BINDING OF HEMATOPORPHYRIN DERIVATIVE TO HUMAN SERUM ALBUMIN

Abstract Dialysis of hematoporphyrin derivative fraction A (HpD-A) off human serum albumin at 38°C followed the Hill equation for cooperative binding with saturation at 5 to 8. 600 dalton porphyrin units. Approximately 15% of the HpD-A was free for concentrations typical of human serum in photoradiation therapy. Possible structures of the tumor-localizing and -photosensitizing component in HpD-A are considered. Of these, a folded-over, covalent dimer appears to be more consistent with the photophvsical properties.     

FLUORESCENCE SPECTRAL CHANGES OF HEMATOPORPHYRIN DERIVATIVE UPON BINDING TO LIPID VESICLES, Staphylococcus aureus AND Escherichia coli CELLS

Abstract— The binding of hematoporphyrin derivated (Hpd) to lipid vesicles and bacterial membranes was determined by fluorescence spectroscopy. The fluorescence measurements of Hpd in aqueous solutions showed two bands at 613 and 677 nm. In lipid environments of lecithin vesicles the fluorescence spectrum was shifted to 631 and 692 nm, respectively. Hpd was rapidly bound to the cell membrane of Staphylococcus aureus while much less binding occurred in the presence of Escherichia coli. At the same time, spheroplasts of both bacteria were shown to bind Hpd to a similar extent. These results are well correlated with the photoinactivation of the gram positive bacteria with Hpd while the gram negative cells were shown to be resistant. The pH dependence of both Hpd binding to S. aureus as well as the photodynamic inhibitory effect of the same bacteria are similar. It is concluded that the segregation of Hpd to the cell membrane is a prerequisite for its photodynamic effect.     

PICOSECOND FLUORESCENCE SPECTROSCOPY ON INCORPORATION PROCESSES OF HEMATOPORPHYRIN DERIVATIVE INTO MALIGNANT TUMOR CELLS in vitro

Abstract— By using a highly sensitive streak-camera technique, we investigate incorporation processes of HpD into malignant tumor m-KSA cells in vitro. The picosecond decays of the total fluorescence spectra, the wavelength-resolved fluorescence decays and the time-resolved fluorescence spectra from HpD in the cells are measured as a function of the incubation time. The results show that the aggregate component of HpD which has a fast fluorescence lifetime of 100 ps and a red-shifted band of ∼ 660 nm selectively accumulates more and more in the cells with the increase of the incubation time.     

PHOTODYNAMIC ACTION OF HEMATOPORPHYRIN ON YEAST CELLS—A KINETIC APPROACH

Abstract— By a technique which combines rapid mixing of cells and hematoporphyrin (HP) with a short duration of illumination, the photodynamic inactivation of yeast cells was investigated, particularly, in seeking for the information of the location of HP at the time of action. The fluence-survival curves obtained under the conditions where the reaction mixture was kept in the dark for Is, 60s and even 35 min before illumination were indistinguishable from each other, indicating no interaction between cells and sensitizers took place in about 30 min in such a way that the photodynamic efficiency could be modified. It is unlikely that HP acted intracellularly, since the protective effect of N^?₃ was observed at concentrations as low as 0.5 mM. Furthermore, the rate constant k_p related to the protective effect of NJ, was estimated to be 1 × 10⁸M^?1 s^?1 under the assumption that ¹O₂ was the active intermediate and had a lifetime of 2 μs under the present conditions. This value of k_p is rather close to that of k_q, the quenching rate constant of N^?₃ for ¹O₂, of which the accepted value is 2 × 10⁸M^?1s^?1 in the homogeneous aqueous system. This information, together with the absence of uptake of HP by cells and a well response of survival upon illumination to the D₂O fraction of the reaction mixture, provide strong bases for the argument that direct interaction of HP with yeast cells is of minor importance in the photodynamic processes, and the photodynamic action is largely mediated by an intermediate (¹0₂) generated in bulk medium.     

ABSORPTION SPECTRUM OF HEMATOPORPHYRIN DERIVATIVE in vivo IN A MURINE TUMOR MODEL

Abstract-Time-resolved reflectance was used to measure the absorption spectrum of hematoporphyrin derivative (HpD) in vivo in a murine tumor model. Reflectance measurements were performed in the 600–640 nm range on mice bearing the L1210 leukemia. Then the animals were administered 25 mg/kg body weight of HpD intraperito-neally. One hour later the reflectance measurements were repeated. Fitting of the data using the diffusion theory allowed assessment of the absorption coefficient before and after the administration. As a difference between the latter and the former data, the in vivo absorption spectrum of HpD was evaluated. Maximum absorption was measured at 620–625 nm. Similar spectral behavior was obtained for HpD in solution in the presence of low-density lipoproteins.     

