Characterization of extracellular oxygen consumption by the green alga Selenastrum minutum

Cells of the green alga Selenastrum minutum display a high capacity for extra-mitochondrial O₂ consumption in the presence of effectors such as salicylhydroxamic acid and/or NADH. We provide evidence that this O₂ consumption is mediated by extracellular peroxidase. Peroxidase capacity, measured as the potential for stimulation of O₂ consumption by a combination of salicylhydroxamic acid and NADH, changed over a 10-day time course. Maximal stimulation of O₂ consumption occurred at day three, at which point the capacity for peroxidase-mediated O₂ consumption was three-to four-fold higher than that of the control O₂ consumption rate. Peroxidase-mediated O₂ consumption was sensitive to inhibition by 50 m M ascorbate and by cyanide. Cyanide titration curves indicated that O₂ consumption by peroxidase was much more sensitive to inhibition by cyanide than was O₂ consumption by cytochrome oxidase (I₅₀ < 1.6 μ M and I₅₀= 18.3 μ M cyanide, respectively). By using evidence from a combination of cyanide titration curves and ascorbate inhibition, we concluded that despite a large capacity for peroxidase-mediated O₂ consumption, peroxidase did not measurably contribute to control rates of O₂ consumption. In the absence of effectors, O₂ consumption was mediated primarily by cytochrome oxidase.     

Interactions between respiration and inorganic phosphate uptake in phosphate-limited cells of Chlamydomonas reinhardtii

Phosphate addition to P-limited cells of Chlamydomonas reinhardtii resulted in an immediate increase in the rate of respiratory O₂ consumption. The respiration rate continued to increase for several minutes after the addition of P₁. Similar patterns of P₁ stimulation of respiratory O₂ consumption were observed in the presence of cyanide (cytochrome oxidase inhibitor) and propyl gallate (alternative oxidase inhibitor). Stimulation of O₂ consumption was accompanied by rapid changes in levels of glycolytic intermediates. These changes were consistent with activation of ATP-dependent phosphofructokinase and pyruvate kinase. The adenylate pool exhibited only minor perturbations, P₁, uptake resulted in extracellular acidification, which continued for several minutes after the exhaustion of added P₁, whereas exhaustion of extracellular P₁ resulted in a rapid decline in the O₂ consumption rate. These results are consistent with control of respiration in P-limited cells occurring largely at the level of glycolysis.     

Azide-stimulated oxygen consumption by the green alga Selenastrum minutum

Dark O₂ consumption by the green alga Selenastrum minutum was sensitive to inhibition by the cytochrome pathway respiration inhibitor cyanide in the absence of an alternative oxidase inhibitor, consistent with previous work that suggested that this alga lacks alternative oxidase capacity. In contrast, addition of low concentrations of the cytochrome pathway inhibitor azide (50–750 μ M ) resulted in a stimulation of dark O₂ consumption, while higher concentrations of azide (1–2 m M ) partially inhibited O₂ consumption. Measurements of changes in cellular levels of pyruvate, malate and pyridine nucleotides upon cyanide addition were consistent with the absence of alternative oxidase capacity, and suggested that cyanide inhibition of O₂ consumption was not due to nonspecific effects of cyanide. Addition of salicylhydroxamic acid (SHAM) also resulted in an increase in the rate of O₂ consumption. Both azide- and SHAM-stimulated O₂ consumption were sensitive to inhibition by 50 m M ascorbate or by cyanide. However, the ubiquinone analogs chloroquine and quinacrine specifically inhibited azide-stimulated O₂ consumption, with only minor effects on SHAM-stimulated O₂ consumption. These results suggest that azide-stimulated O₂ consumption was not mediated by the previously characterized SHAM-stimulated oxidase, and are consistent with the possibility that azide-stimulated O₂ consumption is mediated by a plasma membrane redox system.     

