Retention and photodynamic effects of haematoporphyrin derivative in cells after prolonged cultivation in the presence of porphyrin

Lipophilic rather than hydrophilic photosensitizers show strong adherence to standard cell culture microplates under cell-free conditions

Analysis of photosensitizer (PS) uptake kinetics into tumor cells is a standard cell culture experiment in photodynamic therapy (PDT) - usually performed in plastic microplates or petri dishes. Organic substances such as PS can potentially interact with the plastic surfaces. In this study, we provide a qualitative comparison of three lipophilic PS (hypericin, Foscan® and Photofrin®) and two rather hydrophilic PS formulations (PVP-hypericin and aluminum (III) phthalocyanine tetrasulfonate chloride) regarding their adherence to the surfaces of 96-well microplates obtained from four different manufacturers. For estimation of the relevance of PS adherence for cellular uptake studies we compared the fluorescence signal of the respective PS in microplates containing A431 human epithelial carcinoma cells with microplates incubated with the respective PS under cell-free conditions. We demonstrate that lipophilic PS substances show a strong adherence to microplates - in case of direct lysis and fluorescence measurement resulting in 50% up to 90% of the overall signal to be caused by adherence of the substances to the plastic materials in a cellular uptake experiment. For the hydrophilic compounds, adherence is negligible. Interestingly, adherence of PS agents to microplates takes place in a time-dependent and thus kinetic-like manner, requiring up to several hours to reach a plateau of the fluorescence signal. Furthermore, PS adherence is a function of the PS concentration applied and no saturation effect was observed for the concentrations used in this study. Taken together, this study provides a systematic analysis under which conditions PS adherence to cell culture plates may contribute to the overall fluorescence signal in - for example - PS uptake experiments.

Heme oxygenase-mediated resistance to oxygen toxicity in hamster fibroblasts

The role of heme oxygenase (HO)-1 was evaluated in the oxygen-resistant hamster fibroblast cell line, O2R95, which moderately overexpress HO when compared with the parental cell line, HA-1. To suppress HO-1 expression, O2R95 were transfected with HO-1 antisense oligonucleotide or treated with tin-mesoporphyrin (SnMP). To increase HO-1 expression, cells were transfected with HO-1 cDNA in a pRC/cytomegalovirus (CMV) vector. All cells were challenged with a 48-h exposure to 95% O2 (hyperoxia). When HO activity was suppressed, O2R95 cells had significantly decreased cell viability, increased susceptibility to lipid peroxidation, and increased protein oxidation in hyperoxia. In contrast, further overexpression of HO-1 did not improve resistance to oxygen toxicity. Antisense-transfected cells and SnMP-treated cells with lowered HO activity showed increased levels of cellular heme compared with controls. In the HO-1 cDNA-transfected O2R95 cells, cellular heme was lowered compared with controls; however, cellular redox active iron levels were increased. We conclude that HO mediates cytoprotection to oxygen toxicity within a narrow range of expression. We speculate that this protective effect may be mediated in part through increased metabolism of the pro-oxidant heme but that higher levels of HO activity obviate protection by increased redox active iron release.

Photofrin photosensitization. Correlation of Photofrin:erythrocyte binding processes with photolysis

Unilamellar suspensions of dimyristoylphosphatidylcholine (DMPC) can be utilized to remove Photofrin from the erythrocyte. This enables correlation of the Photofrin membrane-binding processes with Photofrin-sensitized photolysis. The observed rates of erythrocyte biding as well as the observed rates of removal of PHotofrin from the erythrocyte membrane suggest the existence of two Photofrin species that differ in their rates of exchange between the erythrocyte and buffer phases. Selective depletion and readdition of these Photofrin species to the erythrocyte membrane permits evaluation of their separate and joint photolytic efficiencies. These rapidly and slowly exchanging membrane-bound Photofrin species are separately much less efficient photosensitizers than the two species together. The two Photofrin species exhibit essentially identical fluorescence emission spectra in the presence of DMPC. Nevertheless, models consistent with the results involve partitioning by chemically distinct Photofrin components or partitioning of chemically similar Photofrin components into distinct membrane environments, or a combination of these.

