Fluorescence characteristics of photoinhibition and recovery in a sun and a shade species of the red algal genus porphyra

The effects of light treatment (2000 micromole photons per square meter per second) for varying periods (up to 60 minutes) on chlorophyll fluorescence characteristics and light-limited rates of O₂ evolution were examined in two Porphyra species. Brief light exposures (5-60 seconds) produced a large decrease in variable fluorescence which was not accompained by photoinhibition of light-limited O₂ evolution rates. This rapid decrease in variable fluorescence was suppressed by carbonylcyanide m-chlorophenylhydrazone, indicating that it was related to formation of a proton gradient across the thylakiod membranes. A second phase of fluorescence quenching started after 5 minutes of illumination in the case of the shade species, Porphyra nereocystis Anderson, and after 30 minutes of illumination in the case of the sun species, Porphyra perforata J. Agardh. The rate of fluorescence quenching in the second phase was similar to the rate of photoinhibition of light-limited O₂ evolution in both cases. The dark recovery of variable fluorescence in light-treated plants was also biphasic consisting of a rapid first phase and a slower second phase in both the Porphyra species. Recovery of P. perforata was more complete than that of P. nereocystis over the same recovery period. This greater capacity for recovery could represent a mechanism by which P. perforata is more resistant to photoinhibition than P. nereocystis.     

Nitrogen fixation by Anabaena cylindrica

Hydrogen-supported nitrogenase activity was demonstrated in Anabaena cylindrica cultures limited for reductant. Nitrogen-fixing Anabaena cylindrica cultures sparged in the light with anaerobic gases in the presence of the photosynthesis inhibitor DCMU slowly lost their ability to reduce acetylene in the light under argon but exhibited near normal activities in the presence of 11% H₂ (balance argon). The hydrogen-supported nitrogenase activity was half-saturated between 2 and 3% H₂ and was strongly inhibited by oxygen (50% inhibition at about 5–6% O₂). Batch cultures of Anabaena cylindrica approaching stationary growth phase (“old” cultures) lost nitrogenase-dependent hydrogen evolution almost completely. In these old cultures hydrogen relieved the inhibitory effects of DCMU and O₂ on acetylene reduction. Our results suggest that heterocysts contain an uptake hydrogenase which supplies an electron transport chain to nitrogenase but which couples only poorly with the respiratory chain in heterocysts and does not function in CO₂ fixation by vegetative cells.     

Light-Induced Proton Release by the Cyanobacterium Anabaena variabilis: Dependence on CO(2) and Na

Light-induced acidification by the cyanobacterium Anabaena variabilis is biphasic (a fast phase I and slow phase II) and shown to be sodium-dependent with an optimum concentration of 40 to 60 millimolar Na⁺. Cells grown under low CO₂ concentrations at pH 9 (i.e. mainly HCO₃⁻ present in the medium) exhibited the slow phase II of proton efflux only, while cells grown under low CO₂ concentrations at pH 6.3 (i.e. CO₂ and HCO₃⁻ present) exhibited both phases. Light-induced proton release of phase I was dependent on inorganic carbon available in the bathing medium with an apparent K_m for CO₂ of 20 to 70 micromolar. As was concluded from the CO₂ dependence of acidification measured at different pH of the bathing medium, bicarbonate inhibited phase-I acidification noncompetetively. Acidification was inhibited by acetazolamide, an inhibitor of carbonic anhydrase. Apparently, acidification of phase I is due to a light-dependent uptake of CO₂ being converted to HCO₃⁻ by a carbonic anhydrase-like function of the HCO₃⁻-transport system (M Volokita, D Zenvirth, A Kaplan, L Reinhold 1984 Plant Physiol 76: 599-602) before or during entering the cell, thus releasing one proton per CO₂ converted to HCO₃⁻.     

Light-Stimulated Changes in the Acidity of Suspensions of Oat Protoplasts: Dependence upon Photosynthesis

Light induced an alkalinization and stimulated a subsequent acidification of the medium surrounding oat (Avena sativa L. cv Garry) leaf protoplasts. Blue light was less effective than would be predicted from photosynthetic action spectra. Nonetheless, 3-(3,4-dichlorophenyl)-1,1-dimethylurea prevented alkalinization and reduced acidification to the dark rate for protoplast suspensions exposed to all light regimes tested.