Coordination of photosynthetic and respiratory metabolism in Chlorella vulgaris UAM 101 in the light

In Chlorella vulgaris UAM 101, the presence of glucose altered the photosynthetic and respiratory metabolism in the light. When glucose was added to the growth medium, an increase in the cellular level of enzymes involved in glucose oxidation, namely glucose-6-P dehydrogenase (EC 1.1.1.49) and NAD⁺-glyceraldehyde-3-P dehydrogenase (EC 1.2.1.12), was observed. Glucose also enhanced respiratory O₂ consumption. In addition, CO₂ released by glucose oxidation was refixed in photosynthesis. The presence of glucose also affected photosynthesis. Phosphoribulokinase (EC 2.7.1.19) and NADP⁺-dependent glyceraldehyde-3-P dehydrogenase (EC 1.2.1.13), two regulatory enzymes of the reductive pentose phosphate cycle, were increased by glucose. However, Rubisco (EC 4.1.1.39) activity of these cells was lower than that of autotrophic cells. Despite these alterations, the photosynthetic O₂ evolution was not significantly inhibited by glucose. On the other hand, an increase in the cytosolic NADP⁺-glyceraldehyde-3-P dehydrogenase (EC 1.2.1.9) that is involved in obtaining reducing power for anabolic processes was observed. The CO₂ levels in the growth medium did not significantly affect the cellular level of enzymes measured in this work, except those involved in biosynthetic pathways. These data suggest that the effect of glucose on photosynthesis and respiration can be explained by alteration of the cellular level of photosynthetic enzymes and respiratory substrates, respectively.     

Salt stress induces a decrease in the oxygen uptake of soybean nodules and in their permeability to oxygen diffusion

The effects of short-term NaCl-salinity on nodules of soybean ( Glycine max L. cv. Kingsoy) were studied on hydroponically-grown plants. Both acetylene reducing activity (ARA) and nodule respiration (O₂ uptake and CO₂ evolution) were immediately inhibited, and the stimulation of them by rising the external partial pressure of O₂ (pO₂) was diminished by the application of 0.1 M NaCl in the nutrient solution. The permeability of the nodule to O₂ diffusion, estimated by O₂ consumption or CO₂ evolution, was significantly lower in the stressed nodules than in the cootrol ones. The respiratory quotient of intact nodules and the ethanol production of excised nodules were increased by low pO₂ and by salt stress. These data confirm that in salt-stressed soybean nodules, O₂ availability is reduced and fermentative pathways are stimulated.     

Evidence that growth hormone-induced elevation in routine metabolism of juvenile Atlantic salmon is a result of increased spontaneous activity

Growth hormone (GH) significantly increased the growth in mass and length of Atlantic salmon parr. It also significantly increased routine oxygen consumption ( M O₂). This change in routine M O₂ could be attributed to an increase in activity, but not resting M O₂. Any elevation in resting M O₂ due to GH treatment is much lower than previously suggested.     

A method for long-term measurement of respiration in intertidal fishes during simulated intertidal conditions

Aquatic and aerial respiration of the amphibious fishes Lipophrys pholis and Periophthalmus barbarus were examined using a newly designed flow-through respirometer system. The system allowed long-term measurements of oxygen consumption and carbon dioxide release during periods of aquatic and aerial respiration. The M o ₂ of L. pholis , measured at 15° C, was 2·1 μmol O₂ g^–1 h^–1 during aquatic and 1·99 μmol O₂ g^–1 h^–1 during aerial exposure. The corresponding values of the M co₂ were 1.67 and 1.59 μmol O₂ g^–1 h^–1 respectively, giving an aquatic respiratory exchange ratio (RER) of 0·80 and an aerial RER of 0·79. The M o₂ of P. barbarus , measured at 28°C, was 4·05 μmol O₂ g^–1 h^–1 during aquatic and 3·44 μmol O₂ g^–1 h^–1 during aerial exposure. The corresponding values of the Mco₂ were 3·29 μmol CO₂ g^–1 h^–1 and 2·63 μmol CO₂ g^–1 h^–1 respectively, giving an aquatic RER of 0·81 and an aerial RER of 0·77. While exposed to air for at least 10 h, both species showed no decrease in metabolic rate or carbon dioxide release. The RER of these fishes equalled their respiratory quotient. After re-immersion an increased oxygen consumption, due to the payment of an oxygen debt, could not be detected.     

