PHTHALOCYANINE PHOTOSENSITIZATION OF MAMMALIAN CELLS: BIOCHEMICAL and ULTRASTRUCTURAL EFFECTS

Abstract— The concentrations of Na⁺, K⁺, Ca²⁺, Mg²⁺ and CI⁻ ions in the cytoplasm of octopus photoreceptor cells were determined before and after illumination by electron probe X-ray microanalysis. The concentrations of these elements in the dark-adapted photoreceptor cells were: Na⁺, 68.4; K⁺, 111.4; Ca²⁺, 4.0; Mg²⁺, 16.4; and CI⁻, 102.9 m M /kg of cytoplasm. Illumination raised the concentration of Na⁺ by 58 m M and that of Cl⁻ by 23 m M and reduced the K⁺ concentration by 47 m M /kg of cytoplasm. A trace increase of intracellular Ca²⁺ and a trace decrease of Mg²⁺ were observed. These results confirm the hypothesis that sodium ions flow in on illumination, and suggest the influx of chloride ions and the outflux of potassium ions during illumination. The intracellular concentrations of Na⁺, K⁺ and Cl⁺ can give the basis for calculating the ion permeability of ion channels in octopus photoreceptor cell membranes, using values of the membrane potentials obtained by electrophysiological studies     

EFFECTS OF K+ AND Ca2+ IONS ON MOTILITY AND PHOTOSENSORY RESPONSES OF STENTOR COERULEUS

Extracellular K⁺ ions above a critical concentration induce ciliary reversal in unstimulated Stentor coeruleus and suppress step-up photophobic response. This threshold concentration of K⁺ ions depends on the extracellular Ca²⁺ concentration, and the subsequent backward gyration and light-sensitivity suppression seem to depend on the relative concentrations of K⁺ and Ca²⁺. The concentration of Ca²⁺ necessary to overcome K⁺-mediated inhibition of phobic response and backward swimming increases non-linearly with increasing K⁺ concentration. The Ca²⁺-blocking agent. D-600, selectively inhibits photophobic responses of Stentor , thus further confirming the role of Ca²⁺ ions in photosensory transduction of this ciliate.     

ULTRAVIOLET IRRADIATION OF NUCLEIC ACIDS COMPLEXED WITH HEAVY ATOMS—III. INFLUENCE OF Ag + AND Hg 2+ ON THE SENSITIVITY OF PHAGE AND OF TRANSFORMING DNA TO ULTRAVIOLET RADIATION

Abstract— We have studied the influence of the heavy metal ions Ag⁺ and Hg²⁺ on the photoinactivation and photodimerization of transforming DNA and of bacteriophage. The rate of inactivation of Haemophilus influenzae transforming DNA by ultraviolet (UV) radiation was enhanced by a factor of 30 when it was complexed with Ag⁺. This enhancement was correlated with a comparable increase in the rate of thymine dimerization. In contrast, mercuric ions led to a reduction in the rates of both inactivation and dimerization. When we examined the effects of these metal ions on the photobiology of bacteriophage, we again found that Ag⁺ enhanced and Hg²⁺ reduced the rate of ultraviolet inactivation. These results demonstrate that heavy metals may be useful tools for studying the photochemistry and photobiology of nucleic acids.     

PHOTOCHEMISTRY OF REDUCED LUMIFLAVIN IN ITS ACIDIC FORM

Abstract— The photooxidation of reduced lumiflavin in its acidic form, LfH 3 ⁺, takes place in two consecutive steps. Upon illumination of LfH 3 ⁺ in its absorption band at 313 nm the semiquinone, LfH 3 ⁺, is formed. Two LfH 2 ⁺ ions are consumed for every LfH 2 ⁺ formed. Illumination of the semiquinone in its absorption band at 495 nm causes further oxidation so that the oxidized LfH⁺ ion is formed. In this reaction one LfH 3 ⁺ ion is photolyzed for every LfH⁺ formed. In addition, a hydrogen atom is released in the photooxidation of LfH 2 ⁺. Mechanisms for the two photoreactions are proposed.     