Alkalinization increased in parallel with initial rates of O₂ evolution as the quantum flux density of white light was raised to 75 microeinsteins per square meter per second. Alkalinization was accompanied by a decrease in the CO₂ content of the medium; therefore, it was attributed to photosynthetically induced CO₂ uptake. The effect of CO₂ depletion on the acidity of the medium appeared to be mainly restricted to the first 15 minutes of exposure to light. Consequently, subsequent pH changes primarily reflected a constant net proton efflux. Acidification occurred in the dark, but rates of acidification increased in response to increased light approximately in parallel with changes in a concomitant net O₂ efflux. The results indicated that protoplasts could acidify the medium in response to nonphotosynthetic activity, but that photosynthesis mediated light stimulation of acidification.

     

Nature of the light-induced h efflux and na uptake in cyanobacteria

We investigated the nature of the light-induced, sodium-dependent acidification of the medium and the uptake of sodium by Synechococcus. The rate of acidification (net H⁺ efflux) was strongly and specifically stimulated by sodium. The rates of acidification and sodium uptake were strongly affected by the pH of the medium; the optimal pH for both processes being in the alkaline pH range. Net proton efflux was severely inhibited by inhibitors of adenosine triphosphatase activity, energy transfer, and photosynthetic electron transport, but was not affected by the presence of inorganic carbon (C_i). Light and C_i stimulated the uptake of sodium, but the stimulation by C_i was observed only when C_i was present at the time sodium was provided. Amiloride, a potent inhibitor of Na⁺/H⁺ antiport and Na⁺ channels, stimulated the rate of acidification but inhibited the rate of sodium uptake. It is suggested that acidification might stem from the activity of a light dependent proton excreting adenosine triphosphatase, while sodium transport seems to be mediated by both Na⁺/H⁺ antiport and Na⁺ uniport.     

Effect of root environment on proton efflux in wheat roots

Proton net efflux of wheat (Triticum aestivum L.) roots growing in sand culture or hydroponics was determined by measuring the pH values of the solution surrounding the roots by pH microelectrodes, by base titration and by color changes of a pH indicator in solid nutrient media. The proton net efflux was dependent on light, aeration, and source of nitrogen (NH ₄ ⁺ , NO ₃ ^? ). Ammonium ions caused the highest proton efflux, whereas nitrate ions decreased the proton efflux. Iron deficiency had no significant effect on proton efflux. Replacement of ammonium by nitrate inhibited proton efflux, whereas the reverse enhanced proton extrusion. A lag period between changes in plant environment and proton efflux was observed. The proton net efflux occurred at the basal portion of the roots but not in the root tips or at the elongation zone. Under optimal conditions, proton efflux capacity reached a maximum value of 5.7 μmole H⁺ g^?1 fresh weight h^?1 with an average (between different measurements) of 3.4 μmole H⁺ g^?1 fresh wth^?1 whereas the pH value decreased to 3.2–3.7 and reached a minimal value of 2.9. Inhibition of ATPase activity by orthovanadate inhibited proton efflux. The results indicate that proton efflux in wheat roots is ammonium ion and light dependent and probably governed by ATPase activity.     

Hg2+ and Cd2+ induced inhibition of light induced proton efflux in the cyanobacteriumAnabaena flos-aquae

Light induced proton efflux in intact cells ofAnabaena flos-aquae is inhibited by the heavy metals Hg²⁺ and Cd²⁺. Furthermore, Hg²⁺ and Cd²⁺ reduced the¹⁴CO₂ fixation, oxygen evolution and carbonic anhydrase activity responsible for H⁺ efflux.     

Action Spectrum for Resetting the Circadian Phototaxis Rhythm in the CW15 Strain of Chlamydomonas: I. Cells in Darkness

We have developed protocols for phase shifting the circadian rhythm of Chlamydomonas reinhardtii by light pulses. This paper describes the photobiology of phase-resetting the Chlamydomonas clock by brief (3 seconds to 15 minutes) light pulses administered during a 24 hour dark period. Its action spectrum exhibited two prominent peaks, at 520 and 660 nanometers. The fluence at 520 nanometers required to elicit a 4 hour phase shift was 0.2 millimole photon per square meter, but the pigment that is participating in resetting the clock under these conditions is unknown. The fluence needed at 660 nanomoles to induce a 4 hour phase shift was 0.1 millimole photon per square meter, which is comparable with that needed to induce the typical low fluence rate response of phytochrome in higher plants. However, the phase shift by red light (660 nanometers) was not diminished by subsequent administration of far-red light (730 nanometers), even if the red light pulse was as short as 0.1 second. This constitutes the first report of a regulatory action by red light in Chlamydomonas.     