Scaling of oxygen consumption of Lake Magadi tilapia, a fish living at 37°C

Rates of oxygen consumption were measured in the geothermal, hot spring fish, Oreochromis alcalicus grahami by stopped flow respirometry. At 37° C, routine oxygen consumption followed the allometric relationship: V o₂=0.738 M ^0.75, where V o₂ is ml O₂ h ⁻¹ and M is body mass (g). This represents a routine metabolic rate for a 10 g fish at 37° C of 0.415 ml O₂ g⁻¹ h ⁻¹ (16.4 μmol O₂ g ⁻¹ h ⁻¹). Acutely increasing the temperature from 37 to 42° C significantly elevated the rate of O₂ consumption from 0.739 to 0.970 ml O₂ g ⁻¹ h ⁻¹ ( Q ₁₀=l.72). In the field, O. a. grahami was observed to be 'gulping' air from the surface of the water especially in hot springs that exceeded 40° C. O. a. grahami may utilize aerial respiration when O₂ requirements are high.     

Oxygen control prevents denitrifiers and barley plant roots from directly competing for nitrate

Abstract Two denitrifying bacteria ( Pseudomonas chlororaphis and P. aureofaciens ) and a plant (barley, Hordeum vulgare ) were used to study the effect of O₂ concentration on denitrification and NO₃⁻ uptake by roots under well-defined aeration conditions. Bacterial cells in the early stationary phase were kept in a chemostat vessel with vigorous stirring and thus a uniform O₂ concentration in the solution. Both Pseudomonads lacked N₂O reductase and so total denitrification could be directly measured as N₂O production.
Denitrification decreased to 6–13% of the anaerobic rate at 0.01% O₂ saturation (0.14 μM O₂) and was totally inhibited at 0.04% O₂ saturation (0.56 μM O₂). In this well-mixed system denitrification was 10-times more oxygen sensitive than stated in earlier reports. Uptake of nitrate by plants was measured in the same system under light. The NO₃⁻ uptake rate decreased gradually from a maximum in 21% O₂-saturated medium (air saturated) to zero at 1.6% O₂ saturation (22.4 μM O₂). Owing to the very different non-overlapping oxygen requirements of the two processes, direct competition for nitrate between plant roots and denitrifying bacteria cannot occur.     

Hydrogen Production by Rumen Holotrich Protozoa: Effects of Oxygen and Implications for Metabolic Control by In Situ Conditions

Experiments with washed suspensions of holotrich protozoa (Isotricha spp. and Dasytricha ruminantium ) showed that both organisms have an efficient 0,-scavenging capability (apparent K_m values 2.3 and 0.3 μM, respectively). Reversible inhibition of H₂, production increased almost linearly with increasing O₂ up to 1.5 μM; higher levels of O₂ gave irreversible inhibition. In situ determinations of H, CH₄, O₂, and CO₂, in ovine rumen liquor, using a membrane inlet mass spectrometer probe, indicated that O₂, was present before feeding at 1-1.5 μM and decreased to undetectable levels (<0.25 μM) within 25 min after feeding. A transient increase in O₂. concentration after feeding occurred only in defaunated animals and resulted in suppression of CH₄ and CO₂ production. The presence of washed holotrich protozoa decreases the O₂ sensitivity of CH₄ production by suspensions of a cultured methanogenic bacterium Methanosarcina barkeri . It is concluded that holotrich protozoa play a role in ruminal O₂ utilization as well as in the production of fermentation end products (especially short-chain volatile fatty acids) utilized by the ruminant and H, utilized by methanogenic bacteria. These hydrogenosome-containing protozoa thus both control patterns of fermentation by influencing O₂ levels, and are themselves regulated by the low ambient O₂ concentrations they experience in the rumen.     