The influence of the cysteine protease inhibitor L-trans-epoxysuccinyl-leucyl amido(4-guanidio)butane (E64) on photobiological effects of tetra(4-sulfonatophenyl)porphine

Human cervix carcinoma cells of the line NHIK 3025 were exposed to light after 18 h incubation with tetra(4-sulfonatophenyl)porphine (TPPS4) in the absence or presence of the cysteine protease inhibitor L-trans-epoxysuccinyl-leucyl amido(4-guanidino)butane (E64) followed by 1 h in sensitizer-free medium. E64 changed the photochemical properties of TPPS4 in NHIK 3025 cells, i.e., TPPS4 fluorescence yield was enhanced 2.5-fold and photochemically induced lysosomal rupture and loss of cell bound TPPS4 were inhibited. Additionally, E64 slightly (10%) reduced the sensitivity of the NHIK 3025 cells to photoinactivation. This is not likely to be due to its inhibitory effect on protease activity, but correlates with its inhibition of lysosomal rupture. The present results indicate that the release of lysosomal cysteine proteases from the lysosomal compartments are of little or no importance in the photochemical inactivation of NHIK 3025 cells when TPPS4 is used as photosensitizer.

Retention and phototoxicity of tetra(4-sulfonatophenyl)porphine in cultivated human cells. The effect of fractionation of light

Human cervix carcinoma cells of the line NHIK 3025 were incubated for 18 h with tetra(4-sulfonatophenyl)porphine (TPPS4) and further incubated for 1-29 h in sensitizer free medium before exposure to light. After 1 h in sensitizer free medium only a 20% further loss of TPPS4 was observed within the next 28 h. During the time in sensitizer free medium, each TPPS4 molecule became more efficient in sensitizing single cells to photoinactivation. This enhanced photosensitizing efficiency of TPPS4 correlated well with the enhanced fluorescence yield of TPPS4. In some experiments the cells were exposed to a light dose inactivating 10% of the cells after incubation for 1 h in sensitizer free medium and a second graded light dose given 4-28 h later. Exposure of the cells to the first light dose led to loss of 60% of TPPS4 from the cells. Despite the significant loss of sensitizer from the cells the fluorescence yield of TPPS4 from each cell was found to increase (e.g. by 100% 4 h after light exposure). The enhanced fluorescence yield of cell bound TPPS4 was followed by a 1.6-2.5-fold increase in sensitivity of each cell to second light dose. Thus, a small light dose increased the photosensitivity of TPPS4-loaded NHIK 3025 cells for several hours after the first light exposure. The advantageous effect of light fractionation was reduced by a significantly enhanced loss of sensitizer induced by the first light exposure. The optimal time between the two fractions of light seems to be 30-90 min.

Binding of hematoporphyrin derivative to brain tumor cells--a fluorescence spectroscopic study

The binding of hematoporphyrin derivative (HpD) to brain tumor cells and their photosensitivity was studied as a function of HpD concentration, time of incubation and growth phase of cells. Upon binding to cells, HpD showed three fluorescence bands at 616, 636 and 678 nm. In plateau phase cells a fluorescence band at 636 nm was predominant, which was further enhanced by increasing HpD concentration and/or increasing incubation time. In exponential phase cells the maximum fluorescence was exhibited at 616 nm. After 1 h incubation of exponential phase cells with increasing HpD concentration an overall intensity enhancement occurred with no change in the distribution of bands, whereas longer incubation time caused an increase in relative intensity of the 636 nm band similar to that observed in plateau phase cells. After 1 h incubation with HpD plateau phase cells were more photosensitive than exponential phase cells, although cell bound HpD was much less in the former case. Incubation of cells for 24 h drastically enhanced the photosensitivity irrespective of the growth phase. Our results suggest a relationship between the fluorescence emission band of HpD at 636 nm and photosensitivity of cells.

Comparative kinetics of hematoporphyrin derivative uptake and susceptibility of Bacillus subtilis and Streptococcus faecalis to photodynamic action

Hematoporphyrin derivative (HpD) is widely used in photoradiation therapy of tumors and other diseases, and has been shown to affect the viability of gram positive bacteria. This investigation assessed the efficiency of binding of HpD to Bacillus subtilis and Streptococcus faecalis when HpD-treated organisms were exposed to red light. Kinetic studies indicated that the amount of HpD bound increased with increasing external concentration of HpD until saturation of binding sites was reached. S. faecalis had a higher affinity for HpD and was more susceptible to photoinactivation than B. subtilis. The data from this study suggest that differences in susceptibility of microorganisms to photoinactivation are directly related to the affinity of each strain for HpD.