SUBCELLULAR LOCALIZATION OF HEMATOPORPHYRIN DERIVATIVE IN BLADDER TUMOR CELLS IN CULTURE

Mitochondria have been implicated as a primary subcellular site of porphyrin localization and photodestruction. However, other organelles including the cell membrane, lysosomes and nucleus have been shown to be damaged by hematoporphyrin derivative (HpD) photosensitized destruction as well. In this study we attempted to follow the translocation of the fluorescent components of HpD in human bladder tumor cells (MGH-U1) in culture to determine whether specific subcellular localization occurs over time. Following a 30 min exposure to HpD the cellular fluorescence was examined immediately and 1, 2, 4, and 24 h after HpD removal using fluorescence microscopy and an interactive laser cytometer. The in vitro translocation of dye appeared to be fairly rapid with fluorescence present at the cell membrane and later (1-2 h) within a perinuclear area of the cytoplasm. To determine whether HpD had become concentrated into a specific subcellular organelle, these fluorescence distribution patterns were compared with fluorescent marker dyes specific for mitochondria, endoplasmic reticulum and other membranous organelles. The HpD fluorescence did not appear to be as discrete as the dyes specific for mitochondria or endoplasmic reticulum but appeared similar to the diffuse cytomembrane stain. Finally, the interaction between the fluorescent components of HpD and the cellular constituents was evaluated using a "fluorescence redistribution after photobleaching" technique. The results indicated that the mean lateral diffusion for HpD in MGH-U1 cells was 1.05 x 10(-8) cm2/s, a rate closer to that of lipid diffusion (10(-8)) than that of protein diffusion (10(-10)).(ABSTRACT TRUNCATED AT 250 WORDS)     

A FLUORESCENCE STUDY OF THE BINDING OF HOECHST 33258 and DAPI TO HALOGENATED DNAs

We have studied the time-resolved and the steady-state fluorescence of the DNA groove binders 4',6-diamidino-2-phenylindole (DAPI) and Hoechst 33258 with the double stranded DNAs poly(dA-dU) and poly(dI-dC) and their halogenated analogs, poly(dA-I5dU) and poly(dI-Br5dC). These studies were prompted by earlier observations that steady-state fluorescence of Hoechst 33258 is quenched on binding to halogenated DNAs (presumably due to an intermolecular heavy atom effect involving the halogen atom in the major groove), and recent studies which clearly point to a binding-site in the minor groove of DNA. Measurements of the time resolved fluorescence decay demonstrate that the fluorescence of Hoechst 33258 is quenched on binding to the halogenated DNAs, in agreement with previous observations. However, quenching studies carried out using the free halogenated bases IdUrd and BrdCyd in solution yielded bimolecular rate constants more than one order of magnitude larger than those expected for an intermolecular heavy atom effect. Moreover, the quenching of the Hoechst 33258 fluorescence was accompanied by an accelerated photochemical destruction of Hoechst 33258. We therefore conclude that the fluorescence quenching observed with halogenated DNAs is probably due to a photochemical reaction involving Hoechst 33258, rather than direct contact of Hoechst 33258 with the halogen substituents in the major groove of the DNA. The fluorescence decay measurements however, do provide clear evidence for at least two different modes of binding. Taking into account the alternating sequences used in this study and the possibility of two different conformations for bound dye, at least four different modes of binding are plausible. Our present data do not allow us to distinguish between these alternatives. The time-resolved fluorescence decays and fluorescence quantum yields of DAPI are not affected by the presence of the heavy atom substituents in the DNA major groove. Based on this observation and earlier reports that DAPI binds in one of the DNA grooves, we conclude that the high affinity sites for DAPI on DNA are located in the minor groove.     

