P588, A SECOND RETINAL-CONTAINING PIGMENT IN HALOBACTERIUM HALOBIUM

Abstract— Halobacterium mutant strains with defects in the biosynthesis of various pigments have been isolated. One of these strains, mutant ET-15, is incapable of producing the light-driven proton pump bacteriorhodopsin and the carotenoid bacterioruberin. However, ET-15 synthesizes another photochemically active, retinal-containing pigment, P₅₈₈, which mediates light-induced proton uptake enhanced by uncouplers. P₅₈₈ and bacteriorhodopsin are simultaneously present in wild-type cells grown under normal conditions; however, they can be distinguished by the following criteria.

• 1 They can be separated by independent mutational events.
• 2 Proton ionophores such as FCCP diminish bacteriorhodopsin-driven proton translocation but enhance P₅₈₈-mediated proton flows. We define here proton translocations which can be diminished by the addition of uncouplers (e.g. FCCP) as ‘active’, others which can be enhanced by FCCP as ‘passive’.
• 3 The kinetic and spectral properties of the photocycle intermediates of bacteriorhodopsin and P₅₈₈ are different.
• 4 The action spectrum for photocycling of P₅₈₈ is red-shifted with respect to that for bacteriorhodopsin.

A comparison of action spectra for proton translocations with that for photocycling links pigment P₅₈₈ and light-driven, passive proton uptake by ET-15 envelope vesicles. When chemically bleached P₅₈₈ was regenerated with all-trans-retinal, both photochemical activity and light-induced proton inflow were restored to equal extents. This identifies P₅₈₈ with the energizer for the passive proton flows.     

PICOSECOND FLUORESCENCE STUDIES OF P700-ENRICHED PARTICLES OF SPINACH CHLOROPLASTS

Dynamic properties of the picosecond fluorescence of highly enriched reaction-center particles of photosystem I (8 - 10 chlorophylls/P700) prepared from spinach have been investigated. The number (N) of photons used to excite chlorophyll molecules per reaction center was controlled between 0.06 and 80. The 1/e lifetime was ca. 25 ps for N 1. which is much shorter than previously measured lifetimes of photosystem I particles. The initial fluorescence intensity saturated at higher excitation intensities (N ≲ 1). This was interpreted in terms of interaction and annihilation among excited chlorophyll molecules which occur almost entirely within the duration of a laser flash. The spectrum-resolved fluorescence decay was faster at 690 than at 680 nm. This implies that two kinds of antenna chlorophylls, apart from and in close proximity to P700, have different lifetimes. Upon heat treatment a component with a much longer fluorescence decay time was observed. The growth of this component upon heat treatment at increasing temperatures showed a correlation with a decrease in the amount of P700 that could be photooxidized.     

INTERMEDIATES IN THE PHOTOCONVERSION OF FUNCTIONAL PHYTOCHROME IN FERN SPORES OF Dryopteris–II. In vivo KINETICS OF THE DECAY OF Ii700 AND OF THE FORMATION OF Pfr STUDIED WITH A DOUBLE-LASER APPARATUS*

Abstract— Photoconversion of the red-light-absorbing form of phytochrome, P_r, to the far-red-light-absorbing form, P_fr, was investigated in vivo at 22°C with 600 or 800 ns laser pulses of high spectral purity and induction of spore germination in Dryopteris paleacea was used as indicator for the progress of photoconversion. This reaction is initiated by a saturating R-laser pulse of 648.5 nm, establishing an equilibrium of the photochromic system between P_r and the very early intermediates, Iⁱ₇₀₀ (P_rφ Iⁱ₇₀₀)- The decay of Iⁱ₇₀₀ as well as the formation of P_fr was recorded by the application of a second pulse varied between 698 and 717.5 nm, which inhibits the formation of P_lr being absorbed predominantly by Iⁱ₇₀₀or P_fr, respectively. The most effective inhibition for the second pulse is found up to 10 u.s after the first pulse and this is interpreted by photoreversion of Iⁱ₇₀₀ to P_r; thus reducing the formation of P_fr from Iⁱ₇₀₀. This early inhibition decreases between 10 μs to 100 ms after the R-laser pulse, as a result of the decay of Iⁱ_bl to a bleached species I,;. This decay can be described by three first order kinetics with the rate constants k₁₂= 16830 ± 2970 s^-1, k₁₂= 666 ± 218 s^-1,k₁₃= 9.8 ± 0.9 s^-1. A second inhibition, due to the formation of P_fr, is found for dark intervals <100 ms and can be described by two first order kinetics with the rate constants k₂₁= 2.9 ± 0.6 s^-1 and k₂₂= 0.17 s^-l.     

