INACTIVATION AND MUTAGENESIS OF Herpes VIRUS BY PHOTODYNAMIC TREATMENT WITH THERAPEUTIC DYES

Dyes which photosensitize membranes may be clinically useful for photodynamic treatment (PDT) of Herpes simplex virus (HSV) infections. It is important to determine whether the enveloped HSV can be inactivated via membrane damage without affecting the genetic material. Selection of appropriate PDT conditions, including the choice of dye, could minimize viral mutagenesis. We determined the mutagenesis caused by PDT employing three membrane-photosensitizing dyes of potential use in cancer photochemotherapy (Photofrin II, polyhematoporphyrin esters, zinc phthalocyanine tetrasulfonates) and a DNA-photosensitizing dye (proflavine sulfate). The effects were compared to those caused by exposure of HSV to ultraviolet radiation (UV). The procedure consisted of incubating HSV with microgram/ml (microM) concentrations of the dye, irradiating the samples with broad spectrum visible/near-UV radiation (Daylight fluorescent lamps) and assaying the survival of the treated HSV. Zinc phthalocyanine was the most potent dye per absorbed photon for inactivating HSV. In parallel with determination of survival, progeny of the surviving virus were grown for determination of mutagenesis. The progeny virus was harvested and subsequently assayed in the presence and absence of 40 micrograms/ml iododeoxycytidine (ICrd) to determine the frequency of mutation to ICrd resistance. Mutation frequencies were determined for progeny from the 1-4% survival level. For PDT with each membrane-photosensitizing dye, only zinc phthalocyanine increased the mutation frequency over the untreated control. This increase was less than 2-fold. Proflavine increased the mutation frequency 2-3 fold over the untreated control. Ultraviolet produced a 15-20 fold increase over the untreated control.(ABSTRACT TRUNCATED AT 250 WORDS)     

A SELF-CONSISTENT-FIELD STUDY OF THE EXCITED STATE π-ELECTRON CHARGES IN PHENOL

Abstract— –The semiempirical self-consistent-field (SCF) method was used to calculate the net π-electron charges for phenol in the first excited singlet and first excited triplet states. These calculations differ from the usual ground state calculations in that (i) recently available static excited state data were used wherever possible as the empirical basis for evaluating SCF parameters and (ii) the theory of density matrices was used to include the effects of all singly-excited configurations in the configuration interaction contributions to the excited state π-electron charge densities.     

PHOTODYNAMIC INACTIVATION OF RUBELLA VIRUS ENHANCES RECOMBINATION WITH A LATENT VIRUS OF A BABY HAMSTER KIDNEY CELL LINE BHK21*

Rubella virus is very sensitive to photodynamic action. When tested with 1.2 X 10(-5) M toluidine blue and 8 W fluorescent lamp at a fluence of 11 W/m2, inactivation kinetics showed a linear single hit curve with a k value of 1.48 min-1. Photodynamic inactivation of rubella virus greatly enhanced recombination with a latent virus (R-virus) of baby hamster kidney BHK21 cells. In contrast, no hybrids were detected in lysates of the cells infected with either UV-treated or untreated rubella virus. Therefore, hybrid viruses were readily detected only in lysates of BHK21 cells infected with photodynamically treated rubella virus. Photodynamic damage of rubella virus genomes generated a new hybrid type (hybrid type 3) in addition to a previously described type 2 hybrid (formerly designated as HPV-RV variant). Although both of these hybrid types carry the CF antigens of rubella virus, plaque forming ability of type 3 hybrid is neutralized neither by anti-rubella serum nor by anti-latent virus serum while type 2 hybrid is neutralized by anti-latent virus serum.     

PHOTODYNAMIC INACTIVATION OF AN ION CHANNEL: GRAMICIDIN A

The ion channel formed by the peptide gramicidin A in planar lipid membranes is inactivated by visible light in the presence of the photosensitizer Rose Bengal. This is concluded from the strong decrease of the membrane conductance by more than two orders of magnitude. Experiments performed at different oxygen concentrations, in the presence of the singlet oxygen quenchers beta-carotene or alpha-tocopherol indicate, that presumably a type I process between the dye Rose Bengal and the tryptophan residues of the gramicidin channel with a subsequent oxidation of the tryptophans is responsible for the loss of the conductance properties of the channel.     