Spontaneous Chemiluminescence of Soybean Embryonic Axes during Imbibition

Isolated soybean (Glycine max L. var Hood) embryonic axes have a spontaneous chemiluminescence (about 150 counts per minute per embryo) that increases showing two phases, upon water imbibition. The first photoemission burst was measured between 0 and 7 hours of imbibition with a maximum of about 350 counts per minute per embryo after 2 hours. The second photoemission phase, between 7 and 30 hours, increased from about 220 to 520 counts per minute per embryo. Both chemiluminescence phases were inhibited by infused butylated hydroxyanisole while only the second phase was inhibited by infused salicylhydroxamic acid. On the basis of the sensitivity of the lipoxygenase reaction to both inhibitors (about 90%), the first burst is tentatively assigned to oxy-radicals mobilized upon water uptake by the embryonic axes, and the second phase is tentatively identified as due to lipoxygenase activity. The in vivo lipoxygenase activity of the embryonic axes was estimated by both the fraction of total oxygen uptake that was inhibited by butylated hydroxyanisole and by the fraction of photoemission that was inhibited by butylated hydroxyanisole and by salicylhydroxamic acid. Both approaches indicated marked increases (5-fold and 12-fold, respectively) of lipoxygenase activity between 2 and 30 hours of imbibition. The measured chemiluminescence per O₂ uptake ratio (the experimental quantum yield) for the lipoxygenase reaction (3.3 × 10⁻¹⁴ counts per O₂ molecule) was used to estimate the O₂ uptake due to lipoxygenase activity from the photoemission of the embryonic axes after 30 hours of imbibition. The value (0.54 microliters per minute per axis) was close to the butylated hydroxyanisole-sensitive O₂ uptake (1.2 microliters O₂ per minute per axis) of the same embryonic axes. Chemiluminescence may afford a noninvasive assay for lipoxygenase activity in intact plant tissues.     

Effects of air pollutants on proton and sucrose transport at the plasma membrane of Ricinus communis

The effects of the air pollutants O₃, SO₂ and NO₂ on aspects of sucrose/proton cotransport across the plasma membrane of Ricinus communis plants have been investigated. The H⁺-ATPase hydrolytic activity in cotyledon plasma membrane vesicles purified by phase partitioning showed small stimulations by Na₂SO₃ or NaNO₃ added separately or together to the assay medium. ATPase activity from plants pretreated by fumigation with SO₂ or O₃ also showed an increase, the effect of O₃ being quite marked. Plasma membrane H⁺-pumping in KI-treated microsomal fractions and medium acidification by intact cotyledons both showed small decreases in the presence of Na₂SO₃ or NaNO₂. Both Na₂SO₃ and NaNO₂ at high concentrations (2 mol m^–3) had significant effects on sucrose uptake by intact cotyledons, although sucrose efflux was unaffected. No significant effects on sucrose uptake or efflux by intact cotyledons were observed in plants pretreated by fumigation with SO₂ or O₃. Proton-coupled sucrose transport in isolated plasma membrane vesicles was inhibited in the presence of Na₂SO₃ or NaNO₂. However, both pollutants also significantly inhibited the uptake of acetate by the vesicles, indicating a dissipation of the pH gradient across the membrane. It was concluded that no specific aspect of the sucrose/proton cotransport mechanism was damaged by these air pollutants, and that the effects of these pollutants on carbohydrate partitioning are more likely to be due to general effects on membrane integrity or on other aspects such as leaf carbohydrate metabolism.     

Phloem loading of sucrose: involvement of membrane ATPase and proton transport

p-Chloromercuribenzenesulfonic acid markedly inhibited sucrose accumulation into sugar beet source leaves without inhibiting hexose accumulation. The site of inhibition is proposed to be the plasmalemma ATPase, since the ATPase-mediated H⁺ efflux was completely inhibited by p-chloromercuribenzenesulfonic acid under conditions where intracellular metabolism, as measured by photosynthesis and hexose accumulation, was unaffected. Fusicoccin, a potent activator of active H⁺/K⁺ exchange, stimulated both active sucrose accumulation and proton efflux in the sugar beet leaf tissue. These data provide strong evidence for the phloem loading of sucrose being coupled to a proton transport mechanism driven by a vectorial plasmalemma ATPase.     

