Illumination with Ultraviolet or Visible Light Induces Chemical Changes in the Water-soluble Manganese Complex, [Mn4O6(bpea)4]Br4

We measured the photosensitivity of an artificial tetranuclear oxo–Mn(IV) complex, [Mn₄O₆(bpea)₄]Br₄, which has an adamantane-shaped {Mn₄O₆}⁴⁺ core. Illumination caused changes in the absorption spectrum of the compound consistent with a one-electron reduction in the compound. Bromide appears to be the most probable electron donor in the reaction system. Chemical modification of the cluster appears to destabilize it, predisposing it to reductive degradation. UV light was more efficient than visible light in causing the changes. The data support the suggestion that the natural oxygen-evolving Mn complex is photosensitive and can oxidize components of the oxygen-evolving complex in its excited state causing photoinhibition, and that photostability is an important issue in designing Mn complexes for artificial photosynthesis. Furthermore, light-induced oxidation of bromide by [Mn₄O₆(bpea)₄]⁴⁺ may suggest that oxidation of chloride is involved in natural water splitting or has been involved during the evolution of the water-splitting enzyme.     

PORPHYRIN-SENSITIZED PHOTOREACTIONS IN THE PRESENCE OF ASCORBATE: OXIDATION OF CELL MEMBRANE LIPIDS AND HYDROXYL RADICAL TRAPS

Abstract— Photooxidation reactions in ascorbate (AH)-containing erythrocyte membrane suspensions have been studied in broad perspective by simultaneously monitoring lipid peroxidation in the membrane compartment and formation of hydrogen peroxide (H₂O₂) and hydroxyl radical (OH) in the aqueous compartment. Non-bound uroporphyrin (UP) and membrane-bound protoporphyrin (PP) were used as sensitizers. Photoreduction of UP to the radical anion (UP^-) was detected by electron spin resonance when UP/AH/membrane mixtures were irradiated anaerobically. Aerobic irradiation resulted in a strong AH^--stimulation of lipid peroxidation, H₂O₂ formation, and OH^- generation (detected with 2-deoxyribose (DOR) and the spin trap 5,5-dimethyl-l-pyrroline-N-oxide). Use of diagnostic agents (e.g. catalase, desferrioxamine, mannitol) revealed that OH^- is involved in light-stimulated DOR oxidation, but not in lipid peroxidation. Similar irradiation in the presence of PP resulted in far greater lipid peroxidation than observed with UP, but less DOR oxidation, and insignificant accumulation of H₂O₂. This suggests that photoreduction of membrane-bound PP is less efficient, possibly due to hindered access of AH^-.     

ENERGY-REGULATED FUNCTIONAL TRANSITIONS OF CHLOROPLAST ATPASE

The functional transitions of the membrane-bound chloroplast ATPase (CF₁) as influenced by low ADP and uncoupler concentrations are investigated by measurements of initial and steady-state ATP hyrolysis and concomitant membrane energization. Following activation of latent ATP hydrolysis by light in the presence of dithioerythritol, the resulting steady-state ATP hydrolysis depends on the dark-period ( t _d) bteween light activation and ATP addition. ADP, added during t _d, inhibits this activity ( K _i about 2 μ M ) and induces a lag in the onset of ATP hydrolysis. The extent of membrane energization as monitored by an aminoacridine fluorescent probe is proportional to the ATPase activity.
An uncoupler amplifies the inhibitory effect of ADP if added during f _d, whereas it induces the normal stimulation of ATP hydrolysis in the absence of ADP. The ADP effect, which is different from product inhibition, is interpreted as a conformational interaction with CF₁ causing an increase of the energy threshold required for the inactive → active transition of the CF₁ molecules. These results are in harmony with currently proposed models of CF₁ regulation by adenine nucleotides based on binding studies.
The inactive → active transition of CF₁ conformation is investigated by analysis of the lag in the onset of ATP hydrolysis at different ADP concentrations and by means of varied light pulses and single-turnover flashes, using the electric potential indicating absorption change at 515 nm as a probe for the onset of ATP hydrolysis. The half-time of the process leading to fully (re)activated ATP hydrolysis is about 0.25 s. The ATP-dependent flash-induced inactive → active transition occurs within a few turnovers of electron flow.     

