Protoporphyrin-sensitized photodynamic modification of proteins in isolated human red blood cell membranes

Inhibition of substance P-induced histamine release from rat peritoneal mast cells by low doses of protoporphyrin plus long-wave ultraviolet light irradiation: decreased intracellular calcium as a possible mechanism

BACKGROUND

A considerable amount of recent interest has been devoted to the down-regulatory effects of photosensitizers plus long-wave ultraviolet light (UVA) irradiation on multiple biologic systems. However, these effects on mast cells are controversial.

OBJECTIVE

We have investigated the effect of low doses of protoporphyrin (PP) plus UVA irradiation (PP/UVA) on substance P (SP)-induced histamine release from rat mast cells.

METHODS

Rat peritoneal mast cells purified on a Percoll gradient were treated with 3 ng/mL PP and/or UVA, and challenged with SP. In some experiments, IgE-sensitized mast cells were stimulated by antirat IgE in the presence of phosphatidylserine. Histamine released from mast cells and intracellular calcium concentrations ([Ca2+]i) were measured, respectively.

RESULTS

SP at a concentration of 10(-5) mol/L caused a significant histamine release with the increase in [Ca2+]i. PP or UVA irradiation alone at doses used in the present study induced no histamine release from mast cells and had no significant effects on SP-induced histamine release from the cells. On the other hand, PP/UVA inhibited SP-induced histamine release in a dose-dependent manner of UVA with the reduction of SP-induced maximal increases in [Ca2+]i. Comparing with the inhibitory effects of PP/UVA on anti-IgE-induced histamine release from IgE-sensitized mast cells and maximal increases in [Ca2+]i in the cells, the inhibitory effects of PP/UVA on the findings in SP-stimulated mast cells were less.

CONCLUSION

These data suggest that low doses of PP/UVA inhibits histamine release from SP-activated rat peritoneal mast cells through the suppression of [Ca2+]i.

The role of membrane-bound porphyrin-type compound as endogenous sensitizer in photodynamic damage to yeast plasma membranes

The effect of visible light (400-600 nm) on Candida guilliermondii and Saccharomyces cerevisiae was studied, and irradiation fluences killing the yeast cells without exogenous sensitizers were determined. The lethal effects are strongly oxygen-dependent, suggesting the involvement of photodynamic reactions mediated by endogenous sensitizer(s). Repair-deficient strains of S. cerevisiae show the same photosensitivity as the wild-type strain indicating that visible light does not photosensitize repairable DNA lesions. As was demonstrated using the microfluorometric method with the fluorochrome primulin, photodestruction of plasma membrane permeability barriers is important for yeast cell lethality. Visible light at cell-killing fluences induces lipid peroxidation in plasma membrane ghosts isolated from C. guilliermondii. Data obtained suggest the important role of singlet oxygen photogenerated by endogenous sensitizer(s) in initiating oxidative reactions. A spectrofluorometric analysis of the plasma membrane ghosts revealed one compound fluorescent in the visible spectral region at 683 nm. Its fluorescence excitation and absorption spectra have structures typical for porphyrins. The plasma membrane-bound porphyrin-like compound is different in some fluorescence properties from mitochondrial porphyrins. Estimation of its amount gives a value of 0.1 nmol porphyrin per milligram of protein of the plasma membrane ghosts. This porphyrin-type compound is considered to be the most probable candidate for the role of the sensitizer in photodynamic damage to yeast plasma membrane and cell inactivation by visible light.

Sulfophthalocyanines for photodynamic inactivation of viruses in blood products: effect of structural modifications

Transmission of infectious disease through blood transfusions is well known. Ultraviolet irradiation, solvents, and detergents provide a means of sterilizing noncellular blood components. However, these harsh methods are not applicable to cellular blood products. Recently, attempts have been made to sterilize biological fluids using photodynamic treatment and phthalocyanine (Pc) dyes have been advanced as photosensitizers for this purpose. We have evaluated a series of water-soluble Pc, chelated with different central metal ions, substituted to different degrees with sulfonato and t-butyl groups, for their effectiveness to reduce virus infectivity in red blood cell suspensions. Vaccinia virus cytopathogenicity was determined by endpoint serial dilutions in the CV-1 cell line. Anti-viral activity increased with the central metal ion in the following: Ga(III) < Al(III) < Zn(II), and varied inversely with the degree of sulfonation. Furthermore, addition of a t-butyl group onto the trisulfonated dyes (PcS3[t-Bu]) resulted in a 5-40-fold increase in anti-viral potency, suggesting that amphiphilicity enhances the photodynamic activity of the dye. Strong anti-viral photosensitizing properties cannot be the sole selection criterion. Of equal importance is the preservation of blood component integrity. Accordingly, the photohemolytic activity of the dyes was evaluated using the rate of hemolysis as a parameter and a toxicity index was defined. Among the most active dyes, the AlPcS3(t-Bu) complex exhibited the most favorable anti-viral properties combined with a low toxicity index. Our results suggest that trisulfophthalocyanines, bearing an additional t-butyl group to enhance amphiphilicity, are particularly promising dyes for photodynamic blood sterilization.

