Intermittent illumination increases biophotolytic hydrogen yield by Anabaena cylindrica.

Intermittent illumination increased H2 and C2H4 yields per unit of light from growing cells and from nitrogren-starved cells by 1.7- and 1.35-fold, respectively, as compared with continuous illumination.     

Prolonged lipid oxidation after photodynamic treatment. Study with oxidation-sensitive probe C11-BODIPY581/591

Photodynamic treatment (PDT) is an emerging procedure for the therapy of cancer, based on photosensitizers, compounds that generate highly reactive oxygen species on illumination with visible light. Photodynamic peroxidation of cellular lipids is a consequence of PDT associated with cytolethality. We used chloromethyl dichlorodihydrofluorescein diacetate and a novel fluorescent ratiometric oxidation-sensitive probe, C11-BODIPY581/591 (C11-BO), which reports on lipid peroxidation, for visualizing oxidative stress in cells subjected to PDT with a phthalocyanine photosensitizer Pc4. With C11-BO loaded into the cells before or immediately after PDT, we observed a prolonged oxidation, which continued up to 30 min after illumination. In contrast, H2O2 caused oxidation of C11-BO only when the cells were in direct contact with H2O2. PDT-induced oxidative stress was most pronounced in vesicular perinuclear organelles, most likely photodamaged lysosomes. We hypothesize that the lysosomal localization of the prolonged oxidative stress is a consequence of the presence of redox-active iron in lysosomes. In conclusion, we have found that oxidative stress induced in cells by PDT differs from one induced by H2O2 in respect of induction of prolonged oxidation of lipids.     

Lag phase of CO2-dependent O2 evolution by illuminated Anabaena variabilis cells.

The steady-state rate of CO2-dependent O2 evolution by Anabaena variabilis cells in response to illumination was established after a lag phase. The lag phase was shortened (1) in cells incubated with glucose as an oxidizable substrate and (2) upon an increase in light intensity. The lag phase was absent during electron transfer from H2O to p-benzoquinone (in combination with ferricyanide) involving Photosystem II. A lag was observed during electron transfer from H2O to methyl viologen involving Photosystems II and I, but not for electron transfer from N,N,N',N'-tetramethyl-p-phenylenediamine (in combination with ascorbate) to methyl viologen involving only Photosystem I. The lag phases of the light-induced H2O --> CO2 and H2O --> methyl viologen electron transfer reactions showed the same temperature dependences at 10-30 degrees C. The lag was prevented by 3-(3,4-dichlorophenyl)-1,1-dimethylurea at concentrations that caused partial inhibition of photosynthetic O2 evolution. Retardation of cell respiration by a combination of CN- and benzylhydroxamate shortened the lag phase of the H2O --> methyl viologen electron transfer. It is concluded that the lag phase is associated with the electron transfer step between Photosystem II and Photosystem I common for the photosynthetic and respiratory chains and is due to the stimulation of cell respiration during the initial period of illumination as a consequence of an increase in the reduced plastoquinone pool and to subsequent retardation of respiration resulting from the transition of the electron transfer chain to the competitive pathway involving Photosystem I.     

Characterization of proton extrusion in sunflower cell cultures.

Cell suspensions derived from callus root tips of sunflower (Helianthus annuus L., cv. enano) were obtained in order to assess the effects of different chemical and physical agents on cell H+ extrusion. Cell H+ efflux was sensitive to temperature, pH, inhibitors of plasmalemma H(+)-ATPase and Ca2+ and K+ concentrations in the assay medium, as well as to the light intensity at which cells were cultivated. Thus, in the darkness and at 60 mumol/m2/s of illumination, a strong inhibition of H+ extrusion was detected as compared to cells grown at 30 mumol/m2/s. H+ extrusion by cells grown at 30 mumol/m2/s was unaffected by the presence of calcium in the assay medium, while at 60 mumol/m2/s such an activity increased when calcium was removed. These results provide the basis for the use of cell suspensions as an appropriate model to investigate the involvement of membrane-associated processes in plant tolerance mechanisms to different environmental stresses.     