Depolarization of mouse myeloma cell membranes during photodynamic action

The effect of photodynamic action on plasma membranes was examined using a fluorescent potentiometric indicator [di-SBA-C2(3)] to measure alterations in the plasma membrane potential of mouse myeloma cells treated with zinc phthalocyanine sulfonate and light. Plasma membrane depolarization was observed to be an early event in photodynamic action, showing both photosensitizer concentration and light dose dependence. Depolarization occurred while membrane integrity was retained and appears to be an early event preceding cell death.

A practical test for in vitro evaluation of photosensitization: assessment with hematoporphyrin derivative (HPD)

A simple procedure is described for the determination of the photosensitizing potency of drugs, using three leukemic cell lines, two of lymphocytic origin, L1210 and P388 and one of erythroid type, Friend-745. The procedure allows one to investigate several aspects of the photosensitization properties of tested compounds such as cellular localization and direct (trypan blue exclusion) or delayed (clonogenicity) photomediated toxicities. The method was assessed using crude hematoporphyrin derivative (HPD) as well as dihematoporphyrin ether (DHE) or commercially available Photofrin II. Results were compared to those obtained with normal cells, e.g spleen lymphocytes and erythropoietic stem cells (CFU-e), and discussed in the light of the relative response of normal versus transformed cells.

Water-soluble metal naphthalocyanines--near-IR photosensitizers: cellular uptake, toxicity and photosensitizing properties in NHIK 3025 human cancer cells

Metal naphthalocyanine complexes (MNCSs) absorb light in the near-IR spectral region (760 nm) where tissue penetration is optimal and they have been proposed as agents for photodynamic therapy (PDT). Sulphonated derivatives of tris-(2,3-naphthalocyanato) bis-chloroaluminium(III) and zinc(II) with various degrees of sulphonation were prepared. Cellular uptake, aggregation in cellular environments, cytotoxicity and photosensitizing properties were studied. Three of the four dyes studied were taken up by cells to a satisfactory degree and were not cytotoxic at the concentration used (10 micrograms ml-1). The least sulphonated sample of zinc naphthalocyanine produced some phototoxic effects (LD50 = 1.12 J cm-2). All the other samples of sulphonated naphthalocyanine were found to be aggregated inside the NHIK 3025 cells, preventing any significant PDT effect.

Picosecond fluorescence of R3230AC mammary carcinoma mitochondria after treatment with hematoporphyrin derivative and Photofrin II in vivo

Hematoporphyrin derivative (HPD) and other porphyrin samples were excited by 20-ps 532-nm laser pulses. Fluorescence was detected using a low-jitter streak camera. Data were fitted to a sum of exponential decay times on the order of picoseconds. Fluorescence of porphyrins in aqueous solution show various behaviors depending on the hydrophobicity of the porphyrins. The most hydrophilic porphyrins show long decays only (greater than 500 ps). Porphyrins intermediate in hydrophobicity have intensity-dependent fast decays. The most hydrophobic have fast decays (less than 20 ps). Picosecond fluorescences of mitochondria prepared from rat tumors treated in vivo with HPD or Photofrin II show an increase in the ratio of fast to slow decays when compared to the injected porphyrins. These results are consistent with the concentration of the more hydrophobic porphyrins in mitochondria in photosensitization treatment. Thus picosecond fluorescence studies of porphyrins may provide a means to obtain photoproperties which differentiate between effective and ineffective in vivo photosensitizers.

Effect of photofrin II and light energy on retinoblastoma-like cells in vitro. Dose-response relationships, effect of light dose rate and recovery ratio

A clonogenic survival assay on retinoblastoma-like cells (EXP-5 cells) was applied in vitro to assess the effect of photodynamic therapy at relative low concentrations of photofrin II and high doses of light energy. The cellular concentration of photofrin II was estimated by spectrofluorimetry. The cellular content of photofrin II increased with the concentration in the medium (up to 3 micrograms/ml) and the incubation time (up to 24 h) in cells first incubated in photofrin II for 24 h and then in photofrin-II-free medium for 24 h. There was an obvious dose-response relationship between cell damage and photodynamic therapy both for the cellular photofrin II content and the total amount of light energy delivered. The dose rate of light energy had no influence on the cell damage. The cells had a recovery factor of only 1.34, suggesting a low repair of sublethal damage. An approximately linear isoeffect curve at the 10% survival level was described as a function of photofrin II concentration and light energy, suggesting a predictable reversible relationship between them. The results suggest that retinoblastoma cells are very sensitive to photodynamic therapy.