Light-dependent effects of zinc protoporphyrin IX on endothelium-dependent relaxation resistant to N omega-nitro-L-arginine

Acetylcholine (ACh) induces an N omega-nitro-L-arginine (L-NOARG)-resistant relaxation and hyperpolarization in the rat isolated hepatic artery. The possibility that carbon monoxide (CO) produced by haem oxygenase (HO) is an endogenous mediator of this response was investigated. Exogenously applied CO evoked a concentration-dependent relaxation, and the CO 'scavenger' oxyhaemoglobin (10 microM) reduced the maximum ACh-induced relaxation by 25%. The HO inhibitor zinc protoporphyrin IX (ZnPP, 10 microM) virtually abolished the ACh-induced relaxation in experiments carried out under ordinary light conditions. However, ZnPP did not affect the ACh-induced relaxation under dark conditions, even after exposure of ZnPP to intense light before the preincubation period. Biliverdin (0.1 mM), a feedback inhibitor of HO, was also inactive under dark conditions, and the HO substrate haematin (0.1 mM) did not facilitate the ACh-induced relaxation. The relaxation induced by the nitric oxide (NO) donor 3-morpholino-sydnonimin was not affected by ZnPP in the presence of light. However, ZnPP inhibited the relaxation evoked by the potassium channel opener levcromakalim and the tonic component of the contractile response to 60 mM potassium, indicating that ZnPP has effects distinct from HO inhibition in the presence of light. ZnPP should therefore be protected from light when used to inhibit HO-mediated CO formation. The results do not suggest that CO generated by HO mediates the endothelium-dependent, L-NOARG-resistant relaxation induced by ACh in the rat hepatic artery.

Ca2+ influx induced by photodynamic action in human cerebral glioma (U-87 MG) cells: possible involvement of a calcium channel

The plasma membrane has been implicated as a critical target of photodynamic action on cells. We have observed that the photosensitization of human cerebral glioma (U-87 MG) cells by hematoporphyrin derivative (HpD) causes a large increase in intracellular calcium [Ca2+]i. This increase in [Ca2+]i was solely due to the influx of extracellular Ca2+ through the plasma membrane and showed a dependence on HpD concentration, light dose and concentration of calcium in the extracellular medium. The magnitude of the Ca2+ influx decreased with increasing postirradiation time, which suggests that the cell membrane partially recovers from the photodynamic injury. The photoinduced Ca2+ influx was inhibited by the Ca2+ channel blocker diltiazem and the reducing agent dithioerythritol. These findings are discussed in terms of possible activation of a Ca2+ channel as a result of photosensitization.

Phthalocyanine-induced photohemolysis: structure-activity relationship and the effect of fluoride

Phthalocyanine (Pc) containing A1, Ga or Zn as central metal ligand and substituted with a varying number of sulfonic acid residues as well as additional benzene rings were synthesized and their photodynamic activity was assayed using photohemolysis of human erythrocytes as an endpoint. The Pc derivatives varied > 300-fold in their photodynamic activity. Activity correlated with binding of the dye to the cell, with the exception of some of the amphiphilic dyes where cell uptake was an order of magnitude higher than expected from the observed activity. Fluoride was shown to inhibit A1PcSn-induced photohemolysis. This effect occurred also with other A1Pc and GaPc derivatives, but the concentration of F- required to slow photohemolysis by a factor of two (Ki) varied between 4 microM and 10 mM. Fluorescence spectral studies indicated complex formation between F- and the dye, which was stronger for A1Pc than GaPc derivatives. Ultrastructural studies using scanning electron microscopy showed that the photosensitized cells were converted to spherocytes and that F- prevented this to a large extent.

