In vitro Damage to Rat Lens by Lumazine and Xanthine Oxidase: Prevention by Superoxide Dismutase

Intact rat lenses incubated with lumazine and xanthine oxidase are physiologically damaged as evidenced by a decrease in the net accumulation of rubidium ions against a concentration gradient. Superoxide dismutase protected the tissue against this damage. These experiments, therefore, demonstrate the susceptibility of the lens tissue to O₂^?_? injury under ambient and nonphotochemical conditions, suggesting a possible implication of this radical in the tissue in vivo and eventual cataract formation. The lumazine/xanthine oxidase system which is known to cause oxygen reduction predominantly by the monovalent route, producing superoxide, appears quite suitable to evaluate the toxicity of O₂^?_? to the tissues in vitro.     

Oxygen consumption by purified plasmalemma vesicles from wheat roots: Stimulation by NADH and salicylhydroxamic acid (SHAM)

Plasmalemma vesicles from wheat (Triticum aestivum L.) roots consumed O₂ and the addition of 1 mM NADH increased the rate ~ 3-fold (to 15-30 nmol O₂·mg⁻¹·min⁻¹). The NADH-dependent O₂ uptake was abolished by catalase. In the presence of salicylhydroxamic acid (SHAM), an inhibitor of the alternative oxidase pathway in plant mitochondria, NADH-dependent O₂ consumption was stimulated 10–20-fold (to 200–400 nmol·mg^1̄·min⁻¹). Catalase also abolished this stimulation, which was KCN-sensitive but antimycin A-insensitive, and the production of H₂O₂ during SHAM-stimulated NADH-dependent O₂ uptake was demonstrated. Irrespective of the mechanism, SHAM-stimulated respiration by root plasmalemma makes it difficult to interpret results on root respiration obtained using KCN and SHAM.     

Blue-light-induced pH changes associated with NO3−, NO2− and Cl− uptake by the green alga Monoraphidium braunii

In M. braunii, the uptake of NO₃⁻ and NO₂⁻ is blue-light-dependent and is associated with alkalinization of the medium. In unbuffered cell suspensions irradiated with red light under a CO₂-free atmosphere, the pH started to rise 10s after the exposure to blue light. When the cellular NO₃⁻ and NO₂⁻ reductases were active, the pH increased to values of around 10, since the NH₄⁺ generated was released to the medium. When the blue light was switched off, the pH stopped increasing within 60 to 90s and remained unchanged under background red illumination. Titration with H₂SO₄ of NO₃⁻ or NO₂⁻ uptake and reduction showed that two protons were consumed for every one NH₄⁺ released. The uptake of Cl⁻ was also triggered by blue light with a similar 10 s time response. However, the Cl⁻ -dependent alkalinization ceased after about 3 min of blue light irradiation. When the blue light was turned off, the pH immediately (15 to 30 s) started to decline to the pre-adjusted value, indicating that the protons (and presumably the Cl⁻) taken up by the cells were released to the medium. When the cells lacked NO₃⁻ and NO₂⁻ reductases, the shape of the alkalinization traces in the presence of NO₃⁻ and NO₂⁻ was similar to that in the presence of Cl⁻, suggesting that NO₃⁻ or NO₂⁻ was also released to the medium. Both the NO₃⁻ and Cl⁻-dependent rates of alkalinization were independent of mono- and divalent cations.     

Interaction between light and chilling temperature on the inhibition of photosynthesis in chilling-sensitive plants*

Abstract. Fully expanded leaves of 25°C grown Phaseolus vulgaris and six other species were exposed for 3 h to chilling temperatures at photon flux densities equivalent to full sunlight. In four of the species this treatment resulted in substantial inhibition of the subsequent quantum yield of CO₂ uptake, indicating reduction of the photochemical efficiency of photosynthesis. The extent of inhibition was dependent on the photon flux density during chilling and no inhibition occurred when chilling occurred at a low photon flux density. No inhibition occurred at temperatures above 11.5°C, even in the presence of the equivalent of full sunlight. This interaction between chilling and light to cause inhibition of photosynthesis was promoted by the presence of oxygen at normal air partial pressures and was unaffected by the CO₂ partial pressure present when chilling occurred in air. When chilling occurred at low O₂ partial pressures, CO₂ was effective in reducing the degree of inhibition. Apparently, when leaves of chilling-sensitive plants are exposed to chilling temperatures in air of normal composition then light is instrumental in inducing rapid damage to the photochemical efficiency of photosynthesis.     