A PHYTOCHROME STUDY USING TWO-LASER/TWO-COLOR FLASH PHOTOLYSIS: I700 IS A MANDATORY INTERMEDIATE IN THE PrPfr PHOTOTRANSFORMATION

Abstract— The phototransformation of native (124 kDa)oat phytochrome, P_r P_fr, Has been studied at 10C by two laser/ two-color flash photolysis. the overall P_rP_fr reaction yield did not vary with temperature within the range4–21C. Foloeing the excitation of P_r with a single 15 ns laser flash at 650nm, the formation of P_fr was quantitavely measured in a time-resolved experiment in the presence of a second 8 ns laser flash at 710 nm delayed from the initial flash. the second laser flash causes at 1.0 s after the initial laser flash a depletion of the uintermediate I₇₀₀ as welll as a reduction of the P_fr absorption at 730 nm. The depletion of I₇₀₀ correlates quantitavely with the reduction of P_fr formation. The absorpton spectra of I₇₀₀ and of the following intermendiate, I_bi, were calculated assuming that the amount of P_r, which is photoconverted by a single laser, equals the amount of P_fr formed.     

124-kDa PHYTOCHROME IN MODEL MEMBRANE SYSTEMS: STUDIES OF THE Ii700 INTERMEDIATES WITH THE PROTEIN COVALENTLY BOUND TO PREFORMED LIPOSOMES

Abstract— We have described the covalent binding of 124-kDa oat phytochrome to large unilamellar liposomes composed of either dioleoyl phosphatidylcholine or dipalmkoyl phosphatidylcholine or soybean lecithin, without affecting the photochromic properties of the protein. These phytochrome-liposome systems have now been studied by laser flash photolysis. The liposomes, independent of their membrane rigidity (liquid-crystal vs gel-like phase), do not influence the ratio and reactivity of the two primary photoproducts, Iⁱ₇₀₀- of the red absorbing form of phytochrome, P_l Thus, the lifetimes of the Iⁱ₇₀₀ intermediates and the activation parameters associated with Iⁱ₇₀₀Iⁱ_bl are the same as those measured for nonbound phytochrome in buffer solution. The temperature increase from about 273 K. to 297 K lowers the population of the shorter-lived Iⁱ₇₀₀ intermediate to the same extent both in the liposome-P_l and in nonbound P_l, whereas it does not affect the relative population of the Iⁱ₇₀₀ intermediates from non-bound P_l in the presence of 25% ethylene glycol added to the buffer solution (ionic strength 0.17).     

ELIMINATION OF THE EFFECT OF CONTAMINATING CO2 IN THE 18O-LABELING OF THE CO2 PRODUCED IN BIOLUMINESCENT REACTIONS

Abstract— Although the mechanism of bioluminescent reactions in various species, such as fireflies, ostracod crustaceans ( Cypridina ), sea pansies ( Renilla ), and the deep-sea shrimp Oplophorus , are thought to involve dioxetanone intermediates, studies reported in the past from different laboratories have included widely different experimental results, most likely due to various factors including the effects of contaminating CO₂. With the improved technique employed in the present study, bioluminescent reactions of the firefly and Cypridina in ¹⁸O₂ gas resulted in an incorporation of over 75% of ¹⁸O into one oxygen of the product CO₂. with a reproducibility within a few per cent. When ¹³CO₂. instead of the product CO₂ of the bioluminescent reaction, was studied in an H₂¹⁸O medium, the exchange of one oxygen of ¹³CO₂ with H₂O was 64%. and the effect of contaminant CO₂ amounted to 1418% of the total CO₂. These results suggest that every molecule of CO₂ formed in the bioluminescent reactions of the firefly and Cypridina had intially contained 1 oxygen atom derived from O₂.     