Photodynamic therapy--new approaches

Photodynamic therapy (PDT) requires a photosensitizer within a target tissue and activation by proper-wavelength radiation at appropriate energy level to achieve complete eradication of that tissue. Whereas the first clinical results were reported nearly a decade ago, only in the past few years has the necessary technology been available for development of phase III controlled clinical trials. Photofrin II, the trade name for a mixture of oligomeric porphyrins, is effective in treatment of a wide variety of malignant tumors and is the subject of Phase III controlled trials in bladder and lung. New photosensitizers are being developed that may be both more efficient and less likely to cause the generalized cutaneous photosensitivity associated with Photofrin II. Further advances in light sources and delivery systems portend an even broader acceptance of PDT in medical and biological science.

Relationship between changes in antigen expression and protein synthesis in human melanoma cells after hyperthermia and photodynamic treatment

Hyperthermia and photoactivated hematoporphyrin derivative induce a dose-dependent reduction in the expression of the p250 surface melanoma-associated antigen on the human FME cell line. Expression of this glycoprotein antigen was quantitated by immunofluorescence flow cytometry based on the monoclonal antibody 9.2.27. Decrease in antigen expression was followed by a transient increase above the level for untreated cells, before normalization occurred about one week after treatment. These treatment-induced changes in antigen expression could partly be explained by changes in protein synthesis. This conclusion was based on the following observations: Hyperthermia and photoactivated hematoporphyrin derivative both inhibited protein synthesis. The latter increased again rapidly to rates above normal until antigen expression reached normal level, whereupon the protein synthesis rate decreased to normal. Inhibition of protein synthesis by cycloheximide 1 day after heating, prevented the recovery of antigen expression, demonstrating that protein synthesis is necessary for resumption of normal antigen expression. The changes in both antigen expression and protein synthesis were dose-dependent, and the magnitude and duration of the changes increased with increasing dose. The time courses of the changes in protein synthesis after two different treatments which both inactivated two logs of cells were almost identical, as were the time courses after two lower heat doses inactivating one log of cells. These similarities were reflected in the changes in antigen expression. At the same time as protein synthesis reached its maximum and antigen expression resumed normal level, an increase in the Golgi apparatus was observed ultrastructurally, indicating an increased synthesis rate and transportation of glycoproteins to the cell surface.

Photodynamic effects of hematoporphyrin-derivative on enzyme activities of murine L929 fibroblasts

Photodynamic treatment of murine L929 fibroblasts with hematoporphyrin-derivative resulted in the inactivation of cytosolic, mitochondrial and lysosomal enzymes and in a decrease in cellular adenosine triphosphate and reduced glutathione concentrations. Comparison of these results with those of previous studies revealed that transmembrane transport systems and DNA repair enzymes are inactivated after much shorter illumination periods than are intracellular enzymes. Although the pattern of photodynamic damage altered by varying the protocol of preincubation with hematoporphyrin-derivative and washing, it appeared that under all experimental conditions the plasma membrane was much more sensitive to photodynamic damage than were the intracellular enzymes. Lysosomal membrane disruption with subsequent detrimental release of lysosomal enzymes has been implicated previously in certain forms of porphyrin-induced photodynamic cell destruction. Cytochemical studies on enzyme localization virtually exclude such a mechanism in hematoporphyrin-derivative-induced cell inactivation in L929 fibroblasts.

Photosensitivity of DNA replication and respiration to haematoporphyrin derivative (photofrin II) in mammalian CV-1 cells

DNA synthesis, as well as respiration, has been studied in CV-1 cells incubated with 5 or 25 micrograms/cm3 haematoporphyrin derivative Photofrin II (PF II) for 1, 24 or 48 h and then irradiated with various doses of UVA light (365 nm). The impairments of DNA synthesis increased with the duration of incubation with the porphyrin, its concentration and the dose of irradiation. The cellular consumption of oxygen is also inhibited by the treatment, but less severely. In the case of the higher PF II concentration (25 micrograms/cm3), the impairment of DNA synthesis after illumination seems to be mainly due to 3HTdR transport inhibition. This effect can be related to plasma membrane damage as shown by lactate dehydrogenase leakage. At 5 micrograms/cm3 PF II, DNA synthesis inhibition is observed even after short exposure to PF II and light without 3HTdR transport impairment. In that case, DNA and/or mitochondrial photodamage may explain the inhibition.

