The relationship between ETS (electron transport system) activity and oxygen consumption in lake plankton: a cross-system calibration

The ETS (electron transport system) assay to measure respirationof aquatic organisms has been widely applied in studies of marinemetabolism, but its use in freshwaters has been much more limited.This method calculates oxygen consumption from the measuredETS activity using an empirical conversion factor. This factorhas been calculated for various marine organisms, and for naturalplankton communities, but calibrations for freshwater organismsare lacking. The aim of this paper was to determine the relationshipbetween lake plankton respiration and ETS activity, based onmeasured epilimnetic plankton oxygen uptake and ELS activityin 20 southern Quebéc lakes. The relationship betweenplankton oxygen consumption and ETS varies significantly bothwithin lakes over the growing season, and among lakes. The magnitudeof the error associated with calculating respiration from ETSis, however, similar to the error in other standard limnologicalprocedures used in plankton carbon flow studies. Oxygen consumptionis not a linear function of ETS across the range of lakes, butis rather a power function. The respiration:ETS ratio for lakeplankton therefore not constant: it is high in oligotrophicand colored lakes, and declines with trophy. These results areconsistent with the changes expected in the structure of theplankton along trophic gradients.     

Monitoring oxygen consumption of single mouse embryos using an integrated electrochemical microdevice

Oxygen consumption (respiration activity) has been found to be the most remarkable criterion for determining the viability of an embryo produced in vitro. In this study, we propose an accurate, simple, and user-friendly device for measurement of the oxygen consumption of single mammalian embryos. An integrated electrode array was fabricated to determine the oxygen consumption of a single embryo, including the blastocyst stage, which has an inhomogeneous oxygen consumption rate, using a single measurement procedure. A single mouse embryo was positioned in a microwell at the center of an integrated electrode array, using a mouthpiece pipette, and immobilized by a cylindrical micropit with good reproducibility. The oxygen consumption of two-cell, morula, and blastocyst stages was measured amperometrically using the device. The recorded current profile was corrected to take into consideration transient background current during the measurement. A calculation method for oxygen consumption based on spherical diffusion centered on the defined point of the device was developed. This procedure is quite simple because it is not necessary to estimate the radius of the embryo being measured. The calculated values of oxygen consumption for two-cell, morula, and blastocyst stages were 1.36 ± 0.33 × 10⁻¹⁵ mol s⁻¹, 1.38 ± 0.58 × 10⁻¹⁵ mol s⁻¹, and 3.44 ± 2.07 × 10⁻¹⁵ mol s⁻¹, respectively. The increasing pattern of oxygen consumption from morula to blastocyst agreed well with measurements obtained using conventional scanning electrochemical microscopy (SECM).     

Oxygen consumption by Nephrops norvegicus (L.), (Crustacea: Decapoda) in relationship with its moulting stage

The study of the rate of oxygen consumption by Nephrops norvegicius (L.) at each moulting stage has been carried out in closed respiration chambers, using an oxygen electrode to measure the oxygen concentration.Although the mean respiration rate seems to be low when compared with other decapod crustaceans of similar weight, the general trends of the variation of the oxygen consumption during the moulting cycle are similar to those described for other species of decapods. It should be noted that, during the process of the ecdysis, there is no oxygen consumption.     

A sensitive method for measuring oxygen consumption

A technique is presented whereby oxygen consumption rates of the order of 10⁻⁶ μl/hr can be measured, thus providing a means for studying the respiration rates of single cells, even slowly respiring ones. The technique is based on the principle of incubating cells in extremely small chambers containing highly concentrated hemoglobin solutions. The absorbance shift occurring when hemoglobin is transformed from its oxygenated to its deoxygenated form is recorded microspectrophotometrically. The results obtained by this technique seem to be well in accordance with those of the Warburg manometric method. The technique is convenient and easy to handle and the sensitivity can be varied within wide limits, permitting different types of materials to be studied. In experiments using yeast cells, respiration rates from 1.0 × 10⁻⁶ to 1.8 × 10⁻⁶ μl O₂/cell/hr were revealed.     

