release and/or modified dye binding with some proteins so that the effective photochemical reaction is prevented. In this work we used F- as a probe to evaluate the involvement of the plasma membrane functions of Chinese hamster ovary cells in photocytotoxicity induced by chloroaluminum phthalocyanine (AlPc). Fluoride was found to protect against killing of cells photosensitized by AlPc but not AlPcS4. Plasma membrane damage induced by AlPc photosensitization was manifested by K+ leakage, membrane depolarization, inhibition of glucose and amino acid uptake, and Na+/K(+)-ATPase inactivation. The latter enzyme system was found to be the one most sensitive to inhibition by the combination of AlPc and PDT among the membrane functions studied, and was completely protected by F- in the dose range at which up to 95% of the cells are killed. Of the other membrane functions only glucose transport was slightly protected by F-. It is concluded that damage to the plasma membrane is involved in cell killing induced by AlPc photosensitization and that the plasma membrane enzyme Na+/K(+)-ATPase is a probable candidate as a critical target.

The Role of Protein Kinase C Activity in the Killing of Chinese Hamster Ovary Cells by Ionizing Radiation and Photodynamic Treatment

In several recent studies it has been shown that protein kinase C (PKC) activity may either potentiate or antagonize cell killing by different cytotoxic agents. These apparently conflicting observations suggest that the effects of PKC activity on cell survival may depend on the different properties of different cell types but do not exclude the possibility that the effects may also depend on the nature of the cytotoxic agent. In this context the effects of PKC activation and PKC inhibition or down‐regulation on Chinese hamster ovary (CHO) cell survival after photodynamic treatment and ionizing radiation were studied. It appeared that PKC activation by short‐term incubation with 12‐0‐tetradecanoyl‐phorbol‐13‐acetate (TPA) protected CHO cells against ionizing radiation but, in contrast, sensitized the cells to photodynamic treatment. Conversely, inhibition of PKC by H7 and down‐regulation of PKC activity by prolonged incubation with TPA sensitized CHO cells to ionizing radiation but protected the cells against photodynamic treatment. These results demonstrate that in one particular cell type PKC activity may have opposite effects on cell survival following cellular damage, depending on the nature of the cytotoxic agent.

Anomalous properties of water in macromolecular gels

Low molecular weight solutes often exhibit elution characteristics on gel filtration columns which deviate from ideal behaviour. In many previous studies this anomalous behaviour was attributed to the existence of extremely narrow pores in the gel, inaccessible even to very small solute molecules, to explain Kd values lower than unity. Kd values of small solutes higher than unity were usually ascribed to adsorption of the solute to the gel matrix. In the present paper several observations are presented that contradict these suggestions. Experimental evidence indicates that with small solute molecules Kd values differing from unity can be fully explained by the anomalous properties of vicinal water layers at the gel matrix-water interface.