Photobiological activities of 1,6-dioxapyrene in pro- and eukaryotic cells

The photobiological effect of a new pyrene derivative, 1,6-dioxapyrene (1,6-DP), was studied in Salmonella typhimurium (strain TA100) and in the diploid strain D7 of the yeast Saccharomyces cerevisiae. In Salmonella, 1,6-DP shows little mutagenicity in the dark in comparison to benzo[a]pyrene (B[a]P). This mutagenic activity decreases in the presence of liver S9 homogenates from Aroclor induced XVIInc/Z mice. However, in combination with 365 nm (UVA) radiation and in the absence of S9 mix, 1,6-DP behaves as an effective photodynamic compound inducing lethal and mutagenic effects in both organisms. In yeast, its activity, like that of B[a]P, is highly dependent on the presence of oxygen. For the same incident dose of UVA, 1,6-DP is, however, at least 6 times more effective than B[a]P in inducing cytotoxic and mutagenic effects. At equitoxic doses, 1,6-DP is as photomutagenic as B[a]P, suggesting that in both cases mutagenicity is due to similar mechanisms. Spectrophotometric measurements indicate physical interaction of 1,6-DP with DNA in the dark. Laser flash photolysis experiments show that 1,6-DP generates singlet oxygen with a quantum yield of 0.17. In vitro 1,6-DP produces oxidative damage to guanine bases specific for singlet oxygen mediated reactions. Alkaline step elution analysis of 1,6-DP plus UVA treated yeast cells indicates a decrease in average molecular weights in DNA and an induction of single strand breaks (ssb) originating from alkali labile sites. This effect is enhanced by D2O and is thus likely to be due to the production of singlet oxygen. The strand breaks appear to differ from those induced by gamma-rays because little, if any, repair of these ssb occurs during 30 min of post-treatment incubation in complete growth medium. These results suggest that the photobiological effects of 1,6-DP are due to oxidative damage in DNA mostly induced by singlet oxygen.

The effect of fluoride on binding and photodynamic action of phthalocyanines with proteins

Fluoride inhibits chloroaluminum phthalocyanine tetrasulfonate (AlPcS)-induced photohemolysis when added to dye loaded cells prior to light exposure. The mechanism by which F- exerts this effect was studied by measuring the binding of phthalocyanine (Pc) to various proteins in the absence and presence of F-. Parallel measurements were made of the photodynamic action under these conditions. Fluoride reduced the binding to proteins of AlPcS and CoPcS. The binding of CuPcS, ZnPcS and H2PcS was not affected. When bound to bovine serum albumin and exposed to light, H2Pc, ZnPc and AlPcCl were bleached at a biphasic rate. Only the photobleaching of AlPcCl was affected by F-. The effect of F- was to inhibit the initial rapid phase without affecting the slower phase. In the presence of D2O only the second phase of photobleaching was enhanced, in the absence or presence of F-. No effect of F- was observed on tryptophan photooxidation or glyceraldehyde-3-phosphate dehydrogenase photoinactivation by AlPcS. Crosslinking of spectrin monomers photosensitized by AlPcS was inhibited by F- in parallel with the reduced binding of dye to the protein. It is concluded that F- exerts its effect by complexing with metal ligands of Pc. As a result, the dye may be released from the protein or the binding mode may be changed in such a way that effective photochemistry is prevented. Primary photophysical processes of Pc most probably are not affected by F-.

Photooxidation of specific residues in alpha-crystallin polypeptides

Singlet oxygen is a biologically important, photochemically generated species that preferentially oxidizes His, Trp, and Met residues of protein molecules. Calf alpha-crystallin was photooxidized with use of meso-tetra(p-sulfonatophenyl)porphyrin (TPPS) and uroporphyrin (UP) as singlet oxygen generators. The effects of photooxidation were monitored by analyzing the changes in alpha-crystallin peptide maps obtained by reversed-phase HPLC using a photodiode array absorbance detector. The reaction led to the loss of six specific peptides, five of which contained photooxidizable residues. Peptides containing His-97 and His-154 from the A chain and Met-68 from the B chain are preferentially photooxidized, suggesting that those residues have access to singlet oxygen. Trp residues in the N-terminal region are converted to NFK, whereas Trp-60 in the B chain is not photooxidized strongly suggesting that the former are close to the surface of alpha-crystallin while the latter Trp residue is buried. Only one peptide that is lost from the peptide maps does not contain a photooxidizable group; however, this peptide does contain an apparently undigested Lys residue. It is suggested that it forms a cross-link with a photooxidized His residue.