The oxygen transfer rate as key parameter for the characterization of<Emphasis Type="Italic"> Hansenula polymorpha</Emphasis> screening cultures

Screening cultures are usually non-monitored and non-controlled due to a lack of appropriate measuring techniques. A new device for online measurement of oxygen transfer rate (OTR) in shaking-flask cultures was used for monitoring the screening of Hansenula polymorpha. A shaking frequency of 300 rpm and a filling volume of 20 ml in 250-ml flasks ensured a sufficient oxygen transfer capacity of 0.032 mol (l h)^–1 and thus a respiration not limited by oxygen. Medium buffered with 0.01 mol phosphate l^–1 (pH 6.0) resulted in pH-inhibited respiration, whereas buffering with 0.12 mol phosphate l^–1 (pH 4.1) resulted in respiration that was not inhibited by pH. The ammonium demand was balanced by establishing fixed relations between oxygen, ammonium, and glycerol consumption with 0.245±0.015 mol ammonium per mol glycerol. Plate precultures with complex glucose medium reduced the specific growth rate coefficient to 0.18 h^–1 in subsequent cultures with minimal glycerol medium. The specific growth rate coefficient increased to 0.26 h^–1 when exponentially growing precultures with minimal glycerol medium were used for inoculation. Changes in biomass, glycerol, ammonium, and pH over time were simulated on the basis of oxygen consumption.     

THE OXYGEN CONSUMPTION OF LUMINOUS BACTERIA

Oxygen consumption of luminous bacteria determined by the Thunberg micro respirometer and by the time which elapses before the luminescence of an emulsion of luminous bacteria in sea water begins to dim, when over 99 per cent of the dissolved oxygen has been consumed, agree exactly. Average values for oxygen consumption at an average temperature of 21.5°C. are 4.26 x 10^–11 mg. O₂ per bacterium; 2.5 x 10⁴ mg. per kilo and 5.6 mg. O₂ per sq. m. of bacterial surface. The only correct comparison of the oxygen consumption of different organisms or tissues is in terms of oxygen used per unit weight with a sufficient oxygen tension so that oxygen consumption is independent of oxygen tension. Measurement of the oxygen concentration which just allows full luminescence, compared with a calculation of the oxygen concentration at the surface of a bacterial cell just necessary to allow the observed respiration throughout all parts of the cell, indicates that oxygen must diffuse into the bacterium much more slowly than through gelatin or connective tissue but not as slowly as through chitin.     

New and Fast Method To Quantify Respiration Rates of Bacterial and Plankton Communities in Freshwater Ecosystems by Using Optical Oxygen Sensor Spots

A new method of respiration rate measurement based on oxygen luminescence quenching in sensor spots was evaluated for the first time for aquatic bacterial communities. The commonly used Winkler and Clark electrode methods to quantify oxygen concentration both require long incubation times, and the latter additionally causes signal drift due to oxygen consumption at the cathode. The sensor spots proved to be advantageous over those methods in terms of precise and quick oxygen measurements in natural bacterial communities, guaranteeing a respiration rate estimate during a time interval short enough to neglect variations in organism composition, abundance, and activity. Furthermore, no signal drift occurs during measurements, and respiration rate measurements are reliable even at low temperatures and low oxygen consumption rates. Both a natural bacterioplankton sample and a bacterial isolate from a eutrophic river were evaluated in order to optimize the new method for aquatic microorganisms. A minimum abundance of 2.2 × 10⁶ respiring cells ml⁻¹ of a bacterial isolate was sufficient to obtain a distinct oxygen depletion signal within 20 min at 20°C with the new oxygen sensor spot method. Thus, a culture of a bacterial isolate from a eutrophic river (OW 144; 20 × 10⁶ respiring bacteria ml⁻¹) decreased the oxygen saturation about 8% within 20 min. The natural bacterioplankton sample respired 2.8% from initially 94% oxygen-saturated water in 30 min. During the growth season in 2005, the planktonic community of a eutrophic river consumed between 0.7 and 15.6 μmol O₂ liter⁻¹ h⁻¹. The contribution of bacterial respiration to the total plankton community oxygen consumption varied seasonally between 11 and 100%.     

Photosynthesis and respiration in a fast growing strain of Gigartina exasperata (Harvey and Bailey)

Photosynthesis and respiration rates of blades from a selected, fast growing strain of the marine red alga. Gigartina exasperata Harvey and Bailey, a carrageenan producer, were measured with an oxygen electrode and compared with rates similarly obtained from wild material of the same species. The measurements, expressed as μl O₂ · mg chl a^?1, min^?1. were made over a light intensity range from 5 to 800 μE · m^?2 · sec^?1 and a temperature range of 6 to 16°C. The photosynthesis light intensity data are best described by hyperbolic functions.     