DETERMINATION OF PARAMETERS OF EXCITED STATES OF DNA and RNA BASES BY LASER UV PHOTOLYSIS

Abstract— The mechanism of photodecomposition of nucleic acid bases in a neutral aqueous solution upon two-step excitation of high-lying electronic states by a powerful laser UV radiation is discussed. Experimental dependences of photodecomposition efficiency versus UV radiation intensity are measured both under picosecond and nanosecond laser UV irradiations. By comparison of experimental dependences with a theoretical model, we obtain some characteristics of excited states, such as lifetime t₁ of the first electronic excited state S₁ intersystem crossing yield φ, photosensitivity from an intermediate excited state and others for all five nucleic acid bases.     

PROTECTIVE ACTION OF CAROTENOID PIGMENTS AGAINST PHOTODYNAMIC DAMAGE TO LIPOSOMES*

Abstract— When liposomes (a model membrane system) are subjected to a dye-sensitized photo-oxidation, lysis, as measured by glucose leakage or a change in light scattering, results. Before lysis occurs, the membrane lipids undergo peroxidative damage, as determined by the appearance of malondialdehyde. Carotenoids incorporated into the liposomal membrane protect against both lipid peroxidation and liposomal lysis. Other ¹O₂ quenchers and free radical absorbers also protect liposomes from photodynamic damage.     

PHOTOTOXIC EFFECTS OF NATURALLY OCCURRING POLYACETYLENES AND α-TERTHIENYL ON HUMAN ERYTHROCYTES

Hemolysis, K⁺ leakage and acetylcholinesterase (AChE) inhibition in human erythrocytes were observed with certain naturally occurring polyacetylenes and a thiophene derivative, α-terthienyl. K' leakage, subsequent hemolysis and AChE inactivation by phenylheptatriyne (PHT), a phototoxic compound, were considerably enhanced by UV light (312–400 nm). The same was true with α-terthienyl and with certain other polyacetylenes. Oxygen enhanced AChE inactivation and hemolysis with α-terthienyl in light. With PHT, only AChE inhibition was significantly enhanced in oxygen. Falcarindiol, a non-phototoxic polyacetylene, did not inactivate this enzyme but caused hemolysis in the dark. Inhibition of AChE and hemolysis by these compounds appear to be unrelated phenomena. These results indicate that certain polyacetylenes are capable of damaging biological membranes in light, and others in dark.     

PHOTO ACTIVATION OF ISOFLAVONOID PHYTOALEXINS: INVOLVEMENT OF FREE RADICALS

Abstract— Upon irradiation with ultraviolet light the isoflavonoid phytoalexins phaseollin, 3,6a, 9-trihydroxypterocarpan, glyceollin, tuberosin and pisatin, but not medicarpin, brought about inactivation ofglucose–6-phosphate dehydrogenase in an in vitro assay system. Photoinactivation of the enzyme by photoactivated pisatin in air-saturated solutions was hardly affected by singlet oxygen quenchers such as NaN₃, bovine serum albumin, histidine or methionine. Neither addition of the hydroxyl radical scavengers mannitol, Na-benzoate and ethanol nor the presence of catalase or supcroxide dismutase protected the enzyme against photoinactivation, suggesting that OH, H₂O₂ and O₂ are not the reactive oxygen species involved. However, the free radical scavenger S-(2-amino-ethyl)isothiouronium bromide hydrobromide (AET) protected the enzyme against inactivation by photoactivated pisatin. Direct evidence for the generation of free radicals was obtained by ESR measurements of solutions of phaseollin, pisatin and medicarpin in hexane irradiated with ultraviolet light in the presence or absence of O₂. Phaseollin produced the most stable free radicals, whereas medicarpin hardly gave rise to free radical formation; pisatin took a somewhat intermediate position by producing a strong ESR signal which, however, decayed rather quickly. Photodegradation of all phytoalexins, except for medicarpin, was accompanied with loss of fungitoxicity, as shown in thin-layer chromatographic bioassays, and formation of new products.
These results indicate free radical formation as the causative process for photoinactivation of enzymes by photoactivated isoflavonoid phytoalexins.     