Salicylhydroxamic acid-stimulated NADH oxidation by purified plasmalemma vesicles from wheat roots

Purified, right side-out plasmalemma vesicles were isolated from 7-day-old roots of dark-grown wheat ( Triticum aestivum L. cv. Drabant) by aqueous polymer two-phase partitioning. The oxygen consumption by these vesicles at pH 6.5 in the presence of 1 m M NADH [12–29 nmol (mg protein)⁻¹min⁻¹] was 66% inhibited by 1 m M KCN and ca 40% by 1 m M EDTA. It was unaffected by rotenone, antimycin A, carbonyl cyanide trifluoromethoxyphenylhydrazone (FCCP), mersalyl, chlorotetracycline + Ca²⁺, and EGTA. Salicylhydroxamic acid (SHAM) and its analogue, m -chlorobenzhydroxamic acid, stimulated the rate of oxygen consumption 10–20 fold in the presence of 1 m M NAD(P)H with an apparent K_m (SHAM) of ca 40 μ M (with NADH). The dependence of O₂ consumption on NADH concentration in the presence of SHAM (2 m M ) was sigmoidal, possibly due to endogenous catalase activity, and half-maximal rate was obtained at 1.5 m M . In the absence of SHAM the rate increased with increasing acidity and no pH optimum was detectable between pH 4.5 and 8.5. In the presence of SHAM an optimum was observed at pH 6.5 and 0.8 mol of H₂O₂ was produced for every 1 mol O₂ consumed. Endogenous catalase converted this H₂O₂ to O₂ and after complete conversion the stoichiometry was 2 mol NADH consumed for every mol O₃. SHAM was not consumed in the reaction. The possible involvement of a cytochrome P-450/420 system is discussed.     

Swimming performance, oxygen consumption and excess post-exercise oxygen consumption in adult transgenic and ocean-ranched coho salmon

Routine oxygen consumption ( M o ₂) was 35% higher in 1 day starved and 21% higher in 4 day starved adult transgenic coho salmon Oncorhynchus kisutch relative to end of migration ocean-ranched coho salmon. Critical swimming speed ( U _crit) and M o ₂ at U _crit ( M o _2max) were significantly lower in 4 day starved transgenic coho salmon (1·25 BL s⁻¹; 8·79 mg O₂ kg⁻¹ min⁻¹) compared to ocean-ranched coho salmon (1·60 BL s⁻¹; 9·87 mg O₂ kg⁻¹ min⁻¹). Transgenic fish swam energetically less efficiently than ocean-ranched fish, as indicated by a poorer swimming economy at U _crit ( M o _2max     ). Although M o _2max was lower in transgenic coho salmon, the excess post-exercise oxygen consumption (EPOC) measured during the first 20 min of recovery was significantly larger in transgenic coho salmon (44·1 mg O₂ kg⁻¹) compared with ocean-ranched coho salmon (34·2 mg O₂ kg⁻¹), which had a faster rate of recovery.     

Effects of graded hypoxia on Atlantic salmon infected with amoebic gill disease

Atlantic salmon Salmo salar with amoebic gill disease (AGD) were exposed to a graded hypoxia (135–40 mmHg water P O₂) and blood samples analysed for respiratory gases and pH at 119, 79·5 and 40 mmHg water P O₂. There were no differences in the rate of oxygen uptake between infected and control fish. However, arterial P O₂, and pH were significantly lower in the infected fish whereas P CO₂ was significantly higher in infected fish compared with controls prior to hypoxia and at 119 mmHg water P O₂. At 79·5 and 40 mmHg water P O₂ saturation, there were no significant differences in blood P O₂ or pH although blood P CO₂ was elevated in AGD affected fish at 50% hypoxia (79·5 mmHg water P O₂). The elevated levels of P CO₂ in fish affected by AGD resulted in a persistent respiratory acidosis even during hypoxic challenge. These data suggest that even though the fish were severely affected by AGD, the presence of AGD while impairing gas transfer under normoxic conditions, did not contribute to respiratory failure during hypoxia.     

Kinetics of leaf oxygen uptake represent in planta activities of respiratory electron transport and terminal oxidases

