Measurement of steady-state values of respiration rate and oxidation levels of respiratory pigments at low oxygen tensions. A new technique

1. An apparatus was developed for the simultaneous measurement of steady-state values of respiration rate and oxidation level of respiratory pigments at low oxygen tensions. An open reaction system is utilized. The liquid sample is in contact with a gas mixture whose oxygen tension can be increased linearly with time at a rate so slow that the system is always practically at a steady state.

2. Assuming Michaelis-Menten kinetics in the respiration, theoretical curves for oxygen tension in the liquid and oxidation level of the terminal oxidase during a linear increase of the oxygen tension in the gas were calculated.

3. Measurements were performed on rat liver mitochondria. Steady-state curves for oxygen tension in the liquid and oxidation level of the terminal oxidase, cytochrome a₃, obtained with coupled mitochondria resembled the theoretical curves. For uncoupled mitochondria the cytochrome a₃ curve was signmoidal, deviating strongly from the theoretical curve.

4. The apparent K_m for oxygen uptake of coupled mitochondria in the presence of pyruvate and malate, in the absence of phosphate was found to be 0.5 μM. In the case of uncoupled mitochondria the oxygen tension in the liquid could not be measured with sufficient accuracy to allow comparison with Michaelis-Menten kinetics. The apparent K_m for oxygen uptake was less than 0.05 μM.     

Membrane open-system cell for oxygen consumption measurement

A membrane-diffusion cell for oxygen uptake measurements in an open system is described. Polarographic oxygen measurements with a Clark electrode are combined with simultaneous pH and absorbance or fluorescence determinations. Examples of its use are given and discussed, including experiments on mitochondrial respiration. Advantages of this cell are analyzed and comparisons are made with other open-system respirographs.     

A Microflow Respirometer for Measuring the Oxygen Consumption of Small Aquatic Organisms

A microrespiration device is decribed which uses a Clark electrode to measure the oxygen consumption or production of small and microscopic aquatic organisms in an open flow system. The construction and working principles of the device, which can measure oxygen consumptions as low as 0.5 nl · h⁻¹, are described. The design of the apparatus permits parallel measurements under identical conditions with a single electrode. The device can be matched to various sizes of animal and oxygen consumption rates by means of specimen chambers of different volumes (6 μl, 35 μl, 140 μl) and a variable water flow rate. The microflow respiration device has been used successfully to measure the respiration of zooplankton and meiobenthos organisms as well as protozoans and has also been used successfully on board a research vessel.     

The relationship between critical oxygen level and antibiotic synthesis of capreomycin and cephalosporin C

This paper illustrates the type of conclusions which may be reached by the use of an electrode for measuring oxygen tension in fermentation broths. The critical oxygen level, based on oxygen uptake, and the minimum oxygen tension necessary for maximum antibiotic synthesis for two commercial antibiotic fermentations, capreomycin and cephalosporin C, were studied. Capreomycin yields were depressed at an oxygen tension which was slightly below the critical oxygen level. Cephalosporin C synthesis was depressed at an oxygen tension higher than the critical oxygen level.     

A simple system for the measurement of ion activities with solvent polymeric membrane electrodes.

A simple device for the application of ion-selective liquid membrane electrodes to biochemistry is described. K⁺- and Ca²⁺-selective membranes were sealed on polyvinyl chloride (PVC) tubing and inserted into the side wall of a Plexiglas reaction vessel, enabling simultaneous measurements of K⁺ and Ca²⁺. The vessel also permits the simultaneous detection of changes in pH and oxygen and is predisposed to work under a controlled atmosphere. The system is particularly suitable for the measurement of fast changes in ion activities, since the stirring system described has a mixing time below 0.1 s. The 95% response times of the ion-selective electrodes and of the oxygen electrode were below 0.5 s. The volume of the reaction vessel is 0.5–1.0 ml.     

Monoamine Oxidase-Catalyzed Metabolism of 3,4-Dihydroxyphenylethylamine in the Dopaminergic Synaptosomes from Rat Corpus Striatum

Abstract: This communication describes conditions under which the monoamine oxidase-catalyzed metabolism of 3,4-dihydroxyphenylethylamine can be assayed in dopaminergic synaptosomes from the rat striatum. In contrast to the activity of the isolated enzyme or that of free mitochondria, the synaptosomal reaction exhibits sigmoidal kinetics with respect to substrate concentration. This is consistent with a kinetic mechanism in which intrasynaptosomal substrate partitions between reaction and saturable storage in synaptic vesicles. The reaction is inhibited at moderately decreased oxygen tension, where catecholamine uptake is unaffected. The specificity of this effect suggests that it reflects limited availability of oxygen as an enzyme substrate.     