Potentiation of thermal inactivation of glyceraldehyde-3-phosphate dehydrogenase by photodynamic treatment. A possible model for the synergistic interaction between photodynamic therapy and hyperthermia

Thermal inactivation of glyceraldehyde-3-phosphate dehydrogenase appeared to be caused by a conformational mechanism, without involvement of covalent reactions. On the other hand, photodynamic inactivation of the enzyme (induced by illumination in the presence of Photofrin II) was caused by photo-oxidation of the essential thiol group in the active centre. A short photodynamic treatment of the enzyme, leading to only a limited inactivation, caused a pronounced potentiation of subsequent thermal inactivation, as measured over the temperature range 40-50 degrees C. Analysis of the experimental results according to the Arrhenius equation revealed that both the activation energy of thermal inactivation and the frequency factor (the proportionality constant) were significantly decreased by the preceding photodynamic treatment. The experimental results indicate a mechanism in which limited photodynamic treatment induced a conformational change of the protein molecule. This conformational change did not contribute to photodynamic enzyme inhibition, but was responsible for the decreased frequency factor and activation energy of subsequent thermal inactivation of the enzyme. The opposing effects of decreased activation energy and decreased frequency factor resulted in potentiation of thermal inactivation of the enzyme over the temperature range 40-50 degrees C. With other proteins, different results were obtained. With amylase the combined photodynamic and thermal effects were not synergistic, but additive, and photodynamic treatment had no effect on the frequency factor and the activation energy of thermal inactivation. With respect to myoglobin denaturation, the photodynamic and thermal effects were antagonistic over the whole practically applicable temperature range. Limited photodynamic treatment protected the protein against heat-induced precipitation, concomitantly increasing both the frequency factor and the activation energy of the process. These results offer a model for one of the possible mechanisms of synergistic interaction between photodynamic therapy and hyperthermia in cancer treatment.

Different characteristics of ferrochelatase in cultured fibroblasts of erythropoietic protoporphyria patients and normal controls

Ferrochelatase activity was measured in crude extracts of fibroblasts, obtained from erythropoietic protoporphyria patients and healthy controls. The enzyme activity in erythropoietic protoporphyria fibroblasts was about 50% lower, compared to the controls. The sulfhydryl-oxidising reagent diamide inhibited the normal enzyme by about 50%, whereas ferrochelatase from erythropoietic protoporphyria fibroblasts was completely insensitive to the reagent. Pb2+ inhibits ferrochelatase activity by reacting with essential sulfhydryl groups. Low concentrations of Pb2+ inhibited the normal enzyme by 56%, but the mutant enzyme by only 8%. The photodynamic activity of bound mesoporphyrin substrate caused a biphasic inactivation of the normal enzyme. During the first 5 min of illumination a fast decrease of enzyme activity occurred to about 60% of the initial value. Experimental evidence indicates that this first phase of inactivation is caused by photooxidation of sulfhydryl groups. During further illumination inactivation continued at a much slower rate. With ferrochelatase from erythropoietic protoporphyria fibroblasts only the second, slow phase of photodynamic inactivation was observed. These observations suggest a mutation of ferrochelatase in erythropoietic protoporphyria, affecting the reactivity of sulfhydryl groups, involved in the catalytic activity of the enzyme.

Protein damage, induced by small amounts of photodynamically generated singlet oxygen or hydroxyl radicals

The influence of limited oxidation of glyceraldehyde-3-phosphate dehydrogenase (D-glyceraldehyde-3-phosphate:NAD+ oxidoreductase (phosphorylating), EC 1.2.1.12), alcohol dehydrogenase (alcohol:NAD+ oxidoreductase, EC 1.1.1.1) and myoglobin by singlet oxygen and by hydroxyl radicals was investigated. The intrinsic fluorescence of glyceraldehyde-3-phosphate dehydrogenase and alcohol dehydrogenase decreased rapidly during oxidation, indicating a conformational change of the protein molecules. The free energy of isothermal unfolding in urea solutions was increased by singlet oxygen, but decreased by hydroxyl radical attack. The velocity of refolding of the denatured protein after dilution of the denaturant was increased by exposure to either singlet oxygen or hydroxyl radicals, with one exception: the velocity of refolding of myoglobin, oxidized by singlet oxygen, was strongly decreased. Hydroxyl radicals produced covalently crosslinked protein aggregates and some fragmentation, whereas singlet oxygen produced only crosslinked aggregates with glyceraldehyde-3-phosphate dehydrogenase and alcohol dehydrogenase. All oxidized proteins were more susceptible to proteolysis by elastase and proteinase K, as compared to the undamaged proteins. Singlet oxygen-induced crosslinked aggregates were degraded very rapidly by elastase. Hydroxyl radical-induced aggregates of glyceraldehyde-3-phosphate dehydrogenase were also degraded very rapidly by this enzyme, but hydroxyl radical-induced aggregates of alcohol dehydrogenase were resistent to enzymatic degradation. The results indicate that limited protein oxidation may have a pronounced influence on several properties of the protein. The effects vary, however, with varying proteins and with the oxidizing species.