INACTIVATION OF Trypanosoma cruzi TRYPOMASTIGOTE FORMS IN BLOOD COMPONENTS BY PHOTODYNAMIC TREATMENT WITH PHTHALOCYANINES

Abstract— -Three phthalocyanine dyes HOSiPcOSi(CH₃)₂(CH₂)₃N(CH₃)₂ (Pc 4), HOSiPc-OSi(CH₃)₂(CH₂)₃N+(CH₃)3I- (Pc 5) and aluminum tetrasulfophthalocyanine hydroxide (AlOHPcS₄) were evaluated for their ability to inactivate the trypomastigote form of Trypanosoma cruzi in fresh frozen plasma (FFP) and red blood cell concentrates (RBCC). The compound Pc 4 was found to be highly effective in killing T. cruzi, Pc 5 less effective and AlOHPcS₄ ineffective. With FFP as the medium, a complete loss of parasite infectivity in vitro (≥5 log₁₀) was found to occur with 2 μ M Pc 4 after irradiation with red light (>600 nm) at a fiuence of 7.5 J/cm², while with RBCC as the medium, a complete loss was found to occur at a fiuence of 15 J/cm². Even without illumination, Pc 4 at 2 μ M also killed about 3.7-4.1 log₁₀ of T. cruzi in FFP during 30 min. Observed differences in T. cruzi killing by the various phthalocyanines may relate to differences in binding; Pc 4 binds to the parasites about twice as much as Pc 5. Ultrastructural analysis of treated parasites suggests that mitochondria are a primary target of this photodynamic treatment. The data indicate that Pc 4 combined with exposure to red light could be used to eliminate bloodborne T. cruzi parasites from blood components intended for transfusion. The inactivation of T. cruzi by Pc 4 in the dark suggests a possible therapeutic application.     

THE EFFECTS OF ULTRAVIOLET RADIATION EXPOSURE OF ADJACENT CELLS ON PLAQUE FORMATION WITH Herpes simplex VIRUS TYPE I

African green monkey kidney cells (CV-1P) were exposed to low fluences of 254 nm germicidal radiation and then infected with Herpes simplex virus, type I. The result of this treatment was an increase in viral plaque development rate, the large plaque effect (LPE). A measurement of the kinetics of plaque development suggested that a large portion of the effect could be due to events occurring in those cells that are adjacent to the initially infected cell. An infectious center assay was employed in order to isolate the effects of ultraviolet radiation (UV) on the initially infected cells from those effects on the adjacent cells that became infected as the plaque spread radially outward. Plaque development began earlier in UV irradiated cells and progressed at a uniformly accelerated rate compared to untreated cells. Results indicate that although the initially infected cell contributes to the LPE, the major effect is due to events that occur in the adjacent cells. Each round of viral replication appears to contribute equally to the LPE. The virally induced rate of fusion of the initially infected cell with its immediate neighbors is not affected by UV.     

ABSORPTION OF METHYLBACTERIOPHEOPHORBIDE a SINGLE CRYSTALS: SPECTRAL SHIFTS DUE TO π-π INTERACTIONS

Abstract— Polarized absorption spectra were obtained for a single crystal of methylbacteriophorbide a (MeBPhide a). The Q_y band is red-shifted ∽ 1660 cm^-1 (∽ 110 nm) relative to MeBPhide a in a CH₂Cl₂/benzene solution. This is equivalent to the largest red shifts observed for in vivo bacteriochlorophyll a. The Soret band exhibits a smaller red shift and a significant reduction in intensity, and the Q_x band is not observed. The crystal spectra are qualitatively similar to spectra reported for several other aggregated (bacterio)chlorophyll and bacteriopheophytin systems. Since crystalline MeBPhide a contains no Mg, water or hydrogen bonding (Barkigia etal. , 1981), these results demonstrate that the spectral changes associated with the aggregation of photosynthetic chromophores can arise solely from IT-IT interactions between macrocycles.     

PICOSECOND ABSORPTION STUDIES OF Zn-OCTAETHYLPORPHIN π-MONOANIONS

Abstract— Using the example of Zn-octaethylporphin π-monoanion solution in tetrahydrofuran, we studied the dynamics of ultrafast photoprocesses in porphyrin π-anions using a tunable picosecond absorption spectrometer. The deactivation kinetics of the lowest excited electronic (doublet) state of Zn-octaethylporphin iT-monoanion has been determined and was found to be followed by a single exponential function with the characteristic time 135 ps. It is shown that upon picosecond excitation to the long wavelength absorption band (λ_max= 830 nm) the process of two-quantum photoionization of the involved monoanion is easily realized, with the results that the observable kinetics of spectral changes exhibit a strong dependence on the excitation intensity.     