We present, for the first time, the oxygen response kinetics of mitochondrial respiration measured in intact leaves (sunflower and aspen). Low O₂ concentrations in N₂ (9–1500 ppm) were preset in a flow-through gas exchange measurement system, and the decrease in O₂ concentration and the increase in CO₂ concentration as result of leaf respiration were measured by a zirconium cell O₂ analyser and infrared-absorption CO₂ analyser, respectively. The low O₂ concentrations little influenced the rate of CO₂ evolution during the 60-s exposure. The initial slope of the O₂ uptake curve on the dissolved O₂ concentration basis was relatively constant in leaves of a single species, 1.5 mm s⁻¹ in sunflower and 1.8 mm s⁻¹ in aspen. The apparent K _0.5(O₂) values ranged from 0.33 to 0.67 μ M in sunflower and from 0.33 to 1.1 μ M in aspen, mainly because of the variation of the maximum rate, V _max (leaf temperature 22°C). The initial slope of the O₂ response of respiration characterizes the catalytic efficiency of terminal oxidases, an important parameter of the respiratory machinery in leaves. The plateau of the response characterizes the activity of the mitochondrial electron transport chain and is subject to regulations in accordance with the necessity for ATP production. The relatively low oxygen conductivity of terminal oxidases means that in leaves, less than 10% of the photosynthetic oxygen can be reassimilated by mitochondria.     

EXTRACELLULAR PEROXIDASE-MEDIATED OXYGEN CONSUMPTION IN CHLAMYDOMONAS REINHARDTII (CHLOROPHYTA)1

The unicellular green alga Chlamydomonas reinhardtii Dang. displays a high capacity for salicylhydroxamic acid (SHAM)—stimulated O₂ consumption, mediated by extracellular peroxidaie. Addition of exogenous NADH also resulted in stimulation of O₂ consumption. The SHAM-and NADH-stimulated peroxidase activity was partially sensitive to inhibition by exogenous superoxide dismutase, ascorbate, and gentisic acid. These compounds did not inhibit O₂ consumption in the absence of effectors. SHAM-and NADH-stimulated peroxidase activity also was sensitive to inhibition by cyanide, and cyanide titration curves indicated that O₂ consumption by peroxidase was more cyanide-sensitive than O₂ consumption by cytochrome oxidase. The differential sensitivity to cyanide was used to estimate partitioning of O₂ consumption between mitochondrial respiration and extracellular peroxidase. We suggest that, despite a large capacity for peroxidase-me-diated O₂ consumption, peroxidase did not consume O₂ at detectable rates in the absence of effectors. Therefore, in the absence of effectors, measured rates of O₂ consumption represented the rate of mitochondrial respiration .     

Thiamine Deficiency in Cultured Neuroblastoma Cells: Effect on Mitochondrial Function and Peripheral Benzodiazepine Receptors

Abstract: When neuroblastoma cells were transferred to a medium of low (6 n M ) thiamine concentration, a 16-fold decrease in total intracellular thiamine content occurred within 8 days. Respiration and ATP levels were only slightly affected, but addition of a thiamine transport inhibitor (amprolium) decreased ATP content and increased lactate production. Oxygen consumption became low and insensitive to oligomycin and uncouplers. At least 25% of mitochondria were swollen and electron translucent. Cell mortality increased to 75% within 5 days. [³H]PK 11195, a specific ligand of peripheral benzodiazepine receptors (located in the outer mitochondrial membrane) binds to the cells with high affinity ( K _D = 1.4 ± 0.2 n M ). Thiamine deficiency leads to an increase in both B _max and K _D. Changes in binding parameters for peripheral benzodiazepine receptors may be related to structural or permeability changes in mitochondrial outer membranes. In addition to the high-affinity (nanomolar range) binding site for peripheral benzodiazepine ligands, there is a low-affinity (micromolar range) saturable binding for PK 11195. At micromolar concentrations, peripheral benzodiazepines inhibit thiamine uptake by the cells. Altogether, our results suggest that impairment of oxidative metabolism, followed by mitochondrial swelling and disorganization of cristae, is the main cause of cell mortality in severely thiamine-deficient neuroblastoma cells.     

OXYGEN CONSUMPTION ASSOCIATED WITH FERRIC REDUCTASE ACTIVITY AND IRON UPTAKE BY IRON-LIMITED CELLS OF CHLORELLA KESSLERI (CHLOROPHYCEAE)