Light and dark reactions of the uptake hydrogenase in anabaena 7120

Reactions of the uptake hydrogenase from Anabaena 7120 (A.T.C.C. 27893, Nostoc muscorum) were examined in whole filaments, isolated heterocysts, and membrane particles. Whole filaments or isolated heterocysts that contained nitrogenase consumed H₂ in the presence of C₂H₂ or N₂ in a light-dependent reaction. If nitrogenase was inactivated by O₂ shock, filaments catalyzed H₂ uptake to an unidentified endogenous acceptor in the light. Addition of NO₃⁻ or NO₂⁻ enhanced these rates. Isolated heterocysts consumed H₂ in the dark in the presence of electron acceptors with positive midpoint potentials, and these reactions were not enhanced by light. With acceptors of negative midpoint potential, significant light enhancement of H₂ uptake occurred. Maximum rates of light-dependent uptake were approximately 25% of the maximum dark rates observed. Membrane particles prepared from isolated heterocysts showed similar specificity for electron acceptors. These particles catalyzed a cyanide-sensitive oxyhydrogen reaction that was inactivated by O₂ at O₂ concentrations above 2%. Light-dependent H₂ uptake to low potential acceptors by these particles was inhibited by dibromothymoquinone but was insensitive to cyanide. In the presence of O₂, light-dependent H₂ uptake occurred simultaneously with the oxyhydrogen reaction. The pH optima for both types of H₂ uptake were near 7.0. These results further clarify the role of uptake hydrogenase in donating electrons to both the photosynthetic and respiratory electron transport chains of Anabaena.     

Evidence of singlet oxygen participation in the chlorophyll-sensitized photooxidation of indoleacetic Acid

Chlorophyll-sensitized photooxidation of indoleacetic acid (IAA)—with chlorophyll extracted from Pisum sativum L. cv. Alaska W.R.—was determined in the presence of deuterium oxide and known quenchers of singlet oxygen (¹O₂) to explore the involvement of ¹O₂ in the reaction. O₂ uptake was measured in light in a buffered aqueous micellar system containing Triton X-100, KCl, chlorophyll, and IAA. The rate of O₂ uptake was zero in darkness. The reaction was stimulated by deuterium oxide and inhibited by sodium azide indicating that ¹O₂ participated in IAA photooxidation. Both mannitol and superoxide dismutase failed to inhibit O₂ uptake suggesting that neither the hydroxyl radical nor the superoxide anion played a significant role in the reaction.     

16O2/18O2 analysis of oxygen exchange in Dunaliella tertiolecta. Evidence for the inhibition of mitochondrial respiration in the light

A mass spectrometric ¹⁶O₂/¹⁸O₂-isotope technique was used to analyse the rates of gross O₂ evolution, net O₂ evolution and gross O₂ uptake in relation to photon fluence rate by Dunaliella tertiolecta adapted to 0.5, 1.0, 1.5, 2.0 and 2.5 M NaCl at 25°C and pH 7.0.At concentrations of dissolved inorganic carbon saturating for photosynthesis (200 M) gross O₂ evolution and net O₂ evolution increased with increasing salinity as well as with photon fluence rate. Light compensation was also enhanced with increased salinities. Light saturation of net O₂ evolution was reached at about 1000 mol m^-2s^-1 for all salt concentrations tested. Gross O₂ uptake in the light was increased in relation to the NaCl concentration but it was decreased with increasing photon fluence rate for almost all salinities, although an enhanced flow of light generated electrons was simultaneously observed. In addition, a comparison between gross O₂ uptake at 1000 mol photons m^-2s^-1, dark respiration before illumination and immediately after darkening of each experiment showed that gross O₂ uptake in the light paralleled but was lower than mitochondrial O₂ consumption in the dark.From these results it is suggested that O₂ uptake by Dunaliella tertiolecta in the light is mainly influenced by mitochondrial O₂ uptake. Therefore, it appears that the light dependent inhibition of gross O₂ uptake is caused by a reduction in mitochondrial O₂ consumption by light.Abbreviations DCMU 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea - DHAP dihydroxy-acetonephosphate - DIC dissolved inorganic carbon - DR_a rate of dark respiration immediately after illumination - DR_b rate of dark respiration before illumination - E₀ rate of gross oxygen evolution in the light - NET rate of net oxygen evolution in the light - PFR photon fluence rate - RubP rubulose-1,5-bisphosphate - SHAM salicyl hydroxamic acid - U₀ rate of gross oxygen uptake in the light     