Simple light guide for measuring irradiance in an aqueous oxygen electrode chamber

The light-dependent reactions of photosynthesis are often measured with Clark-type oxygen electrodes yet the irradiance level inside aqueous oxygen electrode reaction vessels is seldom reported due to the difficulty of measuring light inside a small volume chamber. We describe a simple light guide terminating in a 90° prism that can be inserted into a reaction vessel. Incoming irradiation is directed to a commercially available quantum sensor positioned at the other end of the light guide. Both materials for and construction of the device are inexpensive. This revised version was published online in June 2006 with corrections to the Cover Date.     

Oxygen diffusion in a spherical cell with nonlinear oxygen uptake kinetics

The oxygen diffusion in a spherical cell is analyzed in the present work. An oxygen uptake kinetics of the Michaelis-Menten type is employed. The oxygen uptake kinetics predicts the oxygen uptake rates which agree fairly well with the observed data. It has been found that difference between the predicted steady state oxygen tension distribution using the previous simplified oxygen uptake kinetics and that using the present non-linear kinetics is very significant.     

The Use of the Wide-Bore Dropping-Mercury Electrode for the Determination of Rates of Oxygen Uptake and of Oxidation of Ammonia by Micro-Organisms

S ummary : Convenient and reliable polarographic methods, using a wide-bore dropping-mercury electrode, for determining the dissolved oxygen content and the rate of respiration of sewage and activated sludge are described and verified by independent procedures. Using thiourea to inhibit Nitrosomonas spp., a technique was developed by which the uptake of oxygen by heterotrophs could be distinguished from that used in ammonia oxidation. Conditions are discussed under which accurate estimates of the rate of uptake of oxygen due to the oxidation of ammonia could be made. Typical values are given for the rates of respiration and of nitrification of activated sludge and also for the rates of respiration of a phenol-destroying pseudomonad.     

Cyanide-initiated oxygen consumption in autoclaved culture medium containing sugars

The consumption of oxygen initiated by KCN in an autoclaved sugar-containing rinse medium with protoplasts is described. The effect of autoclaving on several sugars was examined. Fructose solutions, followed in decreasing order by glucose, sucrose and sorbitol, were found to contain the largest amount of degraded products that could react with oxygen in the presence of KCN. Mannitol was found to be stable under the autoclaving conditions used in this investigation. KCN generally has an inhibitory effect on respiration, but in some plant tissues, respiration is stimulated by it. Under certain circumstances the degradation artefact described here may confuse interpretation of the results of respiration measurements. The use of autoclaved media containing sugars should be avoided in respiration studies that involve the application of KCN.Abbreviations SHAM salicylhydroxamic acid     

A new method to measure plant water uptake and transpiration simultaneously

A new weighing lysimeter system is described measuring transpirationand water uptake simultaneously on one plant, growing in waterculture. The measurements may be made for short time intervals(min) making it possible to monitor quick responses to changingenvironmental conditions. Fresh weight change, a combinationof growth and water status alterations in the plant, may becalculated from transpiration and water uptake. The system consistsof two communicating vessels filled with nutrient solution;each placed on an electronic balance. One of these vessels carriesthe plant and is connected to the other by a flexible tube.Water uptake will cause an equal decrease of the solution levelin each vessel. The weight decrease of the vessel with no plantprovides a measure of water uptake, the total weight decreaseon both balances represents transpiration. Test observations showed that measurements of transpirationand water uptake in a greenhouse can be made to an accuracyof about 0.03 g min^–1 plant^–1. With fluctuatingradiation, a clearly radiation-dependent transpiration was measuredon a tomato plant in a greenhouse. These measurements showeda delay between transpiration and water uptake. Consequently,fresh weight also fluctuated with radiation. An immediate decreasein transpiration was measured upon closure of a screen in thegreenhouse, accompanied by an increase in fresh weight. Fromlate afternoon until sunrise a constant fresh weight increasewas measured; first at a relatively high rate probably due togrowth and recovering from water deficits, thereafter at a constantrate probably only due to growth. Key words: Transpiration, water uptake, water relations, tomato, lysimeter     

Measurement of low levels of oxygen and their effect on respiration in cell suspensions maintained in an open system