PROOXIDANT and ANTIOXIDANT EFFECTS OF ASCORBATE ON PHOTOSENSITIZED PEROXIDATION OF LIPIDS IN ERYTHROCYTE MEMBRANES

Abstract— Continuous blue light irradiation of resealed erythrocyte ghosts at 37°C in the presence of uroporphyrin or protoporphyrin results in ¹O₂-mediated (azide inhibitable) lipid peroxidation and membrane lysis. Lipid peroxidation was assessed by thiobarbituric acid reactivity and by quantitation of total hydroperoxides, while lysis was measured in terms of trappedglucose–6-P release. Low concentrations of ascorbate, AH^- (e.g. 0.5 m M ). present at the start of irradiation, significantly enhanced the rates of lysis and peroxidation, whereas relatively high concentrations of AH^- (e.g. 15 m M ) inhibited both processes. By way of contrast. AH^- produced only a dose-dependent inhibition of the photoinactivation of lysozyme, added as an extramembranous target. No significant AH^-induced lipid peroxidation was observed in dark or light controls, plus porphyrin or minus porphyrin, respectively. Stimulation of peroxidation and lysis by low levels of AH^- was enhanced by added Fe(III), abolished by EDTA. but unaffected by catalase or superoxide dismutase. A plausible explanation for these results is as follows. At low concentrations of AH^- prooxidant activity is favored. Redox metal-mediated breakdown of photoperoxides occurs, which tends to amplify lipid peroxidation. Neither O₂^- nor H₂O₂ appears to be involved. At significantly high concentrations, AH^- acts predominantly as an antioxidant by intercepting ¹O₂ and/or sensitizer triplet, or by scavenging free radical intermediates of lipid peroxidation.     

Melanocyte-stimulating Properties of Secretory Phospholipase A2

Abstract— Phospholipase A₂ (PLA₂) catalyzes the release of free fatty acids from membrane phospholipids, and its products derived from these fatty acids, such as prostaglandins and leukotrienes, significantly up-regulate the key mela-nogenic enzyme, tyrosinase, in melanocytes. This has led to suggestions that PLA₂ itself triggers melanin synthesis in melanogenesis following UV irradiation or inflammation.
We have examined the effect of secretory PLA₂ (sPLA₂) on melanogenesis in cultured human melanocytes. Secretory PLA₂ stimulated DNA synthesis and melanin synthesis, and these phenomena were completely inhibited by treatment with a phospholipase inhibitor, p- bromophenacyl bromide, demonstrating that the catalytic activity of sPLA₂ is required for melanogenesis. Secretory PLA₂ also stimulated tyrosinase activity, increased the amount of tyrosinase-related protein-1 and up-regulated the expression of both mRNA. These findings suggest that sPLA₂ is an important mediator of UV-induced or postinflammatory pigmentation.     

PHOTODYNAMIC EFFECTS OF NEW SILICON PHTHALOCYANINES: In vitro STUDIES UTILIZING RAT HEPATIC MICROSOMES AND HUMAN ERYTHROCYTE GHOSTS AS MODEL MEMBRANE SOURCES