A REVERSIBLE PHOTOCHEMICAL REACTION OF CHLOROPHYLL a WITH I2

Abstract— Chlorophyll a and I₂ form a 1:1 addition compound, which exhibits a strong absorption maximum at about 360 nm. When dissolved in anaerobic methanol, this compound can be reversibly bleached by illumination with red light. Prolonged illumination at low temperatures (˜– 75°C) or intense illumination at room temperature reduces the height of the red absorp tion maximum to about half of its normal value. Since the thermal back reaction is negligibly slow at – 75°C, presumably the chlorophyll-I₂ complex is converted completely to its bleached form, when illuminated under those conditions. This assumption leads to a simple mechanism which is consistent with the experimental data.     

EPR STUDIES OF TRAPPED SINGLET OXYGEN (lO2) GENERATED DURING PHOTOIRRADIATION OF HYPOCRELLIN A

Hypocrellin A, a peryloquinone derivative, has recently been isolated from the sacs of the fungus Hypocrella bambusae. This pigment, in combination with phototherapy, has been used in human medicine to cure various skin diseases. The generation of singlet oxygen during photoirradiation of Hypocrellin A (HA) was detected as an oxidation product of a sterically hindered amine (tetramethylpiperidine oxide; TEMPO) by electron paramagnetic resonance (EPR) spectroscopic techniques. Azide inhibited the EPR signal intensity in a dose-dependent manner with a quenching rate constant of 3.86 x 10(8) M-1s-1 in ethanol. Deuterated solvents, known to increase the lifetime of singlet oxygen, augmented the EPR signal intensity. The rate of production of singlet oxygen was dependent not only upon the concentration of HA and the time of irradiation but also on the oxygen content of the reaction mixture. The hyperfine splitting constant (aN = 16.3 G) and g-value (g = 2.0056) of the photoproduct of TEMP-singlet oxygen and TEMPO were found to be identical. This indicates that the nitroxide species detected by EPR spectroscopy generated by reacting TEMP with photogenerated 1O2 is TEMPO. The rate constant (kT) for the reaction of singlet oxygen with TEMP to form TEMPO radical was found to be 5.3 x 10(5) M-1s-1.     

CORRELATION BETWEEN DELAYED LIGHT EMISSION AND FLUORESCENCE OF CHLOROPHYLL a IN SYSTEM II PARTICLES DERIVED FROM SPINACH CHLOROPLASTS

Abstract— The induction transient of delayed light of chlorophyll a, excited by repetitive flashes (0.5 ms in duration) and emitted 0.1 - 1.2 ms after the flashes, was measured in system II particles derived from spinach chloroplasts. An uncoupler, gramicidin S, was always added to the particles in order to eliminate the influence of the phosphorylation system on the delayed light and to isolate a direct relationship between the delayed light emission and the primary photochemical reaction, except for the experiments described in the next paragraph. The yield of delayed light emission from the system II particles was found to be about three–times higher than that of chloroplasts on a chlorophyll content basis. System I particles, on the other hand, emitted much weaker delayed light than chloroplasts. Upon intermittent illumination, induction of delayed light in system II particles showed a decrease from the initial rise level to the steady-state level. The initial rise level was the maximum. The fluorescence induction, on the other hand, exhibited an increase from the initial rise level to the maximum steady-state level. The induction of both delayed light emission and fluorescence arrived at their final steady-state levels after the same period of illumination. Induction of delayed light emission was measured under various conditions that changed the oxidation-reduction state of the primary electron acceptor, X, of photoreaction II: by adding an electron acceptor and an inhibitor of electron transport, and by changing the light intensity. The state of A'was monitored by measuring the fluorescence yield. The yield of delayed light emission excited by each flash was found to depend on the amount of oxidized form of X present before the flash. To examine the role of the primary electron donor Y of photoreaction II in delayed light emission, effects of electron donors of photoreaction II such as Mn²⁺, hydroquinone and p-phenylenediamine were investigated. These agents were found to markedly decrease the yield of delayed light emission without altering the pattern of its induction. They had little effect on the induction of fluorescence. These findings are interpreted by a mechanism in which transformation of the reaction center from the form (X^-Y⁺) into (X Y) produces a singlet excitation of chlorophyll a that is the source of millisecond delayed light emission. This reaction is probably non–physiological and must be very slow if compared to the transformation of (X^-Y⁺) into (X^-Y). Since the form (X^-Y⁺) is produced when the excitation is transferred to the reaction center in the form (XY), it is expected in this scheme that the yield of delayed light emission should depend on the amount of the form (X Y) present before the excitation flashes. Electron donors stimulate transformation of the reaction center from (X^-Y⁺) into (X^-Y). Since this reaction competes with the process of delayed light emission, electron donors are expected to suppress delayed light emission.     