Photodynamic and non-photodynamic action of several porphyrins on the activity of some heme-enzymes

The action of porphyrins, uroporphyrin I and III (URO I and URO III), pentacarboxylic porphyrin I (PENTA I), coproporphyrin I and III (COPRO I and COPRO III), protoporphyrin IX (PROTO IX) and mesoporphyrin (MESO), on the activity of human erythrocytes delta-aminolevulinic acid dehydratase, porphobilinogenase, deaminase and uroporphyrinogen decarboxylase in the dark and under UV light was investigated. Both photoinactivation and light-independent inactivation was found in all four enzymes using URO I as sensitizer. URO III had a similar action as URO I on porphobilinogenase and deaminase and PROTO IX exerted equal effect as URO I on delta-aminolevulinic acid dehydratase and uroporphyrinogen decarboxylase. Photodynamic efficiency of the porphyrins was dependent on their molecular structure. Selective photodecomposition of enzymes by URO I, greater specificity of tumor uptake by URO I and enhanced porphyrin synthesis by tumors from delta-aminolevulic acid, with predominant formation of URO I, underline the possibility of using URO I in detection of malignant cells and photodynamic therapy.

A study on the sequence of phototoxic effects of rose bengal using retinal pigment epithelial cells in vitro

This paper describes a study on the sequence of the phototoxic effects of rose bengal (RB), a fluorescein derivative used as a vital stain in the diagnosis of certain external ocular diseases. Bovine melanotic RPE cells were grown in culture. These cells were labeled with [51Cr] and exposed to visible light in the presence of various concentrations of RB; the leakage of [51Cr] from the cells was used as a measure of cell lysis. Exposure to light of the cells with 0.3-10 microM RB induced approximately 13 to 43% cell lysis. The lysis progressively increased when the exposure time was varied from 10 to 30 min. A relatively short period of irradiation in the presence of RB was sufficient to produce sublytic cellular injury which could subsequently lead to complete cell lysis even in the absence of the photochemical treatment. The dark reaction was time-dependent, and reached a maximum for a given irradiation period. Our results thus show that there are two different processes that could eventually lead to the cell lysis: (a) a phototoxic effect which caused a sublytic damage and (b) a dark reaction that followed.

Enhancement of transbilayer mobility of a membrane lipid probe accompanies formation of membrane leaks during photodynamic treatment of erythrocytes

In order to further characterize membrane alterations in human erythrocytes subjected to photodynamic treatment the passive transbilayer mobility of a phospholipid analogue was studied in cells illuminated for various lengths of time in the presence of the photosensitizer, aluminum chlorotetrasulfophthalocyanine. These measurements were combined with the characterization of the membrane leaks for polar solutes occurring under the same conditions with respect to their apparent size, number and ion selectivity. The time-dependent photodynamic enhancement of leaks for K+ as well as choline or erythritol was paralleled by a marked increase of the transbilayer reorientation rate of the amphiphilic lipid probe, palmitoyllysophosphatidylcholine from 0.05% min-1 in native cells to 0.32% min-1 after 60 min illumination. The asymmetric orientation of native phospholipids was not affected by this treatment. The leak permeability proved to be due to the formation of pores with apparent radii of about 0.45 nm after 60 min illumination, and of 0.75 nm after 90 min. The number of pores per cell was calculated to be less than 1, the pores are slightly cation-selective (PK/PCl approximately 3:1). Since photodynamic treatment did not induce lipid peroxidation under the prevailing experimental conditions, protein modification must be the primary cause of both, leak permeability and flip enhancement. Since it is also likely that the leak permeability arises from oxidation of intrinsic membrane proteins, the results raise the interesting possibility that oxidative alteration of intrinsic membrane proteins may lead to enhanced transbilayer mobility of lipids.