Abstract— Photodynamic therapy (PDT) of cancer is a modality that relies upon the irradiation of tumors with visible light following selective uptake of a photosensitizer by the tumor tissue. There is considerable emphasis to define new photosensitizers suitable for PDT of cancer. In this study we evaluated six phthalocyanines (Pc) for their photodynamic effects utilizing rat hepatic microsomes and human erythrocyte ghosts as model membrane sources. Of the newly synthesized Pc, two showed significant destruction of cytochrome P-450 and monooxygenase activities, and enhancement of lipid peroxidation, when added to microsomal suspension followed by irradiation with ∼ 675 nm light. These two Pc named SiPc IV (HOSiPcOSi[CH₃]₂[CH₂]₃N[CH₃]₂) and SiPc V (HOSiPcOSi[CH₃]₂[CH₂]₃N[CH₃]₃¹ I) showed dose-dependent photodestruction of cytochrome P-450 and monooxygenase activities in liver microsomes, and photoenhancement of lipid peroxidation, lipid hydroperoxide formation and lipid fluorescence in rnicrosomes and erythrocyte ghosts. Compared to chloroaluminum phthalocyanine tetrasulfonate, SiPc IV and SiPc V produced far more pronounced photodynamic effects. Sodium azide, histidine, and 2,5-dimethylfuran, the quenchers of singlet oxygen, afforded highly significant protection against SiPc IV- and SiPc V-mediated photodynamic effects. However, to a lesser extent, the quenchers of superoxide anion, hydrogen peroxide and hydroxyl radical also showed some protective effects. These results suggest that SiPc IV and SiPc V may be promising photosensitizers for the PDT of cancer.     

INTERPRETATION OF THE 'DICHROIC ORIENTATION' OF PHYTOCHROME

The dichroic orientation of phytochrome observed both in the phytochrome-mediated phototropism in Adiantum protonemata and in the phytochrome-mediated chloroplast movement in Mougeotia were analyzed in terms of the orientation of the transition moment associated with the long-wavelength absorption band, assuming that phytochrome, associated with the plasma membrane, rotates around the normal to the membrane. The orientation of the long-wavelength transition moment of the phytochrome chromophore was calculated using the zero-differential overlap approximation of the molecular orbital theory for ir-electrons. The results indicate that the orientation of the long-wavelength transition moment mainly changes later than 2 ms after red light excitation of P_r, and that the different dichroic orientations of P_r and P_fr can be attributed to the change in the angle of the long-wavelength transition moment of phytochrome with the plasma membrane from 18^o to 72^o during phototransformation.     

SPECTRAL PROPERTIES OF THE RHODOPSIN-SYSTEM OF THE CRAYFISH Astacus leptodactylus

Abstract— The absorption spectra of the membrane-bound and of the digitonin-solubilized visual pigment of crayfish Astacus leptodactylus were investigated by conventional spectrophotometry. A method was developed to isolate purified rhabdoms almost entirely free from screening pigments from a single retina. The quantity of isolated and purified rhabdoms from a single retina was sufficient to measure the absorption spectra of the visual pigment.
The absorption spectra of the chromoprotein system (R and M) show that both the membrane-bound and the digitonin-solubilized visual pigment isomers are stable at 0°C and pH 7.0. Rhodopsin and metarhodopsin are photoreversible under these conditions without any light-induced denaturation. The difference spectra for the chromoprotein isomers and those of different photostationary states yield maximal values for ΔE at 570 and 485 nm.
At neutral pH, 0°C, Λ_max of rhodopsin is 530 nm. Irradiation with light of Λ= 630 to 640 nm isomerizes rhodopsin nearly quantitatively to metarhodopsin with Λ_max, of 500 nm. The molar extinction coefficient of metarhodopsin is greater than that of rhodopsin by a factor of ˜ 1.41. each measured at its respective Λ_max Metarhodopsin can be isomerized to rhodopsin by irradiating at Λ > 630 nm. As the absorption spectra of the two chromoprotein isomers overlap, only part of the metarhodopsin can be reversed to rhodopsin. The maximal photoreversion can be achieved by irradiating at 460 nm. The stability of the digitonin-solubilized chromoprotein is remarkably dependent on temperature. Warming the digitonin extract of rhabdoms from 0 to 20 or 30°C caused a shift of the rhodopsin spectrum to shorter wavelengths (Λ_max= 485 nm) accompanied by a decrease of E_Λmax by about 30%.     