PHOTOINACTIVATION OF A Chlamydomonas MUTANT(NL–11) IN THE PRESENCE OF METHIONINE: ROLES OF H2O2 and O-2

Abstract— A mutant of Chlamydomonas reinhardtii (NL–11) isolated from a wild type (137c+) was inactivated in the light in the presence of methionine at concentrations where the wild type was not inactivated. The inactivation was suppressed by either catalase or superoxide dismutase (SOD). Light-induced H₂O₂ formation and nitroblue tetrazolium (NBT) reduction inNL–11 were greater than those in the wild type. Methionine stimulated both the H₂O₂ formation and the NBT reduction inNL–11 as well as the wild type. The light-induced NBT reduction inNL–11 in the presence of methionine was partially suppressed by externally added SOD suggesting the participation of O^-₂. These results suggest that the hypersensitivity ofNL–11 to methionine in the light is due to stimulated formation of H₂O₂ and O^-₂.     

OXIDATION-REDUCTION REACTIONS OF P700 AND CYTOCHROME f IN FRACTION 1 PARTICLES PREPARED FROM SPINACH CHLOROPLASTS BY FRENCH PRESS TREATMENT

Abstract— –Fraction-1 particles were prepared by passing spinach chloroplasts three times through the French pressure cell and centrifuging in a sucrose gradient. With the electron donor DAD (diaminodurol or 2,3,5,6-tetramethyl-p-phenylenediamine) and ascorbate, a light-induced difference spectrum revealed the oxidation of both cytochrome f and P700 upon illumination of these particles. The oxidation of cytochrome f was completed in less than 0.5 msec. P700 and cytochrome f thus seem to be tightly bound to each other in these particles. Addition of Triton X-100 abolished the fast oxidation of cytochrome f but not that of P700. Artificial electron donors such as DAD, DCIP (2,6-dichlorophenol indophenol), and PMS (N-methylphenazonium methosulfate) were good electron donors for photoreaction 1 in these particles, while neither plastocyanin, Porphyra cytochrome 553, nor Euglena cytochrome-552 reduced P700 efficiently. However, after treatment of fraction 1 particles with Triton X-100 reduced DAD, DCIP and PMS were no longer efficient electron donors, while plastocyanin and the algal cytochromes were highly active in reducing P700. Mammalian cytochrome c was not a good electron donor either before or after Triton treatment. Measurements of the effectiveness of P700 reduction as a function of concentration in Triton-treated particles showed plastocyanin to be about four times more active than Porphyra or Euglena cytochromes which in turn were about fourteen times more active than mammalian cytochrome c. Recent studies by Murata and Brown have shown that plastocyanin is not required for the reduction of NADP in these particles with DCIP and isoascorbate as electron donors. The present investigation and that of Murata and Brown indicate that disintegration of chloroplasts with the French pressure cell and centrifugation in a sucrose gradient is the best method to separate system-1 particles having an electron-transport system in almost the native state as in chloroplasts.     

RATE CONSTANTS FOR INTERACTION OF 1O21Δg) WITH AZIDE ION IN WATER

Abstract— The rate constant for quenching of ¹O₂ by azide ion in water was determined to be (5.0 ± 0.4) × 10⁸ M ⁻¹ s⁻¹ using a variety of sensitizers (including humic acids) and ¹O₂ acceptors. The apparent second-order rate constant decreases with pH below pH 5.5 in accordance with the protonation of azide ion to form hydrazoic acid (p K _a= 4.6). Quenching by hydrazoic acid is at least 2 orders of magnitude slower than by azide ion. Greater than 99% of all interactions between ¹O₂ and azide ion involve physical quenching rather than chemical reaction. Humic acid triplets are not significantly quenched by azide ion at concentrations less than 2 m M , allowing azide ion quenching to be used as a diagnostic test for the intermediacy of ¹O₂ in photosensitized oxidations in natural surface waters.     