Studies on the Induction of Reversible Hydrogenase from Cyanobacterium Anabaena variabilis and its Properties

The reversible hydrogenase in vegetative cells of A. variabilis cultured on NH4+ or N-free medium was induced by sparging with N2 for 24 hours under light. Both anaerobic condition and illumination appear to be necessary for the induction of hydrogenase in this algae. The properties of the hydrogenase in cell-free extract obtained from the cells grown on two nitrogen sources are similar: (1) Both the enzymes are able to evolve H2 in the presence of reduced methyl viotogen as electron donor, and to uptake H2 in the presence of benzyl viologen as electron acceptor. (2) The enzymes posses the thermal stability and are stable to O2. (3) The optimum pH required for H2 evolution activity of the enzymes is 7.0–7 5. (4) The Km of the enzymes obtained from NH4+ grown cells and N-free grown cells is 300 mmol/l and 295 mmol/l, respectively. So the high Km measured here suggests that the enzymes in both cases function physiologically as H2 evolution. (5) The activities of both enzymes are inhibited by CO but are not affected by C2H2. The induced H2 evolution activity of the reversible hydrogenase in cells grown on NH4+ reached 1530 nmol H2/mg dry wt, h, which was 3 to 5 times higher than from cells grown on N-free medium. Our experiment results indicate that the appearance of heterocysts of A. variabilis cultured on N-free medium affects the synthesis of reversible hydrogenase and the regulation of its activity.     

Low energy visible light induces reactive oxygen species generation and stimulates an increase of intracellular calcium concentration in cardiac cells

Low energy visible light (LEVL) irradiation has been shown to exert some beneficial effects on various cell cultures. For example, it increases the fertilizing capability of sperm cells, promotes cell proliferation, induces sprouting of neurons, and more. To learn about the mechanism of photobiostimulation, we studied the relationship between increased intracellular calcium ([Ca2+]i) and reactive oxygen species production following LEVL illumination of cardiomyocytes. We found that visible light causes the production of O2. and H2O2 and that exogenously added H2O2 (12 microm) can mimic the effect of LEVL (3.6 J/cm2) to induce a slow and transient increase in [Ca2+]i. This [Ca2+]i elevation can be reduced by verapamil, a voltage-dependent calcium channel inhibitor. The kinetics of [Ca2+]i elevation and morphologic damage following light or addition of H2O2 were found to be dose-dependent. For example, LEVL, 3.6 J/cm2, which induced a transient increase in [Ca2+]i, did not cause any cell damage, whereas visible light at 12 J/cm2 induced a linear increase in [Ca2+]i and damaged the cells. The linear increase in [Ca2+]i resulting from high energy doses of light could be attenuated into a non-linear small rise in [Ca2+]i by the presence of extracellular catalase during illumination. We suggest that the different kinetics of [Ca2+]i elevation following various light irradiation or H2O2 treatment represents correspondingly different adaptation levels to oxidative stress. The adaptive response of the cells to LEVL represented by the transient increase in [Ca2+]i can explain LEVL beneficial effects.     

Electrophysiological evidence for interaction between retinula cells in the flesh-fly

Summary In the electrical response of retinula cells to polarized light in the flesh-flyBoettcherisca peregrina, the polarization plane which showed the maximum sensitivity (Pol_max phase) to illumination by a small spot of light just large enough to cover only one retinula cell was found to differ from that with illumination by a larger spot of light which included adjacent cells. There was a difference of about 30°.This difference in Pol_max phase was assumed to indicate the occurrence of interaction between retinula cells even in the fly photoreceptor having rhabdom of the open type. This assumption was confirmed by the following experiments. (1) Under selective adaptation by a large spot of polarized light so as to eliminate the interaction effect, the Pol_max phase was found to be the same as that measured by a small spot even though the measurement had been made using a large spot of light. (2) The responses to polarized light illuminated from along some restricted off-axes showed a 60° shift in the Pol_max phase in comparison to those obtained from along the other axes. (3) The spectral sensitivity curves to illumination from along off-axes were almost all the same and were for the peripheral retinula cells. (4) The receptor potentials were found to increase in amplitude in a certain limited off-axis area that corresponded to the specific off-axis direction of illumination which had resulted in a shift of the Pol_max phase.It is concluded from these results that the peripheral retinula cells in the flesh-fly demonstrate interaction between certain two adjacent retinula cells. This interaction is positive but not a simple algebraic sum of the activity of two cells.This work was partly supported by a grant from the Japan Education MinistryI wish to thank the Department of Biology, Faculty of Sciences, Kyushu University (Prof. H. Morita and Prof. H. Tateda) for the constant supply of flesh-flies.     