Plasma membrane ferric reductase activity was enhanced 5-fold under iron limitation in the unicellular green alga Chlorella kessleri Fott et Nováková. Furthermore, ferric reductase activity in iron-limited cells was approximately 50% higher in the light than in the dark. In contrast, iron uptake rates of iron-limited cells were unaffected by light versus dark treatments. Rates of iron uptake were much lower than rates of ferric reduction, averaging approximately 2% of the dark ferric reduction rate. Ferric reduction was associated with an increased rate of O₂ consumption in both light and dark, the increase in the light being approximately 1.5 times as large as in the dark. The increased rate of O₂ consumption could be decreased by half by the addition of catalase, indicating that H₂O₂ is the product of the O₂ consumption and that the increased O₂ consumption is nonrespiratory. The stimulation of O₂ consumption was almost completely abolished by the addition of bathophenanthroline disulfonate, a strong chelator of Fe^{2 +} . Anaerobic conditions or the presence of exogenous superoxide dismutase affected neither ferric reduction nor iron uptake. We suggest that the O₂ consumption associated with ferric reductase activity resulted from superoxide formation from the aerobic oxidation of Fe^{2 +} , which is the product of ferric reductase activity. At saturating concentrations of Fe^{3 +} chelates, ferric reductase activity is much greater than the iron uptake rate, leading to rapid oxidation of Fe^{2 +} and superoxide generation. Therefore, O₂ consumption is not an integral part of the iron assimilation process.     

Field estimates of oxygen consumption for the brine shrimp Parartemia zietziana Sayce (Crustacea: Anostraca) in two salt lakes in Victoria, Australia

SUMMARY. Oxygen consumption of P. zietziana was measured monthly in two saline (>60‰ salinity) lakes from November 1973 to November 1975 with short (<2 h) in situ incubations in BOD bottles. Tests in which oxygen decline was monitored continuously showed that there was no handling effect and respiratory rate was constant down to 1.8–1.9 mg O₂ 1⁻¹, about 40% of the usual initial concentration. Incubations over 24 h demonstrated no diurnal fluctuations in oxygen consumption. Multiple regression analysis indicated that 90% of the variance in respiratory rate ( R in mg O₂x10⁻⁴h⁻¹ individual⁻¹) was accounted for by changes in salinity (3%; S in ‰), temperature (7%; T in °C) and dry weight (8%; W in mg × 10⁻³): log R =−1.123+0.0025+0.021 T+ 0.756 log W. From this equation and data on population density, population respiration was calculated: 91864.5 mg O₂ m⁻² year⁻¹ in Pink Lake and 12367.5 mg O₂ m⁻²year⁻¹ in Lake Cundare.     

Oxygen uptake in coprophilous beetles (Aphodius, Geotrupes, Sphaeridium) at low oxygen and high carbon dioxide concentrations

Abstract. The rate of O₂ consumption was measured in five coprophilous beetle species (common in Denmark) at O₂ concentrations from 1–21%. With the exception of the mainly soil-living Geotrupes spiniger (Marsham) (Geotrupidae), these beetles are probably exposed to severe hypoxia in fresh cattle pats. Aphodius fossor (Linnaeus), A. contaminatus (Herbst) (Aphodiidae) and Sphaeridium lunatum Fabricius (Hydrophilidae) maintained normal movements and a normal rate of 0₂ uptake (for at least 30 min) at only 1% O₂. There is no evidence, therefore, that the beetles switch to anaerobic metabolism under these conditions. This ability to regulate respiration, and hence to extract 0₂ at very low concentrations, is exceptional even among terrestrial arthropods living in soil or other potentially hypoxic substrates. In A. rufipes (Linnaeus), respiration declined at ambient concentrations below 2% O₂, and in G. spiniger the ability to regulate respiration seemed to fail at even higher concentrations. In four of the species (G. spiniger was not tested), about 11% CO₂ (the level in a dung pat at 2% O₂) did not affect the O₂ uptake at 2% O₂.     

Oxygen Consumption of Coccidial Sporozoites During in Vitro Excystation

SYNOPSIS. Oxygen consumption of sporozoites of Eimeria acervulina, E. necatrix , and E. meleagrimitis was determined during in vitro excystation. Increase in O₂ consumption occurred only when the permeability of the oocyst membrane was altered by either grinding or incubation in cystine buffer with CO₂ when excystation fluid was present. Addition of 10⁻³ M KCN completely inhibited respiration. The O₂ consumption reached a peak during the time the sporozoites were excysting, and then decreased to a lower level where it remained steady while the sporozoites were awaiting stimulus to penetrate host cells.