On the relationship between isoprene emission and thermotolerance in Phragmites australis leaves exposed to high temperatures and during the recovery from a heat stress

Thermotolerance induced by isoprene has been assessed during heat bursts but there is little information on the ability of endogenous isoprene to confer thermotolerance under naturally elevated temperature, on the interaction between isoprene-induced thermotolerance and light stress, and on the persistence of this protection in leaves recovering at lower temperatures. Moderately high temperature treatment (38 °C for 1.5 h) reduced photosynthesis, stomatal conductance, and photochemical efficiency of photosystem II in isoprene-emitting, but to a significantly lower extent than in isoprene-inhibited Phragmites australis leaves. Isoprene inhibition and high temperature independently, as well as together, induced lipid peroxidation, increased level of H₂O₂, and increased catalase and peroxidase activities. However, leaves in which isoprene emission was previously inhibited developed stronger oxidative stress under high temperature with respect to isoprene-emitting leaves. The heaviest photosynthetic stress was observed in isoprene-inhibited leaves exposed to the brightest illumination (1500 µmol m⁻² s⁻¹) and, in general, there was also a clear additive effect of light excess on the formation of reactive oxygen species, antioxidant enzymes, and membrane damage. The increased thermotolerance capability of isoprene-emitting leaves may be due to isoprene ability to stabilize membranes or to scavenge reactive oxygen species. Irrespective of the mechanism by which isoprene reduces thermal stress, isoprene-emitting leaves are able to quickly recover after the stress. This may be an important feature for plants coping with frequent and transient temperature changes in nature.     

Modulation of peroxynitrite produced via mitochondrial nitric oxide synthesis during Ca2+ and succinate-induced oxidative stress in cardiac isolated mitochondria

We hypothesized that NO^• is generated in isolated cardiac mitochondria as the source for ONOO⁻ production during oxidative stress. We monitored generation of ONOO⁻ from guinea pig isolated cardiac mitochondria subjected to excess Ca²⁺ uptake before adding succinate and determined if ONOO⁻ production was dependent on a nitric oxide synthase (NOS) located in cardiac mitochondria (mtNOS). Mitochondria were suspended in experimental buffer at pH 7.15, and treated with CaCl₂ and then the complex II substrate Na-succinate, followed by menadione, a quinone redox cycler, to generate O₂^•−. L-tyrosine was added to the mitochondrial suspension where it is oxidized by ONOO⁻ to form dityrosine (diTyr) in proportion to the ONOO⁻ present. We found that exposing mitochondria to excess CaCl₂ before succinate resulted in an increase in diTyr and amplex red fluorescence (H₂O₂) signals, indicating that mitochondrial oxidant stress, induced by elevated mtCa²⁺ and succinate, increased mitochondrial ONOO⁻ production via NO^• and O₂^•−. Changes in mitochondrial ONOO⁻ production dependent on NOS were evidenced by using NOS inhibitors L-NAME/L-NNA, TEMPOL, a superoxide dismutase (SOD) mimetic, and PTIO, a potent global NO^• scavenger. L-NAME and L-NNA decreased succinate and menadione-mediated ONOO⁻ production, PTIO decreased production of ONOO⁻, and TEMPOL decreased ONOO⁻ levels by converting more O₂^•− to H₂O₂. Electron microscopy showed immuno-gold labeled iNOS and nNOS in mitochondria isolated from cardiomyocytes and heart tissue. Western blots demonstrated iNOS and nNOS bands in total heart tissue, bands for both iNOS and nNOS in β-tubulin-free non-purified (crude) mitochondrial preparations, and a prominent iNOS band, but no nNOS band, in purified (Golgi and ER-free) mitochondria. Prior treatment of guinea pigs with lipopolysacharride (LPS) enhanced expression of iNOS in liver mitochondria but not in heart mitochondria. Our results indicate that release of ONOO⁻ into the buffer is dependent both on O₂^•− released from mitochondria and NO^• derived from a mtCa²⁺-inducible nNOS isoform, possibly attached to mitochondria, and a mtNOS isoform like iNOS that is non-inducible.     