EFFECT OF METAL IONS ON THE LUMINESCENCE OF ACRIDINE DYES BOUND TO DNA

Abstract— The luminescence of acridine dyes intercalated in DNA was studied as a function of the concurrent binding of metal ions to DNA, in an effort to deduce specific site interactions of the dyes. Two dyes, proflavine (PF) and acridine orange (AO), and two metal ions, silver and mercuric, were used. Both ions quench the fluorescence of the dyes in aqueous solution at room temperature. The metal ions have a different effect on the fluorescence of these dyes when they are intercalated between the base pairs of DNA. The fluorescence of AO is decreased when silver is bound, while the fluorescence of PF is enhanced. Since Ag⁺ initially binds to GC sites in DNA, which quench the PF fluorescence, it ostensibly 'turns off' the quenching by DNA at these sites, and this effect is greater than the quenching effect of the silver ion itself. Hg²⁺ ion initially binds to AT sites in DNA. Since both dyes fluoresce from AT sites, Hg²⁺ is expected to quench their fluorescence. This behavior is observed at low r (metal ion/base). At higher r values, however, where Hg²⁺ is expected to begin binding to GC sites, the fluorescence of PF is enhanced. These quenching turn-off effects are tentatively interpreted in terms of a change in the structure of the dye/DNA complex which occurs when a metal ion binds at the intercalation site. At 77 K. no fluorescence enhancement is observed when metal ions bind; Ag⁺ quenches the fluorescence and enhances the phosphorescence of both dyes. Qualitatively similar results are obtained with Hg²⁺.     

EFFECT OF TEMPERATURE AND pH ON THE QUENCHING OF TRIPLET LUMIFLAVIN IN THE PRESENCE AND ABSENCE OF FERRI- AND FERROCYANIDE

Abstract— –Flash photolysis at 450 nm over the temperature range 0.8–60°C was used to determine Arrhenius parameters for the first and second order disappearance of triplet lumiflavin (1.66 µ .M ) at a flash energy of 2 kj in deaerated phosphate buffer at varying pH:
³Lf → Lf₀
³Lf +³Lf → Lf₀+ Lf₀
Arrhenius parameters were also determined for the pseudo first-order quenching of triplet lumiflavin by 10 µ M ferri- and ferrocyanide ions,
³Lf + Fe³⁺→ Fe³⁺→ Lf₀+ Fe³⁺ (energy transfer)
³Lf + Fe²⁺→ Lf^-+ Fe³⁺ (electron transfer)
and for disappearance of the semireduced lumiflavin in the presence of ferrocyanide at pH 6.8, by the second-order reaction
Lf^-+Lf ^-→ Lf₀+ Lf⁼.     

MIGRATION OF EXCITATION ENERGY FROM THIONINE TO METHYLENE BLUE IN MICELLES

Abstract— The main absorption bands of thionine (Th⁺) and methylene blue (MB⁺) in aqueous solution lie at 598 nm and 664 nm, respectively. This position permits excitation energy transfer from Th⁺ to MB⁺, but not vice versa. We describe here studies of such transfer between these molecules adsorbed on micelles of sodium lauryl sulfate (SLS), imitating, at least to some extent, the state of pigments in chloroplasts.
The SLS concentration was varied from 3.0 to 11 × 10^-3 M. In the presence of dye, aggregation to micelles, each containing 70–100 detergent molecules, begins at about 3.0 × 10^-3 M SLS. Practically all dye ions are adsorbed on these micelles as soon as their formation begins.
Energy transfer from adsorbed Th⁺ ions to adsorbed MB⁺ ions can be demonstrated by observing the quenching of the fluorescence of thionine and the sensitization of that of methylene blue.
At [Th⁺] = [MB⁺] = 1 × 10^-5 M , the most efficient energy transfer (82 per cent efficiency, as derived from measurements of the quenching of Th⁺ fluorescence, or 90 per cent, as derived from sensitization of MB⁺ fluorescence) is observed at the lowest SLS-concentration (3.0 × 10^-3 M ), when the only micelles present are those formed by aggregation of dye-carrying low molecular complexes of SLS with dye cations. Each micelle carries, under these conditions, 10–14 molecules of the two dyes, and the distance between two closest dye ions is about 16 A. Transfer becomes less efficient as the SLS-concentration increases, causing pigment molecules to distribute themselves among a greater number of micelles.     

PHOTOMORPHOGENESIS IN Penicillium isariaeforme: EXOGENOUS CALCIUM SUBSTITUTES FOR LIGHT

Abstract— Penicillium isariaeforme is a photomorphogenic fungus which produces upright bundles of conidia-bearing mycelia (called coremia) when grown on a defined medium in visible (450–500 nm) light. We found that exogenous Ca²⁺ ions could substitute for light. In the dark 1–2 m M Ca²⁺ triggered coremia formation. Dark induction of coremia was specific for Ca²⁺ in that it could not be duplicated by 50 m M Ba²⁺, Fe²⁺, Mg²⁺, Mn²⁺, Sr²⁺, or Zn²⁺. Additionally, light-induced coremia formation was inhibited by both KI (2.5 m M ) and phenylacetic acid (0.25 m M ).     