HEMATOPORPHYRIN DERIVATIVE UPTAKE BY ATHEROMA IN ATHEROSCLEROTIC RABBITS: THE SPECTRA OF FLUORESCENCE FROM HEMATOPORPHYRIN DERIVATIVE DEMONSTRATED BY AN EXCIMER DYE LASER

Abstract A new diagnostic and therapeutic endoscopic system consisting of an excimer pulse dye laser is presented. This report demonstrates the accumulation of hematoporphyrin derivative (HpD) in atheroma as shown by the fluorescence of HpD using this equipment. Atheroma was induced in the aorta of WHHL (Watanabe heritable hyperlipidemic) rabbits, 5 mg kg⁻¹ HpD was injected intravenously and the rabbits were sacrificed 24 h later. The aorta was dissected and the localization of HpD was examined. Characteristic peaks of the fluorescence of HpD at 630, 665 and 690 nm wavelength were detected in the atheromatous lesion. However, in the fatty plaque, the emission peak at 630 nm was lower and the 665 nm peak faded away. No fluorescence with peaks was detected in the normal area. The ratio of fluorescence intensity in atheroma, border zones and normal areas was 10.4 : 5.0 : 1.0. On normal rabbits made atherosclerotic by diet and balloon damage, an ultra thin endoscopic catheter was inserted from the descending aorta of atherosclerotic rabbits under anesthesia. Essentially the same data was obtained by these studies in vivo as was obtained in the in vitro studies. The above data suggests the possibility of future applications of this equipment for diagnosis of atheroma.     

CELLULAR BINDING OF HEMATOPORPHYRIN DERIVATIVE IN HUMAN BLADDER CANCER CELL LINES: KK-47

Abstract— The fluorescence lifetime and degree of fluorescence polarization of hematoporphyrin derivative (HpD) have been investigated using different solutions: organic and micellar solutions. Ham's F12 medium, and KK-47 cell suspension. The lifetime and polarization degree in organic and micellar solutions did not change with increasing incubation time, but the polarization degree in the cell suspensions temporarily increased at the initial incubation time and then decreased 4 h after incubation. The lifetime in the cell suspensions exhibited a bi-phasic exponential decay. The results obtained suggested that mainly dimeric HpD may bind weakly to the cell membrane, and then slowly be distributed throughout the cytoplasm. The polarity and viscosity of the intracellular loci containing HpD were evaluated from the fluorescence polarizations of HpD in MeOH-H₂O mixtures and ethylene glycol(EG)-MeOH mixtures. The dielectric constant and viscosity of the loci containing HpD were 35 and 11 cp, respectively. Accordingly, the intracellular location of HpD were considered relatively hydrophilic loci of the cells.     

FLOW CYTOMETRIC ANALYSIS OF INTRACELLULAR HEMATOPORPHYRIN DERIVATIVE IN HUMAN TUMOR CELLS AND MULTICELLULAR SPHEROIDS

Flow cytometry (FCM) has been used to investigate the intracellular fluorescence of hematoporphyrin derivative (HPD) in monolayer and spheroid cultures of WiDr cells. For exponentially-growing monolayer cultures mean cellular fluorescence was directly proportion to the external HPD levels in the range 5-100 micrograms ml-1 (r = 0.99). Heterogeneity of cellular fluorescence was quantified by determining the ratio of the fluorescence value below which were observed values for 98% of the cell population compared to the fluorescence value for 2%. In exponentially-growing cultures, decreasing levels of HPD in the medium led to an increase in the 98:2% ratio, i.e. an increase in heterogeneity of intracellular drug levels. The growth of cells as multicellular spheroids confers a spheroid-size-dependent resistance to photodynamic treatment. With increasing spheroid size (100, 250, 500, 750 and 1000 microns diam.) there was a decrease in mean intracellular HPD levels and a large linear increase in the 98:2% ratio (r = 0.94).     

INTERDEPENDENCE OF FLUENCE, DRUG DOSE and OXYGEN ON HEMATOPORPHYRIN DERIVATIVE INDUCED PHOTOSENSITIZATION OF TUMOR MITOCHONDRIA

Abstract— Studies were conducted to assess the interdependence of three discrete parameters known to influence hematoporphyrin derivative (Hpd)-induced photosensitization. The effects of fiuence, drug dose and oxygen environment were examined for their role in causing an inhibition of the activity of mitochondrial cytochrome c oxidase. Experiments were performed on R3230AC mammary tumor mitochondria in vitro and on mitochondria isolated from tumors of animals pre-treated with Hpd in vivo. Inhibition of cytochrome c oxidase activity was observed to be directly proportional to total energy density. Photosensitization was dependent on oxygen concentration, with total energy density dependent photosensitization being diminished in environments containing less than 5% oxygen. At 1% oxygen environments, photosensitization was significantly impaired and demonstrated no drug-dose relationship. These results suggest that tissue oxygen concentration may represent a critical factor for the therapeutic usefulness of Hpd photodynamic therapy in treatment of cancer.     