The role and mechanism of metal ions and their complexes in enhancing damage in biological systems or in protecting these systems from these systems from the toxicity of O2−

Cooper complexes of 1,10-phenanthroline and some substituted 1,10-phenanthroline cleave DNA in the presence of a reducing agent and molecular oxygen. Generally, the damage is attributed to hydroxyl radicals which are formed through the Haber-Weiss reaction. It is assumed that this reaction occurs with the ternary metal complexes with the biological target and the mechanism is defined as the “site specific mechanism.” In these systems, O₂⁻ drives the cycle through the reduction of copper(II). On the other hand, these same copper complexes catalyze the dismutation of O₂⁻ and thus should protect the systems from O₂⁻ toxicity. In this article, the toxicity of these complexes is explained on kinetic grounds. A general discussion on the various factors which could cause the metal ions or their complexes to act either as protectors from O₂⁻ toxicity or as sensitizers of toxic effects of O₂⁻ is given.     

Redox activity and peroxidase activity associated with the plasma membrane of guard-cell protoplasts

Redox systems have been reported in the plasma membrane of numerous cell types and in cells from various species of higher plant. A search for a redox system in the plasma membrane of guard cells was therefore made in efforts to explain how blue light stimulates stomatal opening, a process which is coupled to guard cell H⁺ efflux and K⁺ uptake. The rates of O₂ uptake by intact guard-cell protoplasts (GCP) of Commelina communis L., in the dark, were monitored in the presence of NAD(P)H since the stimulation of O₂ consumption by reduced pyridine nucleotides is used as an indicator of the presence of a redox system in the plasma membrane. Oxygen consumption by intact GCP increased two- to threefold in the presence of NAD(P)H. The NAD(P)H-stimulation of O₂ uptake was dependent on Mn²⁺ and was stimulated 10- to 15-fold by salicylhydroxamic acid (SHAM). Catalase, cyanide and ascorbate, a superoxide scavenger, all individually inhibited the SHAM-stimulated O₂ uptake. These are all characteristics of peroxidase activity although some of these features have been used to imply the presence of a redox system located in the plasma membrane. High levels of peroxidase activity (using guaiacol as a substrate) were also detected in the GCP and in the supernatant. The activity in the supernatant increased with time indicating that peroxidase was being excreted by the protoplasts. The properties of O₂ uptake by the incubation medium after separation from the protoplasts were similar to those of the protoplast suspension. It is concluded that our observations can be more readily explained by peroxidase activity associated with the plasma membrane and secreted by the GCP than by the presence of a redox system in the plasma membrane of the protoplasts.Abbreviations EDTA ethylenediaminetetraacetic acid - GCP guard cell protoplast - Mes 2-(N-morpholino)ethanesulphonic acid - SHAM salicylhydroxamic acid     

The effect of cholesterol on glycerophosphono- and glycerophosphinocholines. Permeability measurements in lipid vesicles