Further Characterization on the Transport Property of Plasmalemma NADH Oxidation System in Isolated Corn Root Protoplasts

Recent experiments show that exogenous NADH increases the O₂ consumption and uptake of inorganic ions into isolated corn (Zea mays L. Pioneer Hybrid 3320) root protoplasts (Lin 1982, Proc Natl Acad Sci USA 79: 3773-3776). A mild treatment of protoplasts with trypsin released most of the NADH oxidation system from the plasmalemma (Lin 1982 Plant Physiol 70: 326-328). Further studies on this system showed that exogenous NADH (1.5 millimolar) tripled the proton efflux from the protoplasts thus generating a greater electrochemical proton gradient across the plasmalemma. Trypsin also released ubiquinone (11.95 nanomoles per milligrams protein) but not flavin or cytochrome from the system. Kinetic analyses showed that 1.5 millimolar NADH quadrupled V_max of the mechanism I (saturable) component of K⁺ uptake, while K_m was not affected. Diethylstibestrol and vanadate inhibited basal (ATPase-mediated) K⁺ influx and H⁺ efflux, while NADH-stimulated K⁺ uptake was not or only slightly inhibited. p-Chloromercuribenzene-sulfonic acid, N,N′-dicyclohexylcarbodiimide, ethidium bromide, and oligomycin inhibited both ATPase- and NADH-mediated H⁺ and K⁺ fluxes. A combination of 10 millimolar fusicoccin and 1.5 millimolar NADH gave an 11-fold increase of K⁺ influx and a more than 3-fold increase of H⁺ efflux. It is concluded that a plasmalemma ATPase is not involved in the NADH-mediated ion transport mechanism. NADH oxidase is a -SH containing enzyme (protein) and the proton channel is an important element in this transport system. Fusicoccin synergistically stimulates the effect of NADH on K⁺ uptake.     

Phloem unloading in soybean seed coats: dynamics and stability of efflux into attached ;empty ovules'

The time-course of sucrose efflux from attached seedcoats (having their embryos surgically removed) into aqueous traps placed in the `empty ovules' had three phases. The first phase lasted 10 minutes and probably was a period of apoplastic flushing. The second lasted 2 to 3 hours and is thought to be a phase of equilibration of seed coat symplast with the frequently refreshed liquid. The third phase of relatively steady efflux was postulated to reflect the continued import of sucrose from the plant, and hence to reflect the rate of sieve tube unloading. The average steady state efflux was equal under most conditions to the estimated rate of sucrose import. Efflux and import were unaffected by 150 millimolar osmoticum (mannitol or polyethylene glycol [molecular weight about 400]), by 0.5 millimolar CaCl<sub>2</sub>, or by pretreatments up to 20 minutes with p-chloromercuribenzenesulfonic acid (PCMBS); they were enhanced by 40 micromolar abscisic acid, 40 micromolar indoleacetic acid, 20 micromolar fusicoccin, and 1 millimolar dithiothreitol (DTT) and were inhibited by 100 micromolar KCN, by 0.03% H<sub>2</sub>O<sub>2</sub>, by 20 micromolar and 5 micromolar trifluoromethoxy (carbonyl cyamide) phenylhydrazone, by repeated 5 minutes per hour treatments with 5 millimolar PCMBS, and by 5 millimolar DTT. The `steady state' sucrose efflux was able to account for about half the rate of dry weight growth of the embryo, but stabilization of the system with <1 millimolar DTT taken together with other considerations is likely to give good correspondence between experimental unloading rates and in vivo growth rates.     