Entamoeba histolytica. I. Aerobic metabolism

The respiration of intact trophozoites harvested from axenic cultures of Entamoeba histolytica was studied with the polarographic technique utilizing the Clark oxygen electrode. A typical Q_o2 value for the freshly harvested amebae was 1 μatom oxygen/mg protein/hr.It was conclusively demonstrated that this parasite, a putative anaerobe, not only consumes oxygen when provided, but has a high affinity for the gas.Added glucose, galactose, and ethanol increased the respiratory rates, whereas other carbohydrates were without effect on the endogenous respiration. Intermediates of the tricarboxylic acid cycle, amino and fatty acids did not stimulate the respiration of E. histolytica.Inhibitors of the mammalian respiratory chain (cyanide, antimycin) as well as agents that inhibit enzymes catalyzing the tricarboxylic acid cycle (malonate, fluoropyruvate, fluoroacetate, fluorocitrate) had little effect on the endogenous or glucose-supported respiration. Alkylating agents (iodoacetamide, iodoacetate), cinnamate, and N-ethylymaleimide strongly inhibited the oxygen consumption of E. histolytica. The chemotherapeutic agents, Paromomycin, Emetine and Metronidazole, at concentrations that inhibit growth in vitro, did not restrict the respiration.Storage of the trophozoites at 4 C led to progressive deterioraion of the parasites and loss of endogenous and glucose-supported respiration. The deterioration was paralled by loss of SH-materials from the amebae. Likewise, sonication or lysis with detergents abolished both the endogenous respiration and response to glucose.Exogenous NADH or NADPH evoked only marginal increases in oxygen consumption of the freshly harvested amebae, but were effective respiratory substrates with stored or sonicated organisms. Addition of vitamin K₃ greatly enhanced the endogenous and glucose-supported respiration of the intact amebae, as well as enhancing the response of stored or sonicated amebae to reduced pyridine nucleotides.     

Meiobenthos and the oxygen budget of an intertidal sand beach

Field and laboratory experiments are used to construct a partial oxygen budget for a typical fine sand area just above mean tide level in Strangford Lough, Northern Ireland. Oxygen consumption was determined mainly from batch respiration using a YSI electrode. Experiments with different batch sizes indicate that oxygen uptake rate per individual decreased as the number in the test chamber increased. Experiments conducted monthly at ambient environmental temperature with batches of 40 individuals show minimum oxygen consumption occurred at 12 °C in the nematode, copepod and turbellarian populations tested.Modelling the situation for 1 m² of beach in November 1979 gives a meiofaunal demand from 295,250 individuals of a total 40 ml O₂ . h^–1 compared with an estimated 2760 for macrofauna and 1172 for sediment with attached microorganisms. Microfloral production was calculated as 324 ml O₂ . h^–1 in light. The individual meiofaunal respiration values are much higher than those previously reported. The reasons for this and the confidence which can be attached to these and other workers results are discussed. Information from laboratory and field results is used to construct a partial oxygen budget for a typical fine sand area just above mid-tide level in Strangford Lough, Northern Ireland. Oxygen consumption by meiofaunal taxa and Hydrobia was determined from batch respiration experiments using a YSI oxygen electrode, as was consumption and production by sediment with attached microflora. Experiments conducted monthly at ambient temperature indicate minimum oxygen consumption at 12 ° C in the nematode, copepod and turbellarian (Monocelopsis sp.) population tested. Batch size affected consumption; with nematodes, copepods and gastrotrichs (Turbanella varians) uptake per individual decreased as number in the test chamber increased. Later experiments were therefore conducted with a standard batch size of 40 individuals.Inspection of biological and physical data showed conditions in November 1979 were close to the annual mean. Using these and the appropriate laboratory data the calculated values give a meiofaunal oxygen demand per m² of beach of 40 ml h^–1 compared with an estimated 2760 for the macrofauna and 1172 for the sediment with attached micro-organisms. Microfloral oxygen production was 324 ml h^–1 in light. The meiofaunal figures are based on a population of 295,250 individuals per m² with a percentage composition of Nematoda 58.2, Copepoda 22.7, Gastrotricha 14.4, Turbellaria 5.3 and Gnasthostomulida 1.3. These figures give a relative population oxygen uptake of 50.1 : 32.3 : 5.1 : 9.9 : 2.7% respectively. The confidence which can be attached to these and other workers results is discussed.     