Light-driven primary sodium ion transport in halobacterium halobium membranes

Light-induced sodium extrusion from H halobium cell envelope vesicles proceeds largely through an uncoupler-sensitive pathway involving bacteriorhodopsin and a proton/sodium antiporter. Vesicles from bacteriorhodopsin-negative strains also extrude sodium ions during illumination, but this transport is not sensitive to uncouplers and has been proposed to involve a light-energized primary sodium pump. Proton uptake in such vesicles is passive, and under steady-state illumination the large electrical potential (negative inside) is just balanced by a pH difference (acid inside), so that the protonmotive force is near zero. Action spectra indicated that this effect of illumination is attributable to a pigment absorbing near 585 nm (of 568 for bacteriorhodopsin). Bleaching of the vesicles by prolonged illumination with hydroxylamine results in inactivation of the transport; retinal addition causes partial return of the activity. Retinal addition also causes the appearance of an absorption peak at 588 nm, while the absorption of free retinal decreases. The 588 nm pigment is present in very small quantities (0.13 nmole/mg protein), and behaves differently from bacteriorhodopsin in a number of respects. Vesicles can be prepared from bacteriorhodopsin-containing H halobium strains in which primary transport for both protons and sodium can be observed. Both pumps appear to cause the outward transport of the cations. The observations indicate the existence of a second retinal protein, in addition to bacteriorhodopsin, in H halobium, which is associated with primary sodium translocation. The initial proton uptake normally observed during illumination of whole H halobium cells may therefore be a passive flux in response to the primary sodium extrusion.     

Reductive effect of H(2) uptake and poly-beta-hydroxybutyrate formation on nitrogenase-mediated H(2) accumulation of Rhodobacter sphaeroides according to light intensity

Nitrogenase-mediated H(2) accumulation of Rhodobacter sphaeroides under photoheterotrophic conditions is reduced directly by the hydrogenase activity catalyzing H(2) uptake and indirectly by energy-demanding metabolic processes such as poly-beta-hydroxybutyrate (PHB) formation. H(2) accumulation of R. sphaeroides was examined during cell growth under illumination of 15, 7, and 3 W/m(2). Mutations in either hupSL (H(2)-uptake hydrogenase) or phbC (PHB synthase) had no effect on nitrogenase activity. The nitrogenase activity of R. sphaeroides grown at 15 W/m(2), however, was 70% higher than that of cells grown at 3 W/m(2), while the H(2)-uptake hydrogenase activity was approximately 3-fold higher in the same comparison. Accordingly, H(2) uptake by hydrogenase, monitored by measuring the difference in H(2) accumulation between a hupSL-deletion mutant and the corresponding parental strain, appeared to reach a maximum level as illumination was increased to 15 W/m(2). On the other hand, the surplus energy due to lack of PHB formation led to a fixed increase in H(2) accumulation independent of light intensity, reflecting the fact that the cellular PHB content was not changed significantly depending on light intensity. Therefore, H(2) uptake by hydrogenase should be suppressed to achieve higher H(2) accumulation of R. sphaeroides, especially at 15 W/m(2).     

Influence of environmental and nutritional factors in the production of astaxanthin from Haematococcus pluvialis

Astaxanthin extracted from green algae is desirable in the food and pharmaceutical industries due to its antioxidant properties. The green unicellular clear water microalga Haematococcus pluvialis has a high production rate of astaxanthin; indeed, it contains more than 80% astaxanthin content in its cells. This remarkable astaxanthin production is commonly obtained under stress conditions such as nutrient deficiency (N or P), high NaCl concentrations, variations of temperature, and other factors. In this vein, a great research effort has been oriented to determine optimal conditions for astaxanthin production by H. pluvialis.The objective of the present study was the analysis of environmental factors, such as light intensity, aeration and nutrients on the growth and astaxanthin production of H. pluvialis. Maximum growth of H. pluvialis obtained was 3.5x10(5) cells/ml in BBM medium at 28 degrees C under continuous illumination (177 micromol photon m(-2)s(-1)) of white fluorescent light, with continuous aeration (1.5 v.v.m.). Meanwhile, maximal astaxanthin production was 98 mg/g biomass in BAR medium with continuous illumination (345 micromol photon m(-2)s(-1)), with 1 g/l of sodium acetate and without aeration.     