Physiological Studies of Oxygen Protection Mechanisms in the Heterocysts of Anabaena cylindrica

The mechanism of O₂ protection of nitrogenase in the heterocysts of Anabaena cylindrica was studied in vivo. Resistance to O₂ inhibition of nitrogenase activity correlated with the O₂ tension of the medium in which heterocyst formation was induced. O₂ resistance also correlated with the apparent K_m for acetylene, indicating that O₂ tension may influence the development of a gas diffusion barrier in the heterocysts. The role of respiratory activity in protecting nitrogenase from O₂ that diffuses into the heterocyst was studied using inhibitors of carbon metabolism. Reductant limitation induced by 3-(3,4-dichlorophenyl)-1, 1-dimethylurea increased the O₂ sensitivity of in vivo acetylene reduction. Azide, at concentrations (30 mM) sufficient to completely inhibit dark nitrogenase activity (a process dependent on oxidative phosphorylation for its ATP supply), severely inhibited short-term light-dependent acetylene reduction in the presence of O₂ but not in its absence. After 3 h of aerobic incubation in the presence of 20 mM azide, 75% of cross-reactive component I (Fe-Mo protein) in nitrogenase was lost; less than 35% was lost under microaerophilic conditions. Sodium malonate and monofluoroacetate, inhibitors of Krebs cycle activity, had only small inhibitory effects on nitrogenase activity in the light and on cross-reactive material. The results suggest that oxygen protection is dependent on both an O₂ diffusion barrier and active respiration by the heterocyst.     

Ammonium Assimilation Requires Mitochondrial Respiration in the Light : A Study with the Green Alga Selenastrum minutum

Mass spectrometric analysis of O₂ and CO₂ exchange in the green alga Selenastrum minutum (Naeg. Collins) provides evidence for the occurrence of mitochondrial respiration in light. Stimulation of amino acid synthesis by the addition of NH₄Cl resulted in nearly a 250% increase in the rate of TCA cycle CO₂ efflux in both light and dark. Ammonium addition caused a similar increase in cyanide sensitive O₂ consumption in both light and dark. Anaerobiosis inhibited the CO₂ release caused by NH₄Cl. These results indicated that the cytochrome pathway of the mitochondrial electron transport chain was operative and responsible for the oxidation of a large portion of the NADH generated during the ammonium induced increase in TCA cycle activity. In the presence of DCMU, ammonium addition also stimulated net O₂ consumption in the light. This implied that the Mehler reaction did not play a significant role in O₂ consumption under our conditions. These results show that both the TCA cycle and the mitochondrial electron transport chain are capable of operation in the light and that an important role of mitochondrial respiration in photosynthesizing cells is the provision of carbon skeletons for biosynthetic reactions.     

Photophosphorylation after chilling in the light : effects on membrane energization and coupling factor activity

The response of in situ photophosphorylation in attached cucumber (Cucumis sativus L. cv Ashley) leaves to chilling under strong illumination was investigated. A single-beam kinetic spectrophotometer fitted with a clamp-on, whole leaf cuvette was used to measure the flash-induced electrochromic absorbance change at 518 minus 540 nanometers (ΔA_518−540) in attached leaves. The relaxation kinetics of the electric field-indicating ΔA_518−540 measures the rate of depolarization of the thylakoid membrane. Since this depolarization process is normally dominated by proton efflux through the coupling factor during ATP synthesis, this technique can be used, in conjuction with careful controls, as a monitor of in situ ATP formation competence. Whole, attached leaves were chilled at 5°C and 1000 microeinsteins per square meter per second for up to 6 hours then rewarmed in the dark at room temperature for 30 minutes and 100% relative humidity. Leaf water potential, chlorophyll content, and the effective optical pathlength for the absorption measurements were not affected by the treatment. Light- and CO₂-saturated leaf disc oxygen evolution and the quantum efficiency of photosynthesis were inhibited by approximately 50% after 3 hours of light chilling and by approximately 75% after 6 hours. Despite the large inhibition to net photosynthesis, the measurements of ΔA_518−540 relaxation kinetics showed photophosphorylation to be largely unaffected by the chilling and light exposure. The amplitude of the ΔA_518-540 measures the degree of energization of the photosynthetic membranes and was reduced significantly by chilling in the light. The cause of the decreased energization was traced to impaired turnover of photosystem II. Our measurements showed that the chilling of whole leaves in the light caused neither an uncoupling of photophosphorylation from photosynthetic electron transport nor any irreversible inhibition of the chloroplast coupling factor in situ. The sizeable inhibition in net photosynthesis observed after chilling in the light cannot, therefore, be attributed to any direct effect on photophosphorylation competence.     