In situ analysis of oxygen consumption and diffusive transport in high‐temperature acidic iron‐oxide microbial mats

The role of dissolved oxygen as a principal electron acceptor for microbial metabolism was investigated within Fe(III)‐oxide microbial mats that form in acidic geothermal springs of Yellowstone National Park (USA). Specific goals of the study were to measure and model dissolved oxygen profiles within high‐temperature (65–75°C) acidic (pH = 2.7–3.8) Fe(III)‐oxide microbial mats, and correlate the abundance of aerobic, iron‐oxidizing Metallosphaera yellowstonensis organisms and mRNA gene expression levels to Fe(II)‐oxidizing habitats shown to consume oxygen. In situ oxygen microprofiles were obtained perpendicular to the direction of convective flow across the aqueous phase/Fe(III)‐oxide microbial mat interface using oxygen microsensors. Dissolved oxygen concentrations dropped from ～ 50–60 μM in the bulk‐fluid/mat surface to below detection (< 0.3 μM) at a depth of ～ 700 μm (～ 10% of the total mat depth). Net areal oxygen fluxes into the microbial mats were estimated to range from 1.4–1.6 × 10^?4 μmol cm^?2 s^?1. Dimensionless parameters were used to model dissolved oxygen profiles and establish that mass transfer rates limit the oxygen consumption. A zone of higher dissolved oxygen at the mat surface promotes Fe(III)‐oxide biomineralization, which was supported using molecular analysis of Metallosphaera yellowstonensis 16S rRNA gene copy numbers and mRNA expression of haem Cu oxidases (FoxA) associated with Fe(II)‐oxidation.     

The effect of CdCl2 on the respiration of rat small intestine mucosa

Process of oxygen consumption of rat small intestine have already been studied at the level of whole intestinal wall or mucosa only by means of manometric or polarographic methods. The influence of cadmium on mucosal respiration of three sections of rat small intestine was determined because of its toxicological importance. Oxygen consumption was measured polarographically with Clark electrode at 38 degrees C in Krebs Ringer phosphate medium with 0.011 mol/l glucose. Control as well as cadmium affected respiration values were measured one after the other on the same mucosa. High cadmium concentration (applied as CdCl2) that is 2.2 and 1.4 . 10(-2) mol/l significantly inhibited the respiration in duodenum, jejunum and ileum. Observed inhibition of 80 and 50% on the average approximately for these two concentrations was related (similarly as following effects) to 100% value of control respiration. Concentrations 7.8 and 4.5. 10(-3) mol/l caused mostly lower inhibition of oxygen consumption (with the exception of significant 53% inhibition of jejunal respiration for 7.8. 10(-3) mol/l CdCl2). Low concentrations 10(-4) - 10(-6) mol/l CdCl2 had either no effect or stimulated oxygen uptake in intestinal mucosa. In older rats (weight 300-350 g) the respiration of duodenal and jejunal mucosa was inhibited with cadmium chloride concentration of 10(-6) mol/l.     

Oxygen consumption in active and quiescent protonymphs of the American house-dust mite

Oxygen consumption in protonymphs of the American house-dust mite was measured by the Cartesian diver technique. Active protonymphs consumed 1.14 × 10^?2 μl/hr/mite under close to optimum temperature and humidity conditions for the species. This consumption is higher than that reported for fasting non-reproducing females. The protonymphs were active when confined in the diver and exhausted their energy reserves in less than 20 hr. Quiescent protonymphs consumed 4 × 10^?4 μl/hr/mite of oxygen, which is 28 times less than the consumption of active mites. The quiescence was not a static state, disturbed quiescent protonymphs had a six times higher oxygen consumption. This additional energy is thought to be spent in repair of injuries caused by collecting, e.g. secretion of wax on places where the layer has been removed.     