The kinetics of spontaneous chloride ion efflux and valinomycin-mediated rubidium-86 efflux from vesicles prepared from synthetic phospholipids with carbon-phosphorus linkages were investigated at temperatures above the gel-to-liquid-crystalline phase transition. The rate constants for the movement of chloride and rubidium ions were reduced by incorporation of cholesterol into bilayers of phosphono- and phosphinocholines. Nonisosteric phosphonolipids in which the oxygen was removed from the glycerol side of phosphorus without substitution by a methylene group interacted less with cholesterol than the analogous isosteric derivatives, as judged from the magnitude of the decrease in the rate constants for chloride and rubidium ion efflux. The experiments reported in this study suggest that steric factors in the glycerol side of the phosphorus function are important in phosphatidylcholine-cholesterol interaction. However, the oxygen atom on the choline side of the phosphorus in the phosphatidylcholine molecule is not required for strong phosphatidylcholine-cholesterol interaction, since isosteric glycerophosphinocholines interacted as well as the corresponding isosteric glycerophosphonocholines. Furthermore, steric requirements on the choline side of phosphorus are not important in this interaction since phosphinates whose head-group structures are -P(O⁻)CH₂CH₂N⁺(CH₃)₃ and -P(O⁻)CH₂CH₂CH₂N⁺(CH₃)₃ interacted equally well with cholesterol, as estimated by these permeability studies.     

On the nature of the oxygen uptake in the light by Chondrus crispus. Effects of inhibitors,temperature and light intensity

The nature of the different processes of O₂ uptake involved in the light in the red macroalga Chondrus crispus Stackhouse (Rhodophyta, Gigartinales) was investigated. At limiting CO₂, INH (2.5 mM) did not alter the O₂ uptake rate. Glycolate was not excreted and did not accumulate within the cells. KCN reduced the rate of O₂ uptake in the light by 76% at limiting CO₂ and by 43% at saturating CO₂, but caused > 95% inhibition of O₂ evolution. DCMU (5 μM) totally blocked the photosynthetic electron transport chain, but allowed a residual O₂ uptake of 3.0±0.6 μmol O₂ .h^?1.g^?1 FW, irrespective of the CO₂ concentration. In saturating CO₂, a high light intensity pretreatment significantly stimulated the rate of O₂ uptake compared to net O₂ evolution, suggesting the persistence, in the light, of mitochondrial respiration. Irrespective of the CO₂ concentration, the optimum temperature for O₂ evolution was 17°C whereas dark O₂ uptake increased linearly with temperature. In contrast, O₂ uptake in the light showed an optimum at 17°C in limiting CO₂, and 21–25° C in saturating CO₂; its Q₁₀ was 2.4 at limiting CO₂, a value close to that of RuBP oxygenase, and 3.1 at saturating CO₂, a value close to that of dark respiration. It is concluded that: 1) mitochondrial respiration and Mehler reaction are both involved at all CO₂ concentrations, 2) RuBP oxygenase activity cannot account for more than 45%, and Mehler reaction for less than 20%, of the total O₂ uptake observed in the light at limiting CO₂.     

The gills as an important uptake route for the essential nutrient iron in freshwater rainbow trout Oncorhynchus mykiss