PHOTOSENSITIZED LYSIS OF LIPOSOMES BY HEMATOPORPHYRIN DERIVATIVE

The spectral properties and efficiency for photosensitizing the lysis of phosphatidylcholine liposomes have been measured for the components of hematoporphyrin derivative (Hpd) after alkaline hydrolysis and fractionation by polyacrylamidc gel chromatography. Two major and two minor Hpd fractions have been identified whose spectral properties correlate with the anoxic sensitizing efficiency and the oxygen enhancement ratio (OER). The fastest moving fraction, which is the putative biologically active component, comprised one-third of the starting material and had OER = 2.7. Liposome lysis by this fraction was inhibited in the presence of human serum albumin at concentration ratios comparable to those employed for photoradiation therapy. The present results show that Hpd can act as an oxic and anoxic photosensitizer of a model biomembrane and suggest that separation from serum proteins is required for in vivo photosensitization.     

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.     

SOME COMPONENTS OF THE TUMOR-LOCALIZING FRACTION OF HEMATOPORPHYRIN DERIVATIVE

In continuation of the effort to delineate the structure of Photofrin, a chromatographically well separated component of the tumor-localizing fraction was isolated and purified using a combination of gel filtration chromatography and semi-preparative high-performance liquid chromatography. This component, the least hydrophobic of the tumor-localizing fraction, was deemed to be dihematoporphyrin ether, based on mass spectrometric analysis and its behavior toward base hydrolysis and lithium aluminum hydride reduction. Although less potent than Photofrin, the purified component was an active photosensitizer.     

FLUORESCENCE STUDY OF THE PHYSICO-CHEMICAL PROPERTIES OF A BENZO(A)PYRENE7,8-DIHYDRODIOL9,10-OXIDE DERIVATIVE BOUND COVALENTLY TO DNA

Abstract— Covalent complexes between 7 ,8-dihydrodiol 9.10-oxide benzo(a)pyrene (BPDE) and DNA with a modification of one BPDE molecule per 1000 DNA bases were prepared in vitro . The same stereoselective and chemically homogeneous binding of BPDE to native DNA was observed, as reported earlier for human and bovine bronchial explants. The fluorescence of the pyrene-like aromatic moiety of BPDE bound to DNA in vitro was used as a probe of the microenvironment of the BPDE molecule in order to obtain information about the structure of the BPDE-DNA complex dissolved in aqueous solution. Fluorescence techniques, based on the quenching of the singlet excited states by metal ions such as Ag⁺, by iodide ions, and by molecular oxygen are described, which provide a method for differentiating between external and internal (intercalation) binding of polycyclic aromatic molecules to DNA. Silver ions, which bind specifically to DNA bases, exhibit a strong quenching effect on noncovalently bound, intercalated benzo(a)pyrene; on the other hand, there is no quenching effect on the fluorescence of BPDE in the covalent DNA adduct. Quenchers such as O₂ and iodide ions, which do not specifically bind to DNA and are dissolved in the solution external to the DNA molecule, exhibit a quenching effect on the BPDE chromophore. Furthermore, the fluorescence yield of the BPDE-DNA complex decreases with increasing DNA concentration, an effect which is not observed with non-covalently bound intercalated benzo(a)pyrene-DNA complexes, and which is attributed to intermolecular DNA-DNA interactions. The results of these studies indicate that the pyrene-like chromophore in the covalent BPDE-DNA complex is not intercalated between the base pairs, and that it is located in an accessible region external to the DNA helix. Possible structures are discussed.     

LOCAL NEUROTOXICITY OF HEMATOPORPHYRIN DERIVATIVE FOLLOWING INTRACEREBRAL INJECTION

The present study reports on toxicity of hematoporphyrin derivative (HpD) for normal brain tissue in vivo without the addition of light. Hematoporphyrin derivative was injected by slow infusion in rat brains. Histological examination was carried out for intervals after HpD administration, ranging from 0 h to 15 days. Ultrastructural changes were examinated with transmission electron microscopy. The extent of the necrosis was determined for different HpD concentrations and compared with control animals infused with 0.9% saline. Leukocytic infiltration was observed at day 5. Transmission electron microscopy showed that nuclei of neurons were completely disintegrated 4 h after HpD administration. Furthermore disruption of myelin sheaths was observed. The extent of the necrosis decreased with lower HpD doses. Injection of 2 μg HpD in a volume of 4 μL (0.5 mg/mL) resulted in a virtually equal extension of the tissue damage, as compared to the mechanical damage in the control animals caused by the infusion procedure.     