THE STRUCTURAL CHANGES IN BOVINE ROD OUTER SEGMENTS IN THE PRESENCE OF ATP

Abstract— We have, previously, described a light-induced near infrared (700–850 nm) light scattering transient obtained in the presence of ATP from bovine rod outer segments suspensions in which the plasma but not the disk membranes were perforated (Uhl et al ., 1979a). This transient was termed the 'A' signal. To elucidate its possible origin, we have analyzed their angular and wavelength dependencies. These data have been compared with osmotically controlled (non-light) induced light scattering changes from identical control rod outer segments suspensions. It has been found that A_D (the dark light scattering signal obtained in the presence of ATP) and A_LS (the slow component of the actinic flash induced light scattering signal, A_L) can be assigned to the swelling of the disk membranes while A_Lf (the fast component of this latter signal) can be attributed to the change in refractive index of the ROS caused by the hypsochromic spectral shift of photolyzed rhodopsin. The collective disk swelling associated with A, and A_LS is consistent with the pumping of ions into the disk lumen by the action of a disk membrane bound ATPase.     

THE SUSCEPTIBILITY OF MUNG BEAN CHLOROPLASTS TO PHOTOINHIBITION IS INCREASED BY AN EXCESS SUPPLY OF IRON TO PLANTS: A PHOTOBIOLOGICAL ASPECT OF IRON TOXICITY IN PLANT LEAVES

In an attempt to elucidate the underlying mechanisms for iron toxicity in plants, the combined effects of iron overload and light intensities on the photosynthetic capacity of leaves were particularly focussed upon in this study, using mung bean seedlings grown under varied conditions regarding the supply of light and iron. The seedlings, when supplied with excess iron (up to 1.0 m M ) and low light (40 W/m²), did not suffer any loss of photosynthesis; further, the typical symptoms of iron toxicity, as shown in the leaves grown in sunlight at ca 450 W/m² on an average, were not seen in those. Nonetheless, excess iron supply resulted in a marked increase in photosensitivity of the low light-adapted seedlings. A large portion of iron accumulated in chloroplasts by the supply of excess iron was found to be incorporated into thylakoids as nonheme iron (NHI), which acts as a potent sensitizer, photogenerating singlet oxygen (¹O₂). The generation rate of ¹O₂ from thylakoids linearly increased with increasing content of NHI; this was in parallel with the NHI content dependence of photoinactivation rates of photosynthetic electron transport and key enzymes of the Calvin cycle in chloroplasts. The results suggest that Fe-dependent photosensitization reactions, occurring via the ¹O₂ mechanism, may be deeply involved in cellular processes leading to developing iron toxicity symptoms in plants.     

PHOTO-OXIDATION EFFECTS ON β-HYDROXYBUTYRATE DEHYDROGENASE: STUDIES OF MEMBRANE FRAGMENTS AND INTACT MITOCHONDRIA

The influence of singlet oxygen (¹O₂), generated by red light irradiation of oxygenated suspensions containing aluminium phthalocyanine sulphonate, on the membrane bound enzyme β-hydroxybutyrate dehydrogenase was investigated. The inactivation rates were measured using a spectrophotometry assay which involves disruption of the mitochondria. A novel NMR assay was also used to measure the activity of the enzyme in intact mitochondria. Relatively high inactivation rates of around 10⁹ M ⁻¹ s⁻¹ were observed in H₂O buffer, and rates in D₂O were a factor of 1.7 faster. Significant differences in enzyme inactivation rates by ¹O₂ were observed, not only between disrupted and intact mitochondria but also between the NMR assay results and the spectrophotometric assay results. The results indicate the value of a specific assay which does not require the disruption of the biological system.     