CHLORIDE ENHANCEMENT OF QUENCHING OF TRIPLET METHYLENE BLUE BY Fe(II)

Abstract— The influence of chloride ion on the rate of decay of triplet methylene blue in 0.01 M acid in the absence and presence of ferrous ions was investigated by means of laser flash-photolysis monitored by kinetic spectrophotometry. Chloride weakly accelerates decay of ³MBH^2± in aqueous solution in the absence of Fe(II). Quenching of ³MBH²⁺ by Fe(II) is more strongly catalyzed by Cl^- in both water and 50 v/v% aq. CH₃CN. The uncatalyzed quenching constant, k ₅, is of the order of 1 × 10⁶ M ^-1 s^-1 while in 4.8 M aqueous chloride ( μ – 7.2 M ) k ₅= (37.2 ± 1.8) × 10⁶ M ^-1 s^-1. A possible role of chloride is as a bridging species in quenching via electron transfer between ³MBH²⁺ and Fe(II).     

THE TRIPLET STATE OF 8-METHOXYPSORALEN

Abstract— Transient absorption spectra produced by laser flash photolysis of an aqueous solution of 8-methoxypsoralen (8-MOP) have been studied. The biphotonic production of hydrated electrons and of the radical ions, 8-MOP ⁺ and 8-MOP^- is reported. The hydrated electron was found to react with ground state 8-MOP with k ˜ 3 × 10¹⁰ M ^-1 s^-1. In order to obtain a true triplet-triplet absorption spectrum. contributions from the radical ions were subtracted from the overall transient absorption. In addition, contributions from e^-_aq to the transient spectrum were removed by using N₂O, low laser intensity to minimize photoionization or by measuring the transient O.D. after the electron has decayed. These three methods each produced the same triplet-triplet spectrum which differs in the red region from previously reported spectra.     

Na+/K+ TRANSPORT AND PHOTOSENSITIVITY OF THE COLORLESS FLAGELLATE Peranema trichophorum (Euglenida)

Abstract— Perimycin, ouabain and elevation of extracellular K⁺ concentrations cause an increase in the fluence rate thresholds (white light) for the step-up photophobic response in Peranema trichophorum . Elevation of extracellular Na⁺ concentration decreases the thresholds for this response in comparison to the control level. The fluence rate threshold of perimycin-treated cells increases before the side effect of an antibiotic action appears. Removal of K⁺ ions from the medium of K⁺-treated cells to a concentration of 1 mM depresses the threshold for the step-up response to the control level. By addition of K⁺ or Na ⁺ ions to perimycin- or ouabain-treated cells the threshold returns to the control value. It is suggested that the flagellar and cell membrane are responsible for changes of P. trichophorum photosensitivity.     

DYE-SENSITIZED PHOTOREDUCTION OF METHYL VIOLOGEN

Abstract— The kinetics of the proflavine-sensitized photoreduction of methyl viologen (MV²⁺) to the blue radical cation (MV^.+) are presented. The triplet excited state of proflavine accepts an electron from EDTA to form the singly-reduced species of proflavine (PH^.); this species donates an electron to either the oxidized (MV^.+) or the singly–reduced (MV^.+) species of the bipyridyl. MV²⁺ can be reoxidized by oxygen to MV²⁺ but is decomposed by H₂O₂. The doubly-reduced form can not be reoxidized either by oxygen or by peroxide. Potassium iodide inhibits the photoreduction of MV²⁺ by competing with it as reactant for the singly-reduced form of proflavine (PH^.). The mechanism presented may be analogous to that occurring in the reduction of MV²⁺ by illuminated spinach chloroplasts; its herbicidal action can not be ascribed to the formation of peroxides.     

EVIDENCE AGAINST THE PRODUCTION OF SUPEROXIDE BY PHOTOIRRADIATION OF HEMATOPORPHYRIN DERIVATIVE

Abstract Experiments were performed to ascertain whether superoxide anion (O₂⁻) was produced by the photodynamic activation of hematoporphyrin derivative (HPD). Three different systems were utilized to detect formation of O₂⁻, oxidation of epinephrine to adrenochrome, reduction of cytochrome c and reduction of nitro blue tetrazolium (NBT). The effects on these detectors under identical conditions for HPD + h ν were compared to those obtained with two O₂⁻ generating systems, riboflavin + by and xanthine-xanthine oxidase, and to a singlet oxygen generating system, photoradiation of methylene blue. The results indicated that HPD + hv differed from the two O₂⁻ generating systems in failing to reduce cytochrome c or NET, and that HPD + h ν was similar to the behavior of methylene blue + h ν . In addition, HPD + h ν but not the O₂⁻ generating systems could inhibit mitochondrial cytochrome c oxidase activity. We conclude that the photodynamic activation of HPD does not produce O₂⁻ as a major oxygen radical and that the effects of HPD + h ν on mitochondrial cytochrome c oxidase are not caused by O₂⁻.     