The influence of ozone on human red blood cells. Comparison with other mechanisms of oxidative stress

Exposure of red blood cells to ozone resulted in K+ leakage, lipid peroxidation and inhibition of some membrane-associated enzymes. On the other hand, carrier-mediated transport of glucose, leucine, sulfate and glycerol and the nonspecific permeation of glycerol, L-glucose and erythritol were not affected by ozone. The cellular level of reduced glutathione declined, whereas the ATP content of the cells was quite insensitive to ozone exposure. It was shown that, most probably, lipid peroxidation and K+ leakage are not causally related. Further, K+ leakage did not reflect gradual, progressive loss of K+ from all cells simultaneously, but occurred in an all-or-none fashion. Finally, ozone-induced damage was compared to damage induced by H2O2, t-butyl hydroperoxide and photosensitizers plus light. It appeared that the pathways leading to membrane deterioration are quite dissimilar in these various forms of oxidative stress.

Superoxide, hydrogen peroxide and singlet oxygen in hematoporphyrin derivative-cysteine, -NADH and -light systems

Hematoporphyrin derivative and light in the presence of cysteine or glutathione were found to convert oxygen to superoxide and hydrogen peroxide at pH less than approx. 6.5, while at pH greater than 6.5 no superoxide or hydrogen peroxide production was observed. However, at pH values greater than 6.5 the rate of oxygen consumption increased. This rate paralleled the acid dissociation curve of the cysteine thiol group and is consistent with the chemical quenching of 1O2 by cysteine. The superoxide and hydrogen peroxide formation observed below pH 6.5 appeared not to be related to the singlet oxygen production of hematoporphyrin derivative. In addition, superoxide and hydrogen peroxide production was observed with hematoporphyrin derivative and light in the presence of NADH, both above and below pH 6.5. Direct detection of singlet oxygen luminescence at 1268 nm in the hematoporphyrin derivative-light system (2H2O as solvent) revealed an apparent linear increase in the singlet oxygen emission intensity as the p2H was raised from 7.0 to 10.0. Azide efficiently quenched this observed emission. In addition, at p2H 7.4, 1 mM cysteine resulted in a 40% reduction of the singlet oxygen luminescence, while at p2H 9.4 the signal was quenched by over 95% (under the experimental conditions employed). In total, we interpret these results as consistent with the chemical quenching of 1O2 by the ionized thiol group of cysteine.

Photosensitization of membrane components

The chemical mechanisms of the photosensitized peroxidation of unsaturated fatty acids and cholesterol are reviewed and the subsequent reactions of peroxide decomposition products with biological targets such as DNA and amino acids are analyzed. The importance of protein photooxidation and cross-linking in membrane function impairment is discussed.

The photosensitized oxidation of the calf lens main intrinsic protein (MP26) with hematoporphyrin

Hematoporphyrin (HP), a drug used for the treatment of tumors including intraocular tumors, is an efficient photosensitizer. In addition to its therapeutic value, it also produces a phototoxic side effect in the skin. To test whether such effects may also occur in the eye, calf lens fiber membranes were photolyzed in the presence and absence of 1 mM HP. A marked increase (ca 5 times) in the photopolymerization of the calf lens membrane main intrinsic protein (MP26) was found in the presence of HP. Tenfold increases in destruction rates were found in losses of histidine. The MP26 was also photolyzed after tryptic and chymotryptic digestion to MP21, this resulted in an increased photopolymerization in the presence of 1 mM HP. These data suggest an age related increase in sensitivity of the lens fiber membrane proteins to such photoprocesses. The addition of both azide and penicillamine reduces the photosensitized loss of the main intrinsic protein.

Photodynamic effects of hematoporphyrin-derivative on transmembrane transport systems of murine L929 fibroblasts

Photodynamic treatment of murine L929 fibroblasts with hematoporphyrin-derivative causes deterioration of various membrane functions. Most sensitive to photodynamic inactivation are the energy-coupled transport systems for aminoisobutyric acid and for Rb+. The facilitated diffusion system for 2-deoxy-D-glucose is slightly less sensitive. After longer illumination periods also the membrane barrier function is impaired, as reflected by K+ leakage and increased passive Rb+ uptake. After still longer illumination periods intermolecular protein crosslinking can be observed. This makes it unlikely that intermolecular protein crosslinking is causally involved in the deterioration of these membrane functions.