PHOTOSENSITIZING EFFECTS OF HEMATOPORPHYRIN DERIVATIVE IMMOBILIZED ON SEPHAROSE

Abstract— The cytotoxicity that ensues following photosensitization by hematoporphyrin derivative (Hpd) is attributed to production of singlet oxygen. Many of the cellular end points reported to be affected are localized to membranes, hydrophobic environments conducive to partitioning of hydrophobic porphyrins in Hpd. In order to test the hypothesis that efficacy of Hpd-induced photosensitization is enhanced by its ability to freely enter cells or subcellular organelles, we immobilized Hpd on a sepharose support. This immobilized reagent was found to produce ¹O₂ when photoradiated, in yields similar to those observed for Hpd in solution, as evidenced by the bleaching of p -nitrosodimethylaniline in the presence of imidazole. The immobilized Hpd was capable of photosensitizing, i.e. inhibit, cytochrome c oxidase activity in intact mitochondrial membranes and in aqueous solution. However, enzymes located on the interior of mitochondrial membranes (F₀F₁ ATP synthase and succinate dehydrogenase), in the mitochondrial matrix (malate dehydrogenase), or on the inside of the plasma membrane, (Na++ K+)- ATPase, were unaffected by immobilized Hpd plus photoradiation compared to free Hpd. The results suggest that photosensitization by Hpd most likely arises from entry of the photosensitizer into the biological membrane, although proteins on the exterior membrane surface may be susceptible to damage by ¹O₂ produced in proximity to their location.     

NMR STUDY ON THE MAJOR COMPONENTS IN HEMATOPORPHYRIN DERIVATIVE YHPD

The hematoporphyrin derivative YHPD, a China-made product, has been clinically used in photodynamic therapy of tumors as a good photosensitizing drug. The NMR study on the structure of its major components is reported here. In terms of high performance liquid chromatography (HPLC) four major components A, B, C and D were isolated. The NMR results showed that the component A is O-acetylhematoporphyrin, B and C are two isomers of vinyldeuteroporphyrin. The spectra of 2-dimensional homonuclear correlation NMR, 2-dimensional NOE (nuclear overhauser enhancement), ~(13)C-NMR and off-resonance as well as FAB (fast atom bombarding) mass spectrum of component D indicate that it is a protoporphyrin dimer linked by carbon-carbon bond. This finding may providea chemical basis for understanding the difference in biological activity between YHPD and other foreign commercial HPD, as well as the composition of clincally used alkali-treated HPD and its effective component.     

EQUILIBRIUM AMONG HEMATOPORPHYRIN DERIVATIVE COMPONENTSs—II. EFFECT OF ESTERASE ACTIVITY

Photofrin II is the hematoporphyrin-derivative fraction enriched in covalently-linked oligomers, characterized by a high degree of folding. Interaction with hydrophobic structures, such as biomolecules and cell structures, results in a modification of the equilibria among the different species, as a consequence of an unfolding effect exerted towards the electrostatic aggregates. The effect of esterase activity was evaluated, taking into account the nature suggested for the covalent linkage of the oligomers (ether and/or ester). The study was performed in Photofrin II aqueous solution by means of absorption and fluorescence spectral analysis. The results showed that the esterase is active only towards the unfold oligomers: that is, in Photofrin II solution supplemented with albumin. In these conditions, spectral analysis revealed the presence of a monomerization process, which is clearly evident during the first four hours of incubation. The monomerization effect induced by the enzyme was also proven by both equilibrium-dialysis measurements and zinc ion complexation. Zinc ion complexes with high affinity for monomeric species, giving rise to a very distinct emission band at 580 nm. The amount of ester linkage shown in the oligomers through enzyme hydrolysis appeared to be less than might have been expected, owing to the inhibiting effect of the monomer produced on the enzyme. The results are a step toward clarifying the intracellular and intratissue turnover of the drug observed after administration.     

THE STRUCTURE OF THE ACTIVE MATERIAL IN HEMATOPORPHYRIN DERIVATIVE

Abstract The structure of the active material in hematoporphyrin derivative is shown to be a condensation polymer of hematoporphyrin linked by ether functional groups. When a mixture of the monoacetates and the diacetate of hematoporphyrin is treated with dilute sodium hydroxide solution a polymeric fraction is formed which constitutes the active material of hematoporphyrin derivative. This fraction is stable to basic hydrolysis using conditions which are shown to hydrolyse porphyrin esters, but is hydrolysed by acidic conditions which cleave porphyrin ethers as well as esters. When hematoporphyrin diacetate is similarly treated with base a polymeric fraction is formed which is hydrolysed by both acidic and basic conditions showing it to be ester linked. This ester linked polymer is unstable in aqueous solution at pH 7 and converts to the polyether within 2 days at room temperature.