Photosynthetic control of the plasma membrane H+-ATPase in Vallisneria leaves. I. Regulation of activity during light-induced membrane hyperpolarization

In mesophyll cells of the aquatic angiosperm Vallisneria gigantea Graebner, red, blue, or blue plus far-red light induced a typical membrane hyperpolarization, whereas far-red light alone had little effect. Both N,N'-dicyclohexylcarbodiimide, a potent inhibitor of H+-ATPase, and carbonylcyanide m-chlorophenylhydrazone, an uncoupler, produced a considerable membrane depolarization in the dark-adapted cells and a complete suppression of the light-induced hyperpolarization. Although 3-(3',4'-dichlorophenyl)-1,1-dimethylurea (DCMU), an inhibitor of photosynthetic electron transport, did not affect the membrane potential in darkness, it completely inhibited the light-induced membrane hyperpolarization. In vivo illumination of the leaves with red light caused a substantial decrease in the Km for ATP, not only of the vanadate-sensitive ATP-hydrolyzing activity in leaf homogenate, but also of the ATP-dependent H+-transporting activity in plasma membrane (PM) vesicles isolated from the leaves by aqueous polymer two-phase partitioning methods. The effects of red light were negated by the presence of DCMU during illumination. In vivo illumination with far-red light had no effect on the Km for ATP of H+-transporting activity. These results strongly suggest that an electrogenic component in the membrane potential of the mesophyll cell is generated by the PM H+-ATPase, and that photosynthesis-dependent modulation of the enzymatic activity of the PM H+-ATPase is involved in the light-induced membrane hyperpolarization.     

Influence of sodium orthovanadate on the production of astaxanthin from green algae Haematococcus lacustris

Astaxanthin production is commonly induced under stress conditions such as nutrient deficiency (N or P), high light stress, and variations of temperature, high NaCl concentrations, and other factors. The objective of the present study is the analysis of the effect of oxidative stress by sodium orthovanadate (SOV), a nonspecific inhibitor of protein tyrosine phosphatases, on the cells growth and astaxanthin production of H. lacustris. In the presence of SOV (lower than 5.0 mM), maximum growth of H. lacustris obtained was 2.4 × 10⁵ cells/mL in MBBM medium at 24°C under continuous illumination (40 μE/m²/s) of white fluorescent light, with continuous aeration of CO₂ (0.2 vvm). Total carotenoids accumulated per cell biomass unit treated with 2.5 mM SOV has approximately shown 2.5 folds higher than the control after short period of SOV induction time as 2 days, despite that cells were grown under normal light. Meanwhile, maximal astaxanthin production from H. lacustris was 10.7 mg/g biomass in MBBM with 5 days of continuous illumination at 40 μE/m²/s, which has been established as optimal light intensity for the control culture of H. lacustris. Treating algae H. lacustris with sodium orthovanadate showed promoting the accumulation of astaxanthin by advancing either the inhibition of dephosphorylation or synthesis of ATP. Its potential role of PTPases in microalgae H. lacustris is discussed. The first two authors are equally contributed to this work.     

Light-induced blockage of cell division with a chromatin-targeted phototoxic fluorescent protein

Proteins of the GFP (green fluorescent protein) family are widely used as passive reporters for live cell imaging. In the present study we used H2B (histone H2B)-tKR (tandem KillerRed) as an active tool to affect cell division with light. We demonstrated that H2B-tKR-expressing cells behave normally in the dark, but transiently cease proliferation following green-light illumination. Complete light-induced blockage of cell division for approx. 24 h was observed in cultured mammalian cells that were either transiently or stably transfected with H2B-tKR. Illuminated cells then returned to normal division rate. XRCC1 (X-ray cross complementing factor 1) showed immediate redistribution in the illuminated nuclei of H2B-tKR-expressing cells, indicating massive light-induced damage of genomic DNA. Notably, nondisjunction of chromosomes was observed for cells that were illuminated during metaphase. In transgenic Xenopus embryos expressing H2B-tKR under the control of tissue-specific promoters, we observed clear retardation of the development of these tissues in green-light-illuminated tadpoles. We believe that H2B-tKR represents a novel optogenetic tool, which can be used to study mitosis and meiosis progression per se, as well as to investigate the roles of specific cell populations in development, regeneration and carcinogenesis in vivo.     