Photoradiation therapy in advanced carcinoma of the trachea and bronchus

Photoradiation therapy is a new technique being investigated for the treatment of solid malignant tumors. In this study, 17 patients with advanced, recurrent, biopsy-proven malignant lesions of the trachea or main-stem bronchus were treated by photoradiation therapy. Patients received hematoporphyrin derivative intravenously three days prior to light therapy. The light was delivered from a fiberoptic fiber attached to the output beam of a dye laser (633 +/- 3 nm). The fiber was passed through the large channel of a bronchoscope (Olympus BF 2T). Of the 17 patients, two had no measurable response to the photoradiation therapy, six had partial necrosis of the tumor, seven patients had a greater than 50 percent reduction in the intraluminal volume of tumor, and two were lost to follow-up. Survival ranged from 5 to 210 days (median survival, 40 days). Complications of the treatment were significant in this group of advanced-stage patients and included excessive secretions, fever, pneumonia, and abscess formation.

Differential sensitivity to photohemolysis of erythrocytes enriched with some liposome-carried substances

The sensitivity of human erythrocytes to photohemolysis sensitized by addition of protoporphyrin IX can be selectively affected by their enrichment with substances carried by cationic liposomes. In particular the enrichment which superoxide dismutase is accompanied by a copper-related greater sensitivity toward photohemolysis, as observed in the Down's syndrome (mongolism). Instead it is possible to protect the erythrocytes against the phototoxic effect of protoporphyrin by enrichment with small amounts of beta-carotene.

Formation of aqueous pores in the human erythrocyte membrane after oxidative cross-linking of spectrin by diamide

Oxidation of erythrocyte membrane SH-groups by diamide and tetrathionate induces cross-linking of spectrin (Haest, C.W.M., Kamp, D., Plasa, G. and Deuticke, B. (1977) Biochim. Biophys. Acta 469, 226-230). This cross-linking was now shown to go along with a concentration- and time-dependent enhancement of membrane permeability for hydrophilic nonelectrolytes and ions. The enhancement is specific for oxidative SH-group modifications, is reversible by reduction of the induced disulfides, can be suppressed by a very brief pre-treatment of the cells with low concentrations of N-ethylmaleimide and is strongly temperature-dependent. The pathway of the induced permeability discriminates nonelectrolytes on the basis of molecular size and exhibits a very low activation energy (Ea 3-8 kcal/mol). These findings are reconcilable with the formation of a somewhat inhomogeneous population of aqueous pores with radii probably less than or equal to 0.65 nm. Estimated pore numbers vary with the size of the probe molecule. Assuming a diffusion coefficient as in bulk water within the pore, at least 20 pores per cell have to be postulated; more realistic lower diffusion coefficients increase that number. Alterations of the lipid domain by changes of cholesterol contents and insertion of hexanol or nonionic detergents alter the number or size of the pores. Since aggregation of skeletal and intrinsic membrane proteins also occurs after the SH-oxidation, in parallel to the formation of membrane leaks, one may consider (a) defects in the disturbed bilayer interface, (b) a mismatch between lipid and intrinsic proteins or (c) channels in between aggregated intrinsic proteins as structures forming the pores induced by diamide treatment.

Protoporphyrin-induced photodynamic effects on band 3 protein of human erythrocyte membranes

In previous studies it has been shown that protoporphyrin-induced photodynamic effects on red blood cells are caused by photooxidation of amino acid residues in membrane proteins and by the subsequent covalent cross-linking of these proteins. Band 3, the anion transport protein of the red blood cell membrane, has a relatively low sensitivity to photodynamic cross-linking. This cannot be attributed to sterical factors inherent in the specific localization of band 3 in the membrane structure. Solubilized band 3, for instance, showed a similar low sensitivity to cross-linking. By extracellular chymotrypsin cleavage of band 3 into fragments of 60,000 and 35,000 daltons it could be shown that both fragments were about equally sensitive to photodynamic cross-linking. The 17,000 dalton transmembrane segment, on the other hand, was completely insensitive. Inhibition of band 3-mediated sulfate transport proceeded much faster than band 3 interpeptide cross-linking, presumably indicating that the inhibition of transport is caused by photooxidation of essential amino acid residues or intrapeptide cross-linking. A close parallel was observed between photodynamic inhibition of anion transport and decreased binding of 4,4'-diisothiocyanodihydrostilbene-2,2'-disulfonate (H2DIDS), suggesting that a photooxidation in the immediate vicinity of the H2DIDS binding site may be responsible for transport inhibition.