The presence of low levels of oxygen may have profound effects on the cytotoxic activity of radiation, radiosensitizers, and bioreductive alkylating agents. As others have shown, low oxygen tensions may significantly alter rates of cellular and chemical oxygen consumption. When experiments are performed at very low oxygen concentrations, the opposing effects of oxygen leakage into and cellular/chemical oxygen consumption from the system can lead to unpredictable results. Use of a newly designed, highly sensitive Clark-type oxygen sensor has permitted accurate and reproducible measurement of low levels of oxygen. Cellular depletion of oxygen at various cell densities has been monitored for a series of oxygen tensions in solution and the corresponding respiration rates have been calculated. Although oxygen depletion was found to be quite significant at low oxygen tensions, not all oxygen present could be removed by cellular respiration. Respiration rate decreased as oxygen tension decreased and approached zero at low oxygen tensions. This result was independent of cell density. A model is presented to account for the observed effect of oxygen tension on cellular oxygen utilization.     

Electron Partitioning between the Cytochrome and Alternative Pathways in Plant Mitochondria

The contribution of the cyanide-resistant, alternative pathway to plant mitochondrial electron transport has been studied using a modified aqueous phase on-line mass spectrometry-gas chromatography system. This technique permits direct measurement of the partitioning of electrons between the cytochrome and alternative pathways in the absence of added inhibitors. We demonstrate that in mitochondria isolated from soybean (Glycine max L. cv Ransom) cotyledons, the alternative pathway contributes significantly to oxygen uptake under state 4 conditions, when succinate is used as a substrate. However, when NADH is the substrate, addition of pyruvate, an allosteric activator of the alternative pathway, is required to achieve the same level of alternative pathway activity. Under state 3 conditions, when the reduction state of the ubiquinone pool is low, the addition of pyruvate allows the alternative pathway to compete with the cytochrome pathway for electrons from the ubiquinone pool when the cytochrome pathway is not saturated. These results provide direct experimental verification of the kinetics consequences of pyruvate addition on the partitioning of electron flow between the two respiratory pathways. This distribution of electrons between the two unsaturated pathways could not be measured using conventional oxygen electrode methods and illustrates a clear advantage of the mass spectrometry technique. These results have significant ramifications for studies of plant respiration using the oxygen electrode, particularly those studies involving intact tissues.     

Angiogenesis in the hypertensive lung: response to ambient oxygen tension

The present study further analyzes the growth and reorganization of the vessels adjacent to capillaries in the hyperoxia-adapted lung in response to a lower ambient oxygen tension. The aim of the study was to determine the source of the new smooth muscle cells known to develop in these segments on return to breathing air. To accomplish this we determined the reorganization of vessel walls by quantitative light-microscopy techniques, and vascular cell phenotype(s) by high-resolution microscopy, in the lungs of rats that breathed a high oxygen tension (87% O2 for 4 weeks), followed by weaning to a lower oxygen tension (87-20% O2 over 1 week) and return to breathing air (for 1, 2 or 4 weeks). Return to breathing air initially triggered wall growth in a subset of vessels and wall thinning in others before wall thinning predominated throughout the vessel population. Interstitial fibroblasts were identified as the source of new perivascular cells. The recruitment of these cells was accompanied by loss of elastic laminae from vessel walls. Subsequently, most perivascular cells expressed a smooth muscle phenotype and elastic laminae were restored. Arteriography demonstrated an increase in the number of patent vessels on return to air, and light- and high-resolution microscopy restitution of the capillary network. We propose that in the hyperoxia-adapted lung return to breathing air represents a relative hypoxia that triggers differential patterns of vessel and capillary growth to meet new functional demands set by the lower ambient oxygen tension.     

Factors controlling the metabolic response to glucose in isolated rat lung cells

Glucose decreases the oxygen utilization by isolated rat lung cells. Its effect displays saturation type kinetics with a “Ki” of 2.2. mM. The similarity of this value with the reported “Km” of 2.4 mM described for glucose uptake by these cells, suggests that both processes may be intimately related and both of them are under the control of the same rate limiting step. Several arguments point to glucose transport into these cells as the most important rate limiting step for its utilization: 1) Phloridzin prevented glucose inhibition of oxygen uptake while mannoheptulose did not; 2) The activity of hexokinase which is the least active glycolytic enzyme in these cells far exceeded the observed rates of glucose utilization and a decrease of 45 per cent in its activity in starved animals did not affect the rate of glucose uptake; 3) The “Km” of hexokinase for glucose is two orders of magnitude below the observed “Km” for glucose uptake and the “Ki” for glucose inhibition of respiration.     