Molecular mechanisms of the resistance to hydrogen peroxide of enzymes involved in the calvin cycle from halotolerant Chlamydomonas sp. W80

cDNA clones encoding NADP(+)-glyceraldehyde-3-phosphate dehydrogenase (NADP(+)-GAPDH) and sedoheptulose-1,7-bisphosphatase (SBPase) were isolated and characterized from halotolerant Chlamydomonas sp. W80 (C. W80) cells. The cDNA clone for NADP(+)-GAPDH encoded 369 amino acid residues, preceded by the chloroplast transit peptide (37 amino acid residues). The cDNA clone for SBPase encoded 351 amino acids with the chloroplast transit peptide. The activities of NADP(+)-GAPDH and SBPase from C. W80 cells were resistant to H(2)O(2) up to 1 mM, as distinct from spinach chloroplastic thiol-modulated enzymes. The illumination to the dark-adapted cells and dithiothreitol treatment to the crude homogenate had little effect on the activities of NADP(+)-GAPDH and SBPase in C. W80. Modeling of the tertiary structures of NADP(+)-GAPDH and SBPase suggests that resistance of the enzymes to H(2)O(2) in C. W80 is due to the different conformational structures in the vicinity of the Cys residues of the chloroplastic enzymes between higher plant and C. W80 cells.     

Induction of a high-CO2-inducible, periplasmic protein, H43, and its application as a high-CO2-responsive marker for study of the high-CO2-sensing mechanism in Chlamydomonas reinhardtii

The unicellular green alga Chlamydomonas reinhardtii can acclimate to a broad range of environmental CO(2) concentrations. We observed that the cells synthesized a specific 43 kDa protein, H43, in the periplasmic space under photoautotrophic high-CO(2) conditions. Under low-CO(2) conditions, H43 disappeared. However, H43 mRNA expression was observed even under heterotrophic low-CO(2) conditions when the cells were grown with 17.4 mM acetate in darkness. When the cells were treated with 4,4'-dithiocyanatostilbene-2,2'-disulfonate (DIDS) and mersalyl to modify cell surface proteins, H43 mRNA expression was strongly affected under both heterotrophic and photoautotrophic conditions. The H43 induction pattern in a mitochondrial respiration-deficient mutant dum-1 that lacks cytochrome c oxidase was the same, but the level was much lower than that in the wild type. Even under illumination, the dissolved CO(2) concentration in the culture rapidly increased slightly following the addition of acetate and dramatically increased even further by the inhibition of photosynthesis with DCMU. Radiotracer experiments with [U-(14)C]acetate revealed that (14)CO(2) release from cells was greater in darkness than in the light due to the great stimulation of internal CO(2) evolution, resulting in an increase in external CO(2) concentration. Strong light inhibited H43 induction and DCMU promoted the induction under photoheterotrophic low-CO(2) conditions. The results demonstrate that H43 is strictly regulated by a concentration of CO(2) resulting from respiration and photosynthesis. Our results suggest that Chlamydomonas induces high-CO(2)-responsive protein H43 by sensing the concentration of ambient CO(2) with the contribution of cell surface protein.     