IMPORTANCE OF TYPE I AND TYPE II MECHANISMS IN THE PHOTODYNAMIC INACTIVATION OF VIRUSES IN BLOOD WITH ALUMINUM PHTHALOCYANINE DERIVATIVES

The relative importance of type I and type II mechanisms in the photodynamic treatment of red blood cell concentrations (RBCC) to inactivate viruses was studied using aluminum phthalocyanine tetrasulfonate (AlPcS4), visible light and quenching or enhancing agents of reactive forms of oxygen. Treatment of a human RBCC with 10-13 microM AlPcS4 and 25-26 mW/cm2 visible light resulted in the rapid and complete inactivation of added vesicular stomatitis virus (VSV). The addition of mannitol, glycerol, reduced glutathione (GSH), or superoxide dismutase (SOD), known quenching agents of type I mechanisms, had little to no effect on the rate of inactivation of VSV. Significant inhibition of VSV kill was observed on addition of tryptophan or sodium azide, known quenchers of type II mechanisms. Additionally, the rate of VSV kill was enhanced in the presence of D2O. Taken together, these results indicate a predominant role of singlet oxygen in the inactivation of VSV on photodynamic treatment of RBCC. The relative importance of type I and type II mechanisms on cellular toxicity was also evaluated. Little, if any hemoglobin release was observed on treatment of human or rabbit RBCC with 10 microM AlPcS4 and 44 J/cm2 of visible light in the presence or absence of the above mentioned quenchers. The effect of the addition of quenchers on the recovery and circulatory survival of treated, autologous rabbit RBCC, labeled with 51Cr, was also assessed.(ABSTRACT TRUNCATED AT 250 WORDS)     

UROCANIC ACID ANALOGUES AND THE SUPPRESSION OF THE DELAYED TYPE HYPERSENSITIVITY RESPONSE TO Herpes simplex VIRUS

Ultraviolet irradiated urocanic acid (4-imidazoleacrylic acid) containing a mixture of cis- and trans-isomers has been shown previously to induce suppression of the delayed type hypersensitivity (DTH) response to Herpes simplex virus type 1 (HSV-1) in a murine model of infection. The cis-isomer of urocanic acid was prepared and the cis- and trans-isomers of 2-methylurocanic acid. 2-pyrroleacrylic acid, 2-furanacrylic acid, 2-thiopheneacrylic acid, 3-thiopheneacrylic acid as well as dihydrourocanic acid and histamine. Each was applied at concentrations of 1 and 50 micrograms per mouse to the shaved dorsal skin and the mice were infected subcutaneously with HSV 5 h later. After 8-10 days the DTH response to the virus was measured by an ear swelling test. It was found that cis-urocanic acid was effective in suppressing the DTH response at levels of 1 microgram per mouse or less. The cis- and trans-isomers of 2-furanacrylic acid, 2-pyrroleacrylic acid and 2-thiopheneacrylic acid were also effective, with the cis- form generally being more active than trans, and 2-pyrroleacrylic acid being particularly potent. Cis- and trans-3-thiopheneacrylic acid, on the other hand, were only marginally immunosuppressive while neither isomer of 2-methylurocanic acid had any suppressive ability. Dihydrourocanic acid and histamine were also shown to suppress the DTH response. Thus the structural features necessary for urocanic acid and its analogues to act as mediators of UV-induced immunosuppression could be deduced and implications for their mechanism of action discussed.     

ENERGY TRANSFER-ENHANCED CHEMILUMINESCENCE OF ADAMANTANONE (n,π*) AND ESTER (π,π*) SINGLET AND TRIPLET EXCITED STATES IN THE THERMOLYSIS OF SILYLOXYARYL-SUBSTITUTED SPIROADAMANTYL DIOXETANES†