Factors affecting the respiration of rabbit sperm measured with an oxygen electrode

The respiration of rabbit sperm was measured by a Clarke type electrode which has two advantages over the conventional Warburg technique, greater sensitivity, and no necessity for a carbon dioxide-free atmosphere. It was not necessary to resaturate the sample chamber of the oxygen monitor with air, down to about 30% desaturation.Rabbit seminal plasma had a measurable oxygen uptake (0.6 μl/hr/ml) but this was much less than for human seminal plasma (4.3 μl/hr/ml). Hoderate dilution of the sperm and storing the semen at 0°C after slow cooling had no effect on oxygen uptake. Unlike those of most other species, rabbit sperm were also little affected by deliberate exposure to cold shock and the respiration before and after rapid cooling to 0°C was about the same. On the other hand very brief exposure of rabbit sperm to 65°C abolished motility and greatly reduced the respiration rate. Bicarbonate (6 mM) stimulated the oxygen uptake of freshly collected samples of rabbit sperm after washing. Increasing the phosphate concentration of the medium to 80 mM did not greatly depress the oxygen uptake.     

A sensitive measurement of oxygen uptake rate using a optochemical sensor

Summary The measurement of the specific oxygen uptake rate (OUR) of slow growing organisms using a small sample size is often hampered by the consumption of oxygen by the electrode used. Using a optochemical sensor we measured the OUR of carrot embryos with approximately 1000 cell clusters and of hybridoma with approximately 10⁶ cells. An OUR as low as 0.02 mol/h can be accurately measured.     

Oxygen consumption and energy metabolism of the early mouse embryo

Oxygen consumption of preimplantation and early postimplantation mouse embryos has been measured using a novel noninvasive ultramicrofluorescence technique, based on an oil-soluble, nontoxic quaternary benzoid compound pyrene, whose fluorescence is quenched in the presence of oxygen. Pyruvate and glucose consumption, lactate production, and glycogen formation from glucose were also measured. Preimplantation mouse embryos of the strain CBA/Ca × C57BL/6 were cultured in groups of 10–30 in 2 μl of modified M2 medium containing 1 mmol l⁻¹ glucose, 0 mmol l⁻¹ lactate, and 0.33 mmol l⁻¹ pyruvate, for between 4–6 hr. Day 6.5 and 7.5 embryos were cultured singly in 40 μl M2 medium for between 2–3 hr. Oxygen consumption was detected at all stages of development, including, for the first time, in the early postimplantation embryo. Consumption remained relatively constant from zygote to morula stages before increasing in the blastocyst and day 6.5–7.5 stages. When expressed as QO₂ (μl/mg dry weight/hr), oxygen consumption was relatively constant from the one-cell to morula stages before increasing sharply at the blastocyst stage and declining to preblastocyst levels on days 6.5 and 7.5. Pyruvate was consumed during preimplantation stages, with glucose uptake undetectable until the blastocyst stage. Glucose was the main substrate consumed by the 6.5 and 7.5 day embryo. The proportions of glucose accounted for by lactate appearance were 81%, 86%, and 119% at blastocyst, day 6.5, and day 7.5 stages, respectively. The equivalent figures for glucose incorporated into glycogen were 10.36%, 0.21%, and 0.19%, respectively. The data are consistent with a switch from a metabolism dependent on aerobic respiration during early preimplantation stages to one dependent on both oxidative phosphorylation and aerobic glycolysis at the blastocyst stage, a pattern which is maintained on days 6.5 and 7.5. Our technique for measuring oxygen consumption may have diagnostic potential for selecting viable embryos for transfer following assisted conception techniques in man and domestic animals. © 1996 Wiley-Liss, Inc.     

LUMOS - A Sensitive and Reliable Optode System for Measuring Dissolved Oxygen in the Nanomolar Range