BLUE LIGHT INDUCED, REVERSIBLE IN ACTIVATION OF THE TONOPLAST-TYPE H+-ATPase FROM CORN COLEOPTILES IN THE PRESENCE OF FLAVINS

Abstract— Irradiation (λ_max 447 nm; 58.5 W m^-2) of a microsomal membrane fraction of corn coleoptiles for 5 min in the presence of the in vivo concentration of riboflavin inactivates the tonoplast-type H⁺-ATPase. This inhibition is O₂-dependent, is enhanced in D₂O and suppressed by NaN₃, indicating participation of singlet molecular oxygen in the inactivating mechanism. Besides singlet oxygen, the superoxide anion (O₂^-) is generated during irradiation, which obviously has no effect on the H⁺-pumping activity. However, in the presence of superoxide dismutase (SOD), O₂^- is transformed into H₂O₂ which causes an additional strong inhibition of H⁺. ATPase activity. This inhibition can be increased by ethylenediaminetetraacetic acid (EDTA), which is known to be an electron donor of the excited flavin molecule. In contrast, catalase prevents the H₂O₂-mediated photoinactivation of the H⁺ -ATPase. The light dependent inactivation of H⁺-transport does not occur if reduced glutathion (GSH) is added prior to or after irradiation. These results indicate that the blue light mediated inhibition of the H⁺-ATPase is mediated by singlet oxygen and H₂O₂ which oxidize essential SH-groups of the enzyme into disulfides. Reduction of the formed disulfides by GSH restores the activity of the enzyme.     

PHOTORESPONSES OF SEMICONDUCTOR POLYCRYSTALLITES SEPARATING TWO AQUEOUS SOLUTIONS

Solar cells using polycarbonate membranes, with CdS deposited on them, were made by a very simple way; the CdS-containing membrane separates a Lucite cell into two compartments. On illumination, about 150 mV photovoltage ( V _op) and 0.5 μA cm^-2 photocurrent ( I _sc) could be produced; one side of the membrane acted as photoanode, and the other side as photocathode. By means of coating Victoria Blue B (VBB) onto the membrane before CdS deposition, the maximum V _op and I _sc of the CdS-deposited membrane could reach 500 mV and 3.0 (μA cm^-2, respectively. A mixture of CdS and CdSe deposited membrane has also been tested and found to have both the advantages of high photovoltage (over 400 mV) and good stability after modification. Even more interesting results were also obtained with CdSe pellets in place of the CdS-deposited membrane, in which V _op and I _sc of the cell were 1.2 V and 6 mA cm^-2, respectively. The essential aspect of the system, modelled after the photosynthetic thylakoid membrane, contains an asymmetrical, ultrathin semiconductor crystallite layer separating two aqueous solutions.     

PHOTOREACTIVATION OF THYMINE-STARVED ESCHERICHIA COLIBs-1

Abstract —Thymine starvation prior to 254 nm ultraviolet light (UV) exposures has been found to decrease the level of maximum photoreactivation in Escherichia coli B _s-1. The dark equilibrium level of photoreactivating enzyme-substrate complexes was determined from the levels of photoreactivation obtained with exposures to single flashes of high-intensity light. The kinetics indicate that photoreactivating enzyme concentration does not decrease as a result of thymine starvation. The UV sensitivities of normal and thymine-starved cells are found to be the same. Photoreactivation by sequential flashes shows a lesser number of total photorepairable lesions in starved cells. It is concluded that thymine starvation renders a portion of the dimers inaccessible to the photoreactivating enzyme, thus lowering the level of maximum photoreactivation.     

LOSS OF PHOTOREACTIVATION IN UV-IRRADIATED CULTURED FISH CELLS UNDER DIFFERENT CONDITIONS

Abstract— CAF-MM1 cells derived from a goldfish have photoreactivability for the damage induced by ultraviolet light (UV). When UV-irradiated cells were incubated in the dark at 26_AoC, the longest interval in which photoreactivation (PR) was observed (i.e. effective time for PR), measured by colony formation technique, was about 30 h after the UV irradiation. However, if the cells were incubated at 20_AoC, the effective time was prolonged. Since each time appeared to correspond to the doubling time of the cells at each temperature, the loss of photoreactivability is suggested to be closely related to cell growth or progression of cell cycle. The loss of PR was not observed in the cells held in confluence up to 48 h after UV irradiation, in support of the above suggestion. Photoreactivating enzyme in growing CAF-MM1 cells incubated in the dark for 24 h after UV irradiation was shown to be active, so that it is not possible that the cause of the loss of PR is change in the activity of photoreactivating enzyme.