Study of microscopic porphyrin fluorescence

A technique of porphyrin (hematoporphyrin derivative [Hpd]) fluorescence microscopy was evaluated by studying Hpd uptake, retention, and loss in established human cancer cell lines. Hpd uptake appeared to be qualitatively identical in the three cell lines used, but the rate of loss was slowest in the renal-carcinoma-derived line, suggesting a cellular characteristic. The technique was readily applied to demonstrate porphyrin fluorescence in exfoliated cells in urine of bladder cancer patients.

Toxic effects of ozone on murine L929 fibroblasts. Enzyme inactivation and glutathione depletion

Exposure of L929 murine fibroblasts to ozone resulted in K+ leakage and inhibition of several enzymes. Most sensitive to ozone exposure were glyceraldehyde-3-phosphate dehydrogenase and pyruvate kinase. The activities of another cytosolic enzyme, lactate dehydrogenase, the mitochondrial enzymes glutamate dehydrogenase, succinate dehydrogenase, cytochrome c oxidase and the activity of the lysosomal enzymes acid phosphatase and beta-glucuronidase were, initially, not or only slightly affected. The localization of the lysosomal enzymes did not change during ozone exposure. After prolonged exposure complete deterioration of the cells was observed and all enzyme activities declined. The activity of the enzymes was also monitored during ozone exposure of a sonicated cell suspension and it was shown that all these enzymes are in fact susceptible to ozone. These observations clearly demonstrate that, besides the structure and amino acid composition of an enzyme, the localization in the cell plays an important role in its susceptibility to ozone. The intracellular levels of reduced and oxidized glutathione were affected as well. The ATP content, however, proved to be insensitive to ozone exposure.

Toxic and phototoxic effects of tetraphenylporphinesulphonate and haematoporphyrin derivative in vitro

The toxic and phototoxic effects of tetraphenylporphinesulphonate (TPPS4) and haematoporphyrin derivative (HpD) have been examined in vitro. TPPS4 was found to have less dark toxicity to the cells than HpD as measured by inhibition of cell multiplication and colony formation at comparable extracellular concentrations. TPPS4 was also less effective than was HpD in photoinactivating NHIK 3025 cells by more than a factor 2 which should be expected on the basis of cellular uptake. Spectrofluorometric data suggest that HpD in cells interacts more with lipids than TPPS4. This might explain the large photosensitizing effect of HpD compared to TPPS4 since the lifetime of singlet oxygen is about a factor of 10 longer in a lipid environment than in an aqueous environment. The uptake of TPPS4 and HpD by cancer cells in vitro does not correlate with previous in vivo data, indicating retention of TPPS4 in the tumour stroma. This makes in vitro/in vivo extrapolation difficult with regard to the use of TPPS4 as an agent for photodynamic therapy.

Photosensitization with derivatives of haematoporphyrin

This review describes recent progress in delineation of the structure of the active component(s) in the tumour-localizing photosensitizer HPD (haematoporphyrin derivative), along with suggestions concerning the likely determinants of accumulation of this product by different tissues.

Fundamental aspects in tumor photochemotherapy: interactions of porphyrins with membrane model systems and cells

Some molecular aspects underlying photochemotherapy and photodiagnosis of tumors with porphyrins are reviewed. The nature of the clinically used photosensitizer HpD is first presented along with structures of molecules found to be efficient in vitro. The possible role of pH in the preferential retention of dicarboxylic porphyrins by tumors is discussed in light of results obtained with membrane models. The uptake of dicarboxylic porphyrins by cells most likely involves passive mechanisms. Cell photoinactivation using a purified porphyrin does not depend upon the incubation time but only on the intracellular concentration of the dye. This likely reflects a poor specificity of the photoinactivation processes with regard to the cellular localization of the dye. The properties which should be presented by more efficient photosensitizers are discussed.