Cytotoxic action mode of a novel porphyrin derivative isolated from harmful red tide dinoflagellate Heterocapsa circularisquama

Heterocapsa circularisquama is known to cause lethal effect on bivalves, but toxic effect on fish has not been reported yet. Recently, we have found that H. circularisquama has potent light-dependent hemolytic toxins. Based on the chemical structural analysis, one of the hemolytic toxins named H2-a was found to be a novel porphyrin derivative with similar structure to pyropheophorbide a methyl ester (PME), a well-known photoactive hemolytic agent (Miyazaki et al., Aquatic Toxicol. 2005;73:382--393). To clarify the cytotoxic action mode of H2-a, we examined the effects of H2-a on HeLa cells in comparison with PME. The cytotoxicities of both reagents were strictly light dependent, and no significant cytotoxic effects including cellular morphological changes were induced without light illumination. The dose response curves revealed that H2-a showed stronger cytotoxicity to HeLa cells than PME. Fluorescence microscopic observation suggested that H2-a tends to accumulate in the plasma membrane, whereas PME seems to distribute entire cytoplasm. Although PME induced typical apoptotic nuclear morphological changes and DNA fragmentation in HeLa cells, no such apoptosis-inducing ability of H2-a was observed. Among the radical scavengers, histidine significantly inhibited the cytotoxic activity of H2-a, suggesting the involvement of singlet oxygen in the cytotoxicity. These results suggest that the cytotoxic mechanism of H2-a is necrotic rather than apoptosis differing from PME, even though these are structurally quite similar to each other. The relatively high affinity of H2-a to the plasma membrane might result in the potent and quick cytotoxicity without induction of apoptotic signal transduction.     

Permeabilization of thymocytes by photon activation of erythrosin

Thymocytes previously loaded with quin 2 were rapidly permeabilized by the photon activation of erythrosin and the rate of permeabilization monitored by measuring fluorimetrically the increasing saturation of quin 2 with calcium. The extent of permeabilization was assessed also by the loss of [3H]quin 2 from the thymocytes and penetration of the cells by eosin and trypan blue. Lactate dehydrogenase leakage from the permeabilized cells was markedly delayed compared to the rapid increase in permeability to calcium and quin 2. The rate of permeabilization was dependent upon the concentration of erythrosin, the duration of illumination, the presence of oxygen, and the temperature. These results are consistent with the rapid photochemical generation of highly reactive singlet oxygen which alters thymocyte membrane structure and permeability.     

光照和不同药剂浸种对龙葵种子发芽率的影响

为探索超富集植物龙葵种子的快速发芽方法,以滤纸为发芽基质,采用恒温培养箱及温室培养的方法,对龙葵种子进行不同浸种处理,探讨光照及不同浸种液对龙葵种子发芽的影响.结果表明: 光照条件是龙葵种子发芽的重要条件之一,光照条件下的发芽率约为无光照条件下发芽率的5倍(P<0.05);不同浸种液均能显著提高龙葵种子的发芽率,其中以双氧水的处理效果最好,发芽时间最短(P<0.05);浸种后不经清洗处理的龙葵种子发芽率约为浸种后再经清洗处理发芽率的2～3倍(P<0.05).     

Periodic changes in the oxidation state of manganese in photosynthetic oxygen evolution upon illumination with flashes

The pattern of manganese released from chloroplast membranes by a rapid temperature shock after various illumination regimes indicates that changes in the oxidation state of bound manganese occur during photosynthesis. Continuous illumination decreases by 35-40% the amount of Mn(II) released in the presence of K3Fe(CN)6 compared with a dark-adapted control. Following illumination and heat treatment, the addition of the reductant H2O2 to the samples causes an increase in the level of electron paramagnetic resonance (EPR)-detectable manganese. The pH dependence of the H2O2 reduction indicates that the non-EPR-detectable manganese present in the heated sample after illumination is in the form of higher oxidation state compounds, e.g. MnO2. The light-induced Mn(II) decrease is reversible in the dark with t 1/2 approx. 40 s and can be prevented by the presence of the Photosystem II inhibitors 3-(3,4-dichlorophenyl)-1,1-dimethyl urea or fluorocarbonylcyanide phenylhydrazone during the illumination period. After a series of brief flashes of light the Mn(II) released by heat treatment oscillates over periods of four flashes. The pattern is similar to the O2 yield flash pattern and suggests that a cycling of manganese oxidation states is involved in the O2 evolution mechanism. The oscillations in the Mn(II) release are analyzed in terms of the current four-step model for O2 evolution. The analysis suggests that manganese is successively oxidized in the first two steps, but undergoes a partial reduction on the third step. This result is consistent with the concept that water undergoes a partial oxidation prior to the release of O2 from the water-splitting complex.