Photodynamic protein cross-linking

Exposure of spectrin to visible light in the presence of a photosensitizer results in photo-oxidation of sensitive amino acid residues and covalent cross-linking of the polypeptides. In a previous paper the cross-linking was ascribed to a secondary reaction between photo-oxidized histidine residues and amino groups. The following observations, described in this paper, are in accordance with this supposition. (1) During illumination of spectrin in the presence of a photosensitizer a pronounced photo-oxidation of histidine residues takes place. (2) Simultaneously a decrease of free amino groups is observed. (3) Semicarbazide protects against cross-linking and is bound to a histidine photo-oxidation product in spectrin. (4) The pH profile of histidine photo-oxidation and subsequent reaction with amino groups is similar to the pH profile of spectrin cross-linking. Amidination of NH2 groups in spectrin does not inhibit cross-linking, as visualized by gel electrophoresis. On the other hand aminidation of denatured myoglobin causes a 50% inhibition of cross-linking. These observations support the notion of NH2-involvement in cross-linking but also demonstrate, that other photodynamic cross-link mechanisms exist.

Photoradiation therapy for cutaneous and subcutaneous malignancies

Photoradiation therapy (PRT) using hematoporphyrin derivative (Hpd) as the photosensitizing agent is being developed for local treatment of a wide variety of malignant lesions including those involving the skin. The largest group of patients in this category are those with metastatic breast carcinoma in which 34/35 showed response to PRT. Other patients showing response to PRT are those with basal cell carcinoma, malignant melanoma, and squamous cell carcinoma.

Effects of semicarbazide on oxidative processes in human red blood cell membranes

Semicarbazide can interfere with oxidative processes in the red blood cell membrane via different modes of action. Treatment of human red blood cell membranes with O3, results, among other effects, in cross-linking of membrane proteins and inhibition of glyceraldehyde-3-phosphate dehydrogenase activity. Semicarbazide inhibits these effects by acting as an O3 scavenger. The effect of semicarbazide as an O3 scavenger is complicated by the fact that ozonolysis of semicarbazide yields a product that causes inhibition of glyceraldehyde-3-phosphate dehydrogenase. Glyceraldehyde-3-phosphate dehydrogenase inhibition can also be provoked by incubation of membrane suspensions with O3-treated phospholipids. Semicarbazide prevented this effect by interaction with an inhibitory O3-phospholipid reaction product. Protoporphyrin-induced photodynamic cross-linking of membrane proteins is chemically distinct from O3-induced cross-linking. Photodynamic cross-linking is also inhibited by semicarbazide, in this case via reaction with a histidine photooxidation product.

Temperature dependence of photodynamic red cell membrane damage

1. The protoporphyrin-sensitized photo-oxidation of free amino acids, amino acid residues in solubilized spectrin and amino acid residues in red blood cell membranes appeared to be virtually independent of temperature over the range 0-37 degrees C. The photodynamically produced increase in cation permeability in intact cells was also almost temperature independent. 2. The photodynamic cross-linking of the membrane proteins, on the other hand, was clearly temperature dependent, both when the proteins were present in the membrane structure and when isolated and purified. 3. With red cell membranes, illuminated in the presence of protoporphyrin at 0 degrees C, it could be shown that during subsequent incubation in the dark at 37 degrees C the protein cross-linking increased considerably. 4. The results indicate that cross-linking of membrane proteins is a secondary reaction in which rather stable photo-oxidation products of susceptible amino acid residues are involved. Furthermore, these experiments strongly suggest that the deterioration of membrane function, leading to increased caption permeability, is caused by photo-oxidation of amino acid residues rather than by cross-linking of membrane proteins.

Protoporphyrin-induced photodynamic effects on transport processes across the membrane of human erythrocytes

Previous studies have shown that illumination of erythrocytes with visible light in the presence of protoporphyrin results in cross-linking of membrane proteins and deterioration of several membrane functions, e.g. active transport of K+ and Na+. In the present study it is shown that carrier-mediated transport of glucose, L-leucine, sulphate and glycerol is also inhibited by the photodynamic process, whereas non-specific permeability of glycerol and thiourea is increased. It is shown that these effects are not caused by lipid peroxidation, but by photooxidation of membrane proteins. The inhibition of carrier-mediated transport is caused either by photodynamic oxidation of susceptible essential amino acid residues of the carrier molecules, or by an aspectific perturbation of the membrane structure, leading to inhibition of carrier functions.