Binding of Hoechst 33258 to chromatin in situ

The binding of Hoechst 33258 to rat thymocytes, human lymphocytes, and NHIK 3025 tissue culture cells was studied by measuring the fluorescence and light scattering of the cells as functions of dye concentration using flow cytometry. The results indicated that there were two different modes of binding of Hoechst 33258 to chromatin in situ at physiological pH. Type 1 binding, which dominated at total dye/phosphate ratios below 0.1 (0.15, M), was characterized by a binding constant of the order 10(7) M-1 and fluorescence with high quantum yield. Further binding of the dye resulted in a reduced blue/green fluorescence ratio, indicating that secondary sites were occupied. Binding at secondary sites above a certain density (0.1 less than or equal to bound dye/phosphate less than or equal to 0.2) induced strong quenching of fluorescence and precipitation of chromatin. Precipitation was quantitated by measuring the large-angle (greater than or equal to 15 degrees) light scattering of the cells above 400 nm, i.e., outside the Hoechst 33258/DNA absorption spectrum, as a function of dye concentration. In contrast, the light scattering at 365 nm, i.e., within the absorption spectrum of Hoechst 33258/DNA, was independent of the total dye/phosphate ratio. The coefficient of variation of the light-scattering (greater than or equal to 400 nm) histograms decreased with Hoechst 33258 concentration. Type 2 binding to histone-depleted chromatin was cooperative (Hill-coefficient approximately 2) and the apparent binding constant was 2-3 X 10(5) M-1 as determined from quenching and precipitation data.(ABSTRACT TRUNCATED AT 250 WORDS)

Cellular effects of hematoporphyrin derivative photodynamic therapy on normal and neoplastic rat bladder cells

HPD is known to localize in neoplastic cells and when exposed to the appropriate wavelength of light causes cytotoxicity. The authors have established a rat urothelial cell model for use in comparing and contrasting the effects of HPD photodynamic therapy (PDT) in normal (RBL-01) and transitional cell carcinoma (AY27) bladder cell lines. Uptake, toxicity, and morphologic damage following exposure to HPD PDT were evaluated. Trypan blue exclusion was used for determination of the toxicity of several HPD concentrations (1, 10, 25, and 50 micrograms/ml) with increasing duration of incubation with HPD (0, 1, 2, 4, 12, 24, and 48 hours). Both cell lines displayed increased toxicity with higher concentrations of HPD; however, the AY27 cells were more susceptible to the toxic effects of HPD PDT than the RBL-01 cells at the higher HPD doses studied (25 and 50 micrograms/ml). Viability decreased with increased duration of HPD incubation in RBL-01 cells up until 4 hours, after which it showed a steady increase. Viability decreased in the AY27 cells with increased duration of HPD incubation. An increase in serum concentration in the medium resulted in an increase in viability for both cell lines. Both cell lines demonstrated fast initial uptake of HPD followed by slower uptake over the time studied. By 24 and 48 hours the AY27 cells contained twice the amount of methanol-extractable porphyrins as the RBL-01 cells. The initial morphologic change following HPD PDT was damage to mitochondria. Mitochondrial damage occurred immediately after PDT in the AY27 cells and 30 minutes after PDT in the RBL-01 cells. Both cell lines exhibited a similar progression of cell injury; however, morphologic damage was observed earlier after PDT and appeared more extensive in the AY27 cells.

Photosensitization of malignant tumors

Photodynamic therapy is a new, experimental method of treating malignant tumors by utilizing the relatively selective retention of the photosensitizer (hematoporphyrin derivative or dihematoporphyrin ether) and its ability to elicit an efficient photodynamic reaction upon activation with penetrating viable light. Application of this therapy to tumors in the bronchus, bladder, skin, and several other sites has demonstrated both safety and efficacy, even in advanced cases. Eradication of early stage tumors in the bronchus and bladder has been demonstrated. Selective retention of the photosensitizers in tumors is apparently related to the relatively large size of the aggregates of these materials causing phagocytosis by reticuloendothelial cells as well as preventing rapid clearance from tumor interstitial fluid and subsequent uptake in lipophylic components of cells. Upon light activation, generally delivered from lasers via fiber optics, the sensitizers generate singlet oxygen, the apparent cytotoxic agent, causing both vascular damage and injury to tumor cells.