APPLICATIONS OF CALCIUM-SENSITIVE PHOTOPROTEINS IN EXPERIMENTAL BIOLOGY

Abstract—Calcium-sensitive photoproteins are "precharged bioluminescent proteins that are triggered to emit light by binding Ca²⁺ or certain other inorganic ions. Neither molecular oxygen nor any organic cofactor is required. The first such protein to be described was aequorin, and for various reasons that has been the one most widely studied. Photoproteins have been used as Ca²⁺-indicators both in vitro and in living cells. Their chief advantages for this are (1) ease of signal detection, (2) high sensitivity, (3) relative specificity for Ca²⁺, and (4) lack of toxicity. Difficulties in the experimental use of the photoproteins stem from (1) their one-time reactivity, (2) their large molecular size, (3) their scarcity, (4) the influence of experimental conditions on the sensitivity to Ca²⁺, (5) the nonlinearity of the relation between [Ca²⁺] and light intensity, and (6) the limited speed with which light intensity follows sudden changes in [Ca²⁺]. Photoproteins have now been used as intracellular calcium indicators in more than two dozen types of cells, and experience with the method is rapidly growing. They are also useful in the determination of calcium binding constants for other substances in vitro , and as models for studies of receptor-ligand interactions in general.     

PHOTOCHEMICAL HYDROXYLATION OF 7,8-DIMETHYLALLOXAZINE (LUMICHROME)-A FLASH PHOTOLYSIS STUDY

Abstract— Flash photolysis experiments on the hydroxylation of lumichrome (L) in aqueous 0.5 M H₂SO₄ solution in the presence of O₂ or Ni²⁺ as triplet quenchers and quantum yield measurements confirm the assignment of the photoreactive species to the protonated form of the excited singlet state. A mechamism concerning the photochemical step is proposed, accounting for the formation of protonated 9-hydroxy-5,10-dihydrolumichrome (LOH₃⁺). This primary stable photoproduct was characterized by spectral and kinetic data. The dark reactions originating from LOH₃⁺ were investigated, and data regarding the successive steps are presented. The reaction LOH₃⁺ L→ LO + LH₃⁺ is demonstrated to be a two-electron reduction. The rate constant for the reaction of LH₂⁺ with O₂ is much larger than that for the oxidation of LH₃⁺ by oxygen.     

PHOTOOXIDATION OF LANTHANIDE ION-LYSOZYME COMPLEXES. A NEW APPROACH TO THE EVALUATION OF INTRAMOLECULAR DISTANCES IN PROTEINS

Abstract— Rare-earth metal ions give 1:1 complexes with hen's egg-white lysozyme. Spectroscopic and enzymic activity measurements suggest that the binding site consists of the side chains of glutamic-35 and aspartic-52. The spatial conformation of these complexes is practically identical to that of native lysozyme, especially as concerns the environment of the tryptophyl side chains. Irradiation of La³⁺-lysozyme by visible light, in the presence of proflavine as photosensitizer, causes the oxidative modification of all the tryptophyl and methionyl residues at almost the same rate as in uncomplexed protein. On the other hand, when lanthanide ions with nonvanishing magnetic moments were coordinated with lysozyme, at least some tryptophans and methionines were protected from photooxidative attack. The distance of the protected residues from the coordination site increased with increasing magnetic moment of the bound metal ion, which suggests that inhibition of the photoprocess was mainly due to perturbation of the lifetime of the electronically excited intermediate species. On the basis of the atomic coordinates of lysozyme in the crystal state, it is thus possible to define a "quenching radius" for the various lanthanide ions; these radii could in turn be used to evaluate intramolecular distances in proteins of unknown tertiary structure, by identifying the amino acid residues that are protected or photooxidized upon irradiation of complexes between the given protein and several different lanthanide ions. Our studieson lysozyme allow us to define five radii of protection, ranging from 6·7 Å for Sm³⁺ to over 17 Å for Dy³⁺, Ho³⁺, Er³⁺ and Tb³⁺. Therefore, this technique opens the possibility of mapping appreciably large regions of a protein molecule.     