Short-term (3h) acquisition of iron (16 nmol ⁵⁹FeCl₃ l⁻¹) from oxic, alkaline fresh water was assessed in rainbow trout Oncorhynchus mykiss in the presence or absence of a range of iron chelators, all of which had differing binding affinities for ferric iron [100 μmol l⁻¹ of desferrioxamine (DFO), Log₁₀K₁ 32·5; citric acid Log₁₀K₁ 11·9; nitrilotriacetic acid (NTA) Log₁₀K₁ 15·9, CP20 and CP94 (Log₁₀K₁ > 30), as well as humic acid (HA), Log₁₀K₁ 5·04, 5 mg l⁻¹]. In the absence of chelators (control conditions) O. mykiss acquired iron from the water under laboratory lights (wavelength range of the lights 440–650 nm, peak intensity 548–626 nm) via the gill. In these conditions iron uptake onto the gill had a maximum transport capacity (J_max) of 11·2 pmol Fe g⁻¹ h⁻¹ (gill organ mass) and a K_m of 21·3 nmol Fe l⁻¹ h⁻¹. Furthermore, there were two components to iron accumulation into the carcass of these fish, a slow rate of aqueous iron uptake at low concentrations (6–24 nmol Fe l⁻¹), followed by a faster rate of uptake at higher iron concentrations (48–96 nmol Fe l⁻¹), suggesting that the rate-limiting step of iron uptake at low iron concentrations is the apical entry step. O. mykiss also acquired iron in the presence of HA, although the majority of the other chelators prevented iron uptake. Ultraviolet light (354 nm) treatment of Fe-DFO increased iron bioavailability. Results suggest that rainbow trout are able to access either the predicted very low concentrations (picomolar) of ferrous iron present in fresh water or the ferric oxide complexes present in oxic environments. The iron uptake rate measured (0·75 pmol g⁻¹ h⁻¹) would be sufficient to provide a substantial proportion (c. 85%) of the daily iron requirements of growing salmonid fry.     

Chemiluminescent assay of β-D-galactosidase based on indole luminescence

We developed a novel chemiluminescent assay of β-D -galactosidase (β-gal) based on the chemiluminescence of indole. 5-Bromo-4-chloro-3-indolyl-β-D -galactopyranoside (X-gal) was used as a substrate for β-gal and also as a light emitter. X-gal was hydrolysed by β-gal to liberate free indoxyl, followed by oxidation to indigo dye, and simultaneously produces hydrogen peroxide (H₂O₂). H₂O₂ reacts with the residual X-gal in the presence of horseradish peroxidase (HRP) to emit light. The measurable range of β-gal obtained by this method was 6 × 10⁻¹⁴ mol/L to 6 × 10⁻¹¹ mol/L; the detection limit was 3 amol/assay. This chemiluminescent assay could be applied to an enzyme immunoassay of thyroxine using β-gal as the enzyme label. © 1998 John Wiley & Sons, Ltd.     

Kinetic study on the photostability of riboflavin in the presence of barbituric acid

Abstract

The photochemical fate of riboflavin (vitamin B₂) in the presence of barbituric acid was examined employing polarographic detection of dissolved oxygen and steady-state and time-resolved spectroscopy. Under visible light, riboflavin reacts with barbituric acid – the latter being transparent to this type of photo-irradiation – via radicals and reactive oxygen species, such as singlet molecular oxygen [O₂(¹Δ_g)] and superoxide radical anion, which are generated from the excited triplet state of the vitamin. As a result, both the vitamin and barbituric acid are photodegraded. Kinetic and mechanistic studies on the photoreactions of riboflavin in the presence of barbituric acid indicate the excellent quenching ability of the latter towards O₂(¹Δ_g).     

Carbon Dioxide-Induced Oscillations in Fluorescence and Photosynthesis: Role of Thylakoid Membrane Energization in Regulation of Photosystem II Activity

The response of CO₂ fixation to a sudden increase in ambient CO₂ concentration has been investigated in intact leaf tissue from spinach (Spinacia oleracea) using a dual channel infrared gas analyzer. Simultaneous with these measurements, changes in fluorescence emission associated with a weak, modulated measuring beam were recorded. Application of brief (2-3 seconds) dark intervals enabled estimation of the dark fluorescence level (F_o) under both steady state and transient conditions. The degree of suppression of F_o level fluorescence in the light was strongly correlated with nonphotochemical quenching under all conditions. During CO₂-induced oscillations in photosynthesis under 2% O₂ the changes in nonphotochemical quenching anticipate changes in the rate of uptake of CO₂. At such low levels of O₂ and constant illumination, changes in the relative quantum efficiency of open photosystem II units were estimated as the ratio of the rate of CO₂ uptake and the photochemical quenching coefficient. Under the same conditions the relative quantum efficiency of photosystem II was found to vary inversely with the degree of nonphotochemical quenching. The relationship between changes in the rate of CO₂ uptake: photochemical quenching coefficient and nonphotochemical quenching was altered somewhat when the same experiment was conducted under 20% O₂. The results suggest that electron transport coupled to reduction of O₂ occurs to varying degrees with time during oscillations, especially when ambient O₂ concentrations are high.     