Photosynthetic Apparatus Formation during the Cell Cycle of Chlorella

Synchronous cell division in cultures of Chlorella vulgaris Beijerinck was induced by intermittent illumination: 9 hours light, 6 hours darkness. The rate of photosynthetic O₂ evolution per cell increases 4-fold in a one-step manner at the beginning of the light period, to the same extent as the increase in cell number. Over the division cycle, the following accumulation times during the light period were found: chlorophyll a, between 2 and 8 hours, chlorophyll b, between 5 and 8 hours, reaction centers of photosystems I and II, between 2 and 6 hours; and cytochrome f, between 2.5 and 5 hours. Cytochrome f accumulation is closely followed by an increase in amplitude of the rapid phase in light-induced absorption increase at 520 nanometers and in intensity of the delayed light emission. Enhancement of the delayed fluorescence yield per flash under continuous illumination (caused by the establishment of the pH difference across the thylakoid membrane) is maximal by the first hour of the light period.     

Effects of a triterpenoid saponin on spectral properties of undegraded pea phytochrome

Soyasaponin I, a triterpenoid saponin isolated from etiolated pea (Pisum sativum cv. Alaska) shoots and identified as Pfr killer, was examined for its effects on spectral properties of undegraded pea phytochrome. When soyasaponin I in concentrations of 100 micromolar or lower was added to Pr in the dark, the spectrum of Pr was not significantly affected, whereas in the presence of 120 micromolar or higher concentrations the absorption maximum of Pr shifted from 666 to 658 nanometer with slight decrease of absorbance. After a brief exposure of the mixture to red light, the increase in absorbance at 666 nanometers that occurs in the dark was inhibited at 26 micromolar and higher soyasaponin I concentrations; the maximum effect being reached at about 180 micromolar. The decrease in absorbance at 724 nanometers in the dark after red light irradiation was somewhat inhibited by 60 micromolar and totally prevented by 410 micromolar soyasaponin I. When P₆₅₈ was irradiated with red light in the presence of 220 micromolar or higher soyasaponin I concentrations, a bleached form (P_bl) was produced instead of Pfr. P_bl showed no dark spectral changes, and the phototransformation of P_bl to P₆₅₈ required a significantly high irradiance of far-red light. When the saponin was added to Pfr in the dark, none of the above-described spectral changes occurred, although the same effects were observed after the mixture was exposed briefly to far-red light followed by red light.     

Vanadate-sensitive proton efflux by filamentous cyanobacteria

Abstract Light-induced proton efflux has been investigated with intact cells of Anabaena, Nostoc, Anacystis , and Aphanocapsa . The proton efflux by filamentous blue-green algae is biphasic, strongly inhibited by ortho -vanadate and insensitive to cyanide. These data are taken as evidence for a proton-pumping ATP-hydrolase present on the cytoplasmic membrane of Anabaena and Nostoc .     

Is Modulation of the Rate of Proton Pumping a Key Event in Osmoregulation?

The net uptake of 3-O-methylglucose into leaf segments obtained from Senecio mikanioides Otto, and net proton efflux from the segments, were both promoted when the osmotic potential of the medium was decreased by addition of mannitol, sorbitol, or polyethylene glycol (optimal osmolarity, 0.3 Osmolar for mannitol and sorbitol). The effect was not due to promotion of `aging', since the antibiotic cerulenin suppressed aging without reducing the size of the mannitol stimulation; further, mannitol did not accelerate aging. Neither was the effect ascribable to diminished efflux (i.e. reduced `leak' because: first, visualization of the unidirectional sugar fluxes by double labeling indicated that the effect of added osmoticum was to promote influx rather than to reduce efflux; second, compartment analysis did not suggest any effect of mannitol on the rate constants for efflux from either the slowly equilibrating or more rapidly equilibrating compartment. The effect was not specific to poly-ols since it was also obtained with betaine and choline chloride. Since methyl glucose is not taken up into the phloem it could not be ascribed to a turgor effect on phloem loading. We conclude that the effect may reflect osmoregulation. As the sugar flux is probably driven by protonmotive force, it is likely that the effects on proton flux and on sugar flux are related. We suggest that the plasmalemma-sited proton pump is sensitive to the hydrostatic pressure gradient across the plasmalemma-cell wall complex, and functions both as detector and as effector in osmoregulation.