Abstract— The thermal generation of singlet and triplet excited states from silyloxyaryl-substituted spiroadamantyl dioxetanes lab and the adamantylidineadamantane dioxetane (1c) was investigated by direct and enhanced chemiluminescence (CL). 9,10-Diphenylanthracene (DPA) and 9-fluorenone were used as energy acceptors in the singlet-singlet (S-S), naphthalene and europium chelate Eu(TTA)₃Phen (TTA = thenoyltrifluoroacetone, Phen = 1,10-phenanthroline) in the triplet-triplet (T-T) and 9,10-di-bromoanthracene (DBA) in triplet-singlet (T-S) energy transfer experiments. The direct chemiluminescence observed in the thermolysis of dioxetanes lab consisted of fluorescence derived from the singlet-excited adamantanones 2a,b. In the presence of naphthalene, selective T-S energy transfer with DBA (napthalene as quencher) displayed the adamantanone triplets 2a,b and with Eu(TTA)₃Phen (naphthalene as mediator) also the silyloxyaryl ester 3 triplets. From the Stern-Volmer constants (k_TNT_T⁰) the triplet lifetimes t⁰_t of these triplet state products were assessed. By using the Hastings-Weber standard, the total triplet excitation yield (φ^t) was estimated to be ca 20%. The energies of the first excited singlet and triplet states of the adamantanones 2a,b and the silyloxyaryl ester 3, the products of the thermally induced decomposition of dioxetanes la-c , were determined by semiempirical calculations (AMI-based configuration interaction), which included explicitly solvent effects on the excitation energies in terms of a self-consistent reaction field approach. The calculations revealed that the first excited singlet and triplet states of the adamantanones 2a,b are expectedly n,π*-type excitations while the silyloxyaryl ester 3 possesses π,π* character. The semiempirical computations suggest that excitation of the adamantanones 2a,b as well as the silyloxyaryl ester 3 is feasible in the thermolysis of the spiroadamantyl dioxetanes lab , which has been confirmed by the experimental energy transfer studies.     

PHOTODYNAMIC THERAPY OF HUMAN BLADDER CANCER CELLS in vitro CORRELATED WITH CELLULAR FLUORESCENCE LEVELS OF PHOTOFRIN-II

Abstract In order to determine optimum dose of Photofrin-II (PHI) timing and dose of laser therapy and differential effects of laser on normal and neoplastic human bladder cancer cells in vitro , experiments were carried out using 3 cell lines of human bladder cancer (253-J, 639-V, and 647-V) and a human fibroblast line (CRL-1507). Cellular Pf-II uptake and excretion studied using flow cytometric fluorescence analysis of the cells and fluorescence levels of the culture medium showed a wide variability of uptake of Pf-II among the cell lines. Pf-II excretion occurred most rapidly in the first 4 h after incubation reaching maximum at 24-48 h in all cells studied. Cellular concentration of Pf-II and supernatant levels of Pf-II estimated by fluorescence levels had a reciprocal correlation. Laser treatment of one cancer line and the fibroblast line at 20 J (630 nm) at various times after incubation with 50 μ.g m^−l of Pf-II showed that the photodynamic effect correlated directly with cellular fluorescence. These results suggest that in vitro: (1) initial uptake of Pf-II is generally higher in neoplastic than normal cells but that excretion rates are similar; and (2) photodynamic effect is related primarily to initial cellular levels of photosensitizer rather than differential excretion rates.     

PHOTODYNAMIC INACTIVATION OF R3230AC MAMMARY CARCINOMA IN VITRO WITH HEMATOPORPHYRIN DERIVATIVE: EFFECTS OF DOSE, TIME, and SERUM ON UPTAKE and PHOTOTOXICITY

Abstract Primary cultures of the R3230AC mammary adenocarcinoma were used for pharmacokinetic studies of hematoporphyrin derivative (HPD), a preparation containing several porphyrin species and useful as a photoactivatable anti-tumor agent. Uptake of HPD in vitro was shown to be time-, dose- and temperature-dependent with an apparent plateau reached at 2 - 4 h. An increase in the amount of serum in the medium progressively reduced the amount of HPD taken up by the cells; at a level of 10% serum, uptake of HPD was reduced by >95%. The time-course of efflux of HPD from these cells demonstrated a complex pattern, with an initial rapid component followed by a more gradual rate of efflux up to 4 h. Assessment of photoradiation-induced cytotoxicity was performed by a method developed to quantitatively measure trypan blue exclusion. Relative cytotoxicity was determined by use of heat-killed cells as a standard. At two different concentrations of HPD, cytotoxicity was dependent on light exposure time. The presence of serum, which reduced uptake of HPD was correctable to reduced cytotoxicity. Based on the amount of light exposure to produce 50% cell kill, an order of potency was obtained for HPD > hematoporphyrin > hydroxyethylvinyldeuteroporphyrin in vitro. This order of potency correlated with the relative proportion of hydrophobic components as estimated by HPLC analysis. The results indicate that HPD is an effective cytotoxic agent in vitro in a well-differentiated mammary adenocarcinoma model.     