Binding of hematoporphyrin derivative to membranes. Expression of porphyrin heterogeneity and effects of cholesterol studied in large unilamellar liposomes

The binding of hematoporphyrin derivative to membrane was studied at the molecular level, employing fluorimetric techniques and using liposomes (large unilamellar) to model biological membranes. Two specific issues were probed: (a) the effect of increasing the porphyrin-liposome incubation period (37 degrees C, neutral pH, in the dark) from 2 h up to 24 h, with liposomes composed of PC or PC/cholesterol 7:3 (molar ratio); (b) the effects of membrane lipid composition, in terms of mol% cholesterol in PC/cholesterol liposomes, on the porphyrin-membrane binding equilibrium, for a long incubation period (16 h). The data were processed and found to be in good agreement with the following proposed model: With time (t greater than 2 h), the porphyrin fractions into three components, two of them binding to membrane with high and low affinities, respectively, the time effect reaching a plateau at 16 h. Linkage was observed between the slow process and changes in the available pools of each fraction. At sufficiently long incubations, the magnitude of each of the two binding fractions was found to be (roughly) 30%, independent of the membrane lipid composition. On the other hand, the magnitude of the binding constants was found to depend on the lipid composition, that of the high-affinity fraction decreasing from 9000 M-1 for 0% cholesterol, to 3000 M-1 for 40% cholesterol, then increasing back to 5000 M-1 upon further increase in cholesterol (to 50% mol) and that of the low-affinity fraction going from 1000 M-1, to 100 M-1, to 300 M-1 for similar lipid compositions. The origin of the time effect, in terms of porphyrin-specific processes, and the biological relevance of the present findings are discussed.

The binding of dihematoporphyrin ether (photofrin II) to human serum albumin

The variable aggregation of porphyrins such as Hp and Hpd introduces uncertainties and errors into attempts to measure their binding to proteins. Methods such as dialysis, ultrafiltration and gel chromatography, so frequently used, proved to be unreliable when applied to the binding of Hp to serum albumin. Quenching of tryptophan fluorescence will only occur at porphyrin binding sites which are closely situated to the tryptophan residue (1.7 nm). Porphyrin bound to more distant sites may not be included in this analytical procedure which must therefore be applied with reserve. In the present work, photofrin II (PII) was shown to consist of large aggregates greater than 20 000-30 000 Mr, solutions of which did not disaggregate on dilution down to 1 mumol/1. Addition of albumin resulted in a change in the absorption spectrum of PII. Thus, it was assumed that measurements of differential absorption gave the proportion of free-to-bound PII when serum albumin was added in graded amounts to its solution. By applying suitable calculations to the data, an association constant of 0.3 1/mumol +/- 30% was deducted. Hill plots of the binding data were linear with slopes close to unity. Experimentally determined uptake of PII by NHIK 3025 cells from solutions containing different amounts of HSA showed that the amount bound to the cells was proportional to the free PII. The kinetics of quenching of tryptophan fluorescence in HSA by PII indicates that there is one main porphyrin-binding site affecting this fluorescence. This binding site seems to have a slightly higher affinity for PII than the remaining sites. Up to 8 porphyrin rings of PII can be bound to an HSA molecule.

Photodynamic effects and hyperthermia in vitro

Cells from the established human line NHIK 3025 were labelled with hematoporphyrin derivative in vitro. Subsequently, the cells were treated with light and hyperthermia. The cells could be irradiated either before, during or after the incubation at a hyperthermic temperature. It was shown that hyperthermia given shortly after the light exposure gave a synergistic killing effect. In spite of some loss of porphyrins from the cells, the light sensitivity increased 20 min after a light irradiation. At later times, the cells apparently repaired some of the photodynamic damage at 37 degrees C. At higher temperatures, the repair was inhibited.

Effects of haematoporphyrin derivative and light in combination with hyperthermia on cells in culture

Interactions between the photodynamic effect of haematoporphyrin derivative and hyperthermia are reported. Cells labelled with haematoporphyrin derivative and irradiated with red light were sensitized by heat, particularly when the cells were heated after the exposure to light. It is shown that there is a synergistic interaction between the photodynamic effect and hyperthermia (42.5 and 45 degrees C). Hyperthermia-induced inhibition of the repair of photodynamic damage is suggested as a mechanism for the interaction. The possibility that these findings may be advantageous to cancer therapy is discussed.