Most commercially available optical oxygen sensors target the measuring range of 300 to 2 μmol L^-1. However these are not suitable for investigating the nanomolar range which is relevant for many important environmental situations. We therefore developed a miniaturized phase fluorimeter based measurement system called the LUMOS (Luminescence Measuring Oxygen Sensor). It consists of a readout device and specialized “sensing chemistry” that relies on commercially available components. The sensor material is based on palladium(II)-5,10,15,20-tetrakis-(2,3,4,5,6-pentafluorphenyl)-porphyrin embedded in a Hyflon AD 60 polymer matrix and has a K_SV of 6.25 x 10^-3 ppmv^-1. The applicable measurement range is from 1000 nM down to a detection limit of 0.5 nM. A second sensor material based on the platinum(II) analogue of the porphyrin is spectrally compatible with the readout device and has a measurement range of 20 μM down to 10 nM. The LUMOS device is a dedicated system optimized for a high signal to noise ratio, but in principle any phase flourimeter can be adapted to act as a readout device for the highly sensitive and robust sensing chemistry. Vise versa, the LUMOS fluorimeter can be used for read out of less sensitive optical oxygen sensors based on the same or similar indicator dyes, for example for monitoring oxygen at physiological conditions. The presented sensor system exhibits lower noise, higher resolution and higher sensitivity than the electrochemical STOX sensor previously used to measure nanomolar oxygen concentrations. Oxygen contamination in common sample containers has been investigated and microbial or enzymatic oxygen consumption at nanomolar concentrations is presented.     

Planktonic microbial community oxygen consumption rate in Cananéia waters (25°S 48°W), Brazil

Water samples were taken monthly in 1976 at three sites along the Cananéia estuarine-lagoon system (25°S 48°W), on the southern coast of São Paulo State, Brazil. After screening through a 100 μm mesh silk screen, samples from two sites were size fractionated in classes between 100–50 μm, 50–10 μm and 10–0.45 μm and, concentrated. Oxygen consumption rates (OCR) of the fractionated and unfractionated surface samples were estimated after incubating in dark bottles at ‘in situ’ temperature. OCR varied from 0.26±0.95 to 41.61±2.56 μl O₂ l^?1 h^?1. Highest OCR was observed in summer, at the site under fresh-water influence. At this site, for most of the year, the smallest size category contributed mostly to total OCR. Bacteria attached to particulate matter appear to be responsible for most of the oxygen consumption measured. At the more saline waters, OCR was found to be associated with organisms in the 10–100 μm size class. At this site, size analysis of chlorophylla showed that the 0.45–10 μm size category comprised the major portion of total chlorophyll. The lack of association between the OCR dominant size class and the prevailing phytoplankton and bacteria size categories, suggests the oxygen consumption to be due to other organisms, probably nano- and microzooplankton. OCR measured in the unfractionated samples, at site 2, showed the same order of magnitude to those of the fractionated ones. At this site the importance of the bacterial metabolism in relation to the total OCR measured is discussed. It is concluded that in the surface waters of the Cananéia estuarine lagoon system the contribution of bacterial metabolism to total oxygen consumption differs along the system, being significant at the upper reaches of the estuary, where the inputs of organic matter are larger. In saline waters, in spite of high bacterial densities, oxygen consumption seems to reflect the metabolism of larger organisms.     

Electrode measurement of oxygen tension with 1-ms time resolution

A continuous flow device utilizing a Clark oxygen electrode was constructed; this device had a dead time and resolution of 1 ms. Mixing was tested by observing the neutralization of acid with base, and at the maximal flow rate, the mixing was 94% complete within 1 ms and better than 98% complete within 2 ms after initial mixing. Observation of the oxygenation of hemoglobin gave data which agreed with previous data obtained by a stopped-flow optical experiment. The respiration of phosphorylating submitochondrial particles was measured utilizing this device. The burst of respiration in submitochondrial particles was triphasic, with a very rapid burst lasting some 60 ms, followed by a longer burst of respiration lasting more than 4 s.     

Oxygen-stabilized enzyme electrode for d-glucose analysis in fermentation broths

A new principle for the construction of oxygen-dependent enzyme electrodes is presented. The enzyme electrode is based on a galvanic oxygen electrode which is furnished with an electrolysis anode covered by immobilized enzyme and placed close to the oxygen-sensing surface. An ordinary oxygen electrode is used as a reference electrode. The enzymatic consumption of oxygen in the enzyme electrode generates a potential difference between the electrodes which is utilized to control electrolytic generation of oxygen from water in such a way that zero differential potential is maintained. Thus, the enzyme electrode operates under ambient oxygen tension and does not suffer from oxygen limitation. The electrolytic current in this system gives a measure of the concentration of substrate surrounding the enzyme electrode. The electrode has been applied for continuous d-glucose analysis in situ during batch cultures of Candida utilis.