ELECTRON TRANSFER FROM THE EXCITED STATE OF TYROSINE TO COMPOUNDS CONTAINING DISULFIDE LINKAGES

Abstract— The flash photolysis of aqueous solutions of tyrosine has been studied in the presence of various concentrations of the cyclic disulfide sodium lipoate (thioctic acid, Na⁺ salt). In addition to the formation of phenoxyl radicals and hydrated electrons (and possibly H atoms) from the photoionization of tyrosine, the characteristic spectrum of the radical anion RSSR^- of lipoate was also observed in neutral as well as in alkaline solutions. From the dependence of these yields upon the concentration of lipoate, it was found that a long–lived triplet excited state of tyrosine, rather than the singlet excited state, is involved in these reactions. The negative radical ions RSSR^- are formed by two distinct pathways: (a) Na⁺–lipoate reacts with the solvated electrons which are ejected from the tyrosine triplets ³Tyr → RO.+ e ^-_aq+ H⁺ followed by e ^-_aq+ RSSR → RSSR^-, and (b) by direct interaction of lipoate with triplet excited tyrosine, resulting in the transfer of a negative charge from tyrosine to the disulfide linkage. At high lipoate concentrations, the singlet excited state of lipoate is quenched, k ₄= 1.6 × 10¹⁰ M ^-1 sec^-1, but this reaction does not lead to the formation of RSSR^- radical ions.     

SALT AND pH-DEPENDENT CHANGES OF THE PURPLE MEMBRANE ABSORPTION SPECTRUM

Abstract —Purple membrane suspensions change their color to blue and the absorption maximum shifts to 608 nm when the membrane is deionized on a cation exchange column or when it is washed first with < 2N NaCl followed by deionized water. The deionized chromophore is essentially identical with the chromophore produced by lowering the pH of the native membrane to < 4.0 (p K < 3.0). However, the deionized membrane does not aggregate and can be obtained in the pure state. The original purple color of the membrane is restored by addition of around 1 m M Na⁺, K⁺ or 10 μ M Mg²⁺, Ca²⁺, Sr²⁺, Mn²⁺, Pb²⁺ or La²⁺ when the protein concentration is 5μ M . The required salt concentrations decrease with decreasing pH. Direct measurement of bound Ca²⁺ by atomic absorption spectroscopy yields a ratio of Ca²⁺ to protein of <2 and a binding constant of 1.4 × 10⁶. Titration of the spectral change with salts at different pH values shows a linear relation between the pH and the logarithm of the salt concentration, with a 1:1 ratio for Na⁺ and 1:2 ratio for Ca²⁺. These relations are well predicted by Gouy-Chapman theory; however, the accompanying release of protons, changes of the CD spectrum, the complex kinetics of the spectral change during reconstitution with salt and preliminary X-ray diffraction results all suggest that conformational changes may be occurring in the protein.     

A FLASH PHOTOLYSIS STUDY OF 1-METHYLINDOLE

Abstract— The conventional flash photolysis of 1-methylindole in aqueous media was studied at Λ_excitation≥290 nm. The transients observed 20 μs after excitation consisted mainly of the radical cation (R⁺). the hydrated electron (e^-_aq) and the triplet state (T). Electron counting experiments indicate that photoionization is the only source of R⁺ with e^-_aq/R⁺= 1.07±0.09 in neutral media. Quenching of the R⁺ yield with H⁺ indicates that the fluorescent state is the precursor to 80% of the photoionization events with the remainder probably arising from a prefluorescent state. The triplet decays with a lifetime of 29 μs in deaerated neutral media. This decay is unchanged by N₂O saturation, but T reacts with acrylamide with k ≥2.8 × 10⁹ M ^-1. In 2 M Br^-, R⁺ and T yields are increased by factors of 2–3. Consideration of fluorescence quenching and T enhancement by Br-permits an estimate of φ_Isc between 0.33 and 0.49. The increased R⁺yield at high Br-concentrations cannot be accounted for by induced photoionization or triplet state reactions.     

THE EFFECT OF CHEMICAL STRUCTURE ON THE PHOTOSENSITIZING EFFICIENCIES OF PORPHYRINS

Abstract— A kinetic investigation was performed on the photooxidation of methionine sensitized by various porphyrins at different oxygen concentrations. The rate of photooxidation was found to be strongly dependent on the nature of the sensitizer. In the case of hematoporphyrin, chelation of Mg²⁺ and Zn²⁺ and especially of Cu²⁺ and Fe²⁺ caused a significant decrease of the photosensitizing efficiency. Fluorescence and/or flash photolysis studies showed that such a decrease is ascribed to an enhancement of the non-radiative decay of the first excited singlet state as well as to a reduction of the triplet lifetime. The sensitizing efficiency is also dependent on the nature of the porphyrin side chains. A reaction mechanism involving ¹O₂ as the oxidizing agent is proposed.