MODE OF ACTION OF α-TERTHIENYL ON ESCHERICHIA COLI: EVIDENCE FOR A PHOTODYNAMIC EFFECT ON MEMBRANES

The photodynamic effects of α-terthienyl (αT) in near-UV light (UV-A) on Escherichia coli showed close agreement with the light absorption of αT at different wavelengths suggesting that αT is the primary absorbing molecule responsible for the photosensitized reaction. Studies with DNA repair deficient mutants of E. coli indicated that the bactericidal action of αT/UV-A was not mediated by DNA damage, in direct contrast to the well-known photosensitizer, 8-methoxypsoralen. By using a closed borosilicate glass reaction vessel and various gas mixtures, it was demonstrated that photosensitization of both E. coli and a more resistant bacterium, Pseudomonas aeruginosa , was absolutely dependent on the presence of oxygen. The rate of killing by αT/UV-A showed a rather small dependence on preincubation temperatures, with quite rapid killing at 5°C, suggesting that the movement of αT across the cytoplasmic membrane of E. coli is not the rate limiting step in killing and perhaps is not even necessary for killing. Sodium dodecyl sulphate-polyacrylamide gels of cell membrane proteins after 15 and 30min of treatment with αT/UV-A showed substantial random crosslinking of these proteins. The results taken overall suggest that αT is a photodynamic photosensitizer which exerts its primary effect at the level of the cytoplasmic membrane.     

ROLE OF THE TRYPTOPHAN FLUORESCENT STATE IN THE ULTRAVIOLET-INDUCED INACTIVATION OF β-TRYPSIN*

Abstract— Stern-Volmer quenching constants for β-trypsin at pH 3 were determined for fluorescence quenching by histidine, acrylamide, and nitrate ion. A modified Stern-Volmer plot (Lehrer, 1971) was employed to show that all of the fluorescent tryptophanyl residues of β-trypsin were equally susceptible to quenching by acrylamide at pH 3 when the enzyme was either in its native conformation or denatured in 6 M guanidine hydrochloride (GuHCl). Fluorescence lifetime measurements indicated that acrylamide quenched β-trypsin fluorescence by a purely collisional mechanism. Solvation of tryptophanyl residues of the protein was maximal at 2.5 M GuHCl, as monitored by fluorescence emission wavelength.
Investigations of the ultraviolet-induced inactivation of β-trypsin at 295 nm were performed in the presence of acrylamide at pH 3. The quantum yields for enzyme inactivation and indole destruction (determined using the PDAB reagent) were unchanged upon depopulation of the fluorescent state by 65 per cent, whether the enzyme was in its native conformation or denatured by 6 M GuHCl. It is concluded that the fluorescent state of tryptophanyl residues of β-trypsin is not involved in enzyme inactivation or tryptophan destruction.     

STUDIES ON THE INACTIVATION OF TOBACCO MOSAIC VIRUS BY ULTRAVIOLET LIGHT*,‡,§

Abstract— The irradiation of TMV with u.v. light of 2537 Å wavelength results in the binding of protein subunits to the RNA. These bound subunits are stable towards warm sodium dodecyl-sulfate; however, the binding is not covalent since the subunits are removed by 66% acetic acid, guanidine hydrochloride, or phenol. Approximately one protein subunit is bound per lethal biological 'hit'. The virus and the nucleic acid extracted from irradiated virus show virtually identical rates of inactivation.     

PHOTODYNAMIC EFFECTS OF PROFLAVINE ON BACTERIOPHAGE φ times 174 AND ITS ISOLATED DNA

Abstract. Proflavine-mediated photoinactivation of φ times 174 phage and its isolated DNA was studied under identical irradiation conditions. The inactivations followed single-hit kinetics and a linear relationship was obtained in reciprocal plots of the inactivation rates vs the proflavine concentrations for both phage and isolated DNA. The phage photoinactivation rate was increased with an increase in the amount of proflavine bound to the phage DNA in a strong binding range (0.01-0.04 proflavine/ nucleotide) as the total proflavine concentration was increased or the ionic strength decreased. Further, a phage-specific factor was also found to affect the inactivation rate. The photodynamic treatment induced mutations in three phage strains from "amber" to "wild type" at a mutation rate per lethal hit of 0.3 times 10^-5 to 2.6 times 10^-5. In contrast to phage infectivity, the φ times 174 DNA infectivity was measurable only at a high multiplicity of infection, and its photoinactivation occurred only at high proflavine concentrations. The photoinactivation rate was enhanced either with a decrease in the multiplicity of infection or with the use of spheroplasts of recA mutants strains. The results are discussed in terms of the nature of and possible repair mechanisms of photodynamically induced lesions in φ times 174 phage DNA.