Extinction of cells of cyanobacterium Anabaena circinalis in the presence of humic acid under illumination

Laboratory experiments targeting the effect of humic acid (HA) on the cell lysis of cyanobacterium Anabaena circinalis have been performed. Light irradiation was found to be an important factor for the cell lysis phenomenon, whereas intracellular hydrogen peroxide (H₂O₂) might be a chemical factor for the process. An exogenous H₂O₂ concentration of 1.0 mg l⁻¹ was determined as the threshold for cell survival. Our results indicated that HA or its possible product(s) of photochemical reaction can induce damage to intracellular catalase under artificial illumination, which leads intracellular H₂O₂ to be accumulated to an abnormally high concentration, eventually resulting in cell death. Moreover, H₂O₂ released into the culture from dead cells can damage other cells, which in turn brings about the population extinction.     

Physiological reactions of the reversible hydrogenase from anabaena 7120

The reversible hydrogenase from Anabaena 7120 appeared when O₂ was continuously removed from a growing culture. Activity increased further when cells were incubated under argon in the dark or in the light plus 3-(3,4-dichlorophenyl)-1,1-dimethylurea. Hydrogenase existed in an inactive state during periods of O₂ evolution. It could be reductively activated by exposure to reduced methyl viologen or by dark, anaerobic incubation. Hydrogenase-containing cells evolved H₂ slowly during dark anaerobic incubations, and the rate of H₂ evolution was increased by illumination with low intensity light. Light enhancement of H₂ evolution was of short duration and was eliminated by the ferredoxin antagonist disalicylidene diaminopropane. Physiological acceptors that supported H₂ uptake included NO₃⁻, NO₂⁻, and HSO₃⁻, and light had a slight influence on the rate of H₂ uptake with these acceptors. Low levels of O₂ supported H₂ uptake, but higher concentrations of O₂ inactivated the hydrogenase. Hydrogen uptake with HCO₃⁻ as acceptor was the most rapid reaction measured, and it was strictly light-dependent. It occurred only at low light intensities, and higher light intensities restored normal O₂-evolving photosynthesis. It is suggested that hydrogenase is present to capture exogenous H₂ as a source of reducing equivalents during growth in anaerobic environments.     

The effect of pH on the inorganic carbon source for photosynthesis in the seagrass Zostera muelleri irmisch ex aschers

The ability of the seagrass Zostera muelleri Irmisch ex Aschers. to use HCO₃⁻ as well as CO₂ for photosynthesis was investigated by measuring photosynthetic O₂ evolution over a range of pH values. It was found that the apparent K_m CO₂ fell from 0.128 mM at pH 7.9 to 0.016 mM at pH 9.1 indicating that HCO₃⁻ as well as CO₂ may act as a substrate for photosynthesis.The true K_m CO₂ could not be determined due to inhibition of photosynthesis at pHs less than 7.8 K_m CO₂ must be at least 0.128 mM, the apparent K_m at pH 7.9, and is probably of the order of 0.200 mM CO₂, the same as that reported for other marine plants. K_m HCO₃⁻¹ is about 20 mM when CO₂-dependent photosynthesis is minimal. Such a high K_m HCO₃⁻ resembles values reported for freshwater, rather than marine plants.Photosynthetic O₂ evolution is not saturated with respect to total inorganic carbon in natural seawater (pH 8.2). It is suggested that the distinctive shoulder from pH 8.1 to 8.5 in the pH profile of photosynthetic O₂ evolution at a constant concentration of inorganic carbon is caused by an effect of pH on HCO₃⁻ uptake. The effect of pH on HCO₃⁻ uptake was determined by constructing a pH profile of photosynthesis at constant HCO₃⁻ concentration, and subtracting the estimated contribution of CO₂ to photosynthesis from this rate. The resultant curve has a maximum at pH 8.4 and declines sharply at pHs less than 8.