SEARCH FOR SINGLET OXYGEN LUMINESCENCE IN THE DISPROPORTIONATION OF HO2/O2

Abstract— During the reaction HO₂+ HO₂ (or O₂^-) = H₂O₂+ O₂ in aqueous solution, no luminescence in the region 620–720 nm, expected if the product O₂ were formed in a singlet state, could be detected. If any singlet O₂ is formed, its yield must be less than 10%. Faint luminescence, sometimes found at shorter wavelengths, was shown to arise from reaction of HO₂ with impurities in the reagents present.     

PHOTOOXYGENATION OF 3-HYDROXYFLAVONE IN A 12 K O2 MATRIX

Abstract— We present an infrared study of 3-hydroxyflavone in 12 K Ar and O₂ matrices. Although it is extremely photostable in an Ar matrix, a remarkable oxygenation reaction for 3-hydroxyflavone takes place upon photoexcitation in an O₂ matrix. The primary photoproduct is concluded to be a keto-hydroperoxide. On further photolysis the keto-hydroperoxide affords the photostable secondary product 2-(benzoyloxyl)benzoic acid, as well as CO and CO₂ through two independent pathways.     

PHOTOLYSIS OF SUBSTITUTED NAPHTHALENES ON SiO2 AND Al2O3

Abstract— Photolysis of naphthalene on the surface of SiO₂ under an atmosphere of air produces phthalic acid as the only major photoproduct, accounting for 49%o of the consumed naphthalene. Photolysis on Al₂O₃ also produces phthalic acid, in 31% yield. Photolysis of 1 -methylnaphthalene on SiO₂ proceeds under similar conditions to produce 2-acetylbenzoic acid (35%) as the major photoproduct with the production of a small amount of I-naphthaldchyde (6%). 1-Cyanonaphthalene does not photooxidize under similar conditions. The presence of oxygen is necessary for the photodecomposition of naphthalene and 1-methylnaphthalene to proceed. Superoxide formed from the photolysis of naphthalene at the SiO₂/air interface is readily observed by electron paramagnetic resonance spectroscopy. In the absence of naphthalene no superoxide is observed. A mechanism involving electron transfer from the S₁ state of the naphthalene to O₂ is proposed on the basis of these observations and related literature precedent.     

CO2超临界干燥制备超细TiO2粉体的研究

采用溶胶-凝胶法结合CO2超临界流体干燥技术制备了平均粒径为8nmTiO2粉体颗粒,并采用BET、TEM、SEM、XRD、及DTA-TG技术对制得的粉体进行了表征.结果显示出CO2超临界干燥技术在制备大孔高比表面TiO2纳米粉体时具有较大的优越性.     

ADDITION OF OXYGEN AS A DIAGNOSTIC TEST IN MERCURY 6 (3P1) PHOTOSENSITIZATION

Abstract— Mercury in contact with oxygen is rapidly removed from the gas phase when irradiated with the 253.7 run resonance line. The final, steady-state concentration of mercury depends on the total pressure, the mol % of oxygen, and the presence (or absence) of mercury droplets in the reaction cell. The effect of oxygen on the mercury photosensitized formation of allene from methylenecyclobutane and trans -2-butene from cis -2-butene at room temperature was investigated. After correction for competitive quenching, collisional deactivation of the excited methylenecyclobutane, and decreased absorption (due to mercury depletion), the maximum decrease in the allene yield was only 12.3%. This decrease could be caused by the reaction of oxygen atoms or ozone with the product allene. In most of the experiments with mercury-oxygen- cis -2-butene mixtures, the corrected quantum yield of the trans -isomer is unchanged from the yield in the absence of oxygen (0.50). Thus oxygen cannot be used to detect the participation of triplet state molecules in mercury photosensitized reactions.     

RAPID REDUCTION OF P-700 PHOTOOXIDIZED BY A FLASH AT LOW TEMPERATURE IN SPINACH CHLOROPLASTS

Abstract—Excitation of chloroplasts at low temperature (down to 4.2 K) by short laser flashes causes largely reversible absorption changes which are attributed to the photooxidation of P-700, the primary electron donor of Photosystem I. At temperatures below 100 K the dark re-reduction of P-700⁺ is biphasic. with half-times of about 122μs and 1.7 ms. The relative contribution of the two phases varies with temperature with the fast phase becoming dominant at the lowest temperatures (˜90% at 5 K). The results are interpreted in terms of tunnelling of the electron from one or two primary accepting sites back to P-700, a process which is largely dominant over the process of charge stabilisation.