Quantification of embryo quality by respirometry

It is generally accepted that assessment of embryo metabolism, in particular oxygen consumption, may improve embryo selection by identifying the embryos with higher developmental competence. Several methods have been employed to measure embryonic oxygen consumption, but most of them were detrimental to subsequent embryo development. Recently, we have introduced the Nanorespirometer system, which is a non-invasive and highly sensitive technology developed for the individual measurement of embryonic respiration rates. This technology is able to perform single measurements at a fixed time or stage of embryonic development without adversely influencing embryo viability. Concomitantly, and based on the same principles, a second technology -- the Embryo Respirometer -- has been developed. The Embryo Respirometer allows the continuous measurement of individual respiration rates with simultaneous acquisition of digital images of each embryo, during the entire culture period (6-7 days). In this review, both technologies are described and their potential use as diagnostic tools for improving embryo selection in bovine and human following IVF treatments is discussed. Correlations between respiration rates of individual embryos and other parameters such as morphological quality, sex, stage of development, kinetics, diameter, expression of key metabolic genes and subsequent viability following embryo transfer are also examined. On the basis of the results obtained, it is postulated that assessment of embryonic respiration rates in association with other viability parameters allows for a more accurate embryo evaluation, both under clinical and research conditions.     

Intrinsic oxygen use kinetics of transformed plant root culture

Root meristem oxygen uptake, root tip extension rate, and specific growth rate are assessed as a function of dissolved oxygen level for three transformed root cultures. The influence of hydrodynamic boundary layer was considered for all measurements to permit correlation of oxygen-dependent kinetics with the concentration of oxygen at the surface of the root meristem. Oxygen uptake rate is shown to be saturated at ambient conditions, and a saturation level of approximately 300 micromole O2/(cm(3) tissue.hr) was observed for all three of these morphologically diverse root types. In nearly all cases, the observation of a minimum oxygen pressure, below which respiration, extension, or root growth would not occur, could be accounted for as a boundary layer mass transfer resistance. The critical oxygen pressure below which respiration declines is below saturated ambient oxygen conditions. In contrast, critical oxygen pressures for root tip extension were much higher; extension was nearly linear for the two thicker root types (Hyoscyamus muticus, henbain; Solanum tuberosum, potato) above ambient oxygen levels. The performance of the thinnest root, Brassica juncea (Indian mustard) was consistent with reduced internal limitations for oxygen transport. Extension rates did not correlate with biomass accumulation. The fastest growing henbain culture micro = 0.44 day(-)(1)) displayed the slowest extension rate (0.16 mm/hr), and the slowest growing mustard culture (micro = 0.22 day(-)(1)) had the fastest tip extension rate (0.3 mm/hr). This apparent paradox is explained in terms of root branching patterns, where the root branching ratio is shown to be dependent upon the oxygen-limited mersitem extension rate. The implications of these observations on the performance of root culture in bioreactors is discussed.     

Perivascular oxygen tensions in a transplantable mammary tumor growing in a dorsal flap window chamber.

Fischer 344 rats with R3230 Ac mammary carcinomas implanted in dorsal flap window chambers served as a model to obtain measurements of perivascular and stromal oxygen tension in normal and tumor tissues using Whalen recessed-tip microelectrodes (3- to 6-microns tip). Perivascular measurements were made adjacent to vessels with continuous blood flow. Thus the measurements and models provided are reflective of conditions leading to chronic hypoxia. Perivascular oxygen tensions averaged 72 +/- 13 mmHg in normal tissue vessels adjacent to tumor, 26 +/- 5 mmHg in tumor periphery, and 12 +/- 3 mmHg in tumor central vessels. There was a significant trend toward lower perivascular oxygen tensions in the tumor center (Kruskal-Wallis test, P = 0.002). A similar tendency was seen with a limited number of stromal measurements. Krogh cylinder models, which incorporate these data for perivascular oxygen tension, along with morphometric data obtained from the same tumor model suggest that hypoxic regions will exist between tumor vessels in the tumor center unless O2 consumption rates are well below 0.6 ml/100 g/min. The low perivascular measurements observed near the tumor center combined with the theoretical considerations suggest, for this model at least, that tissue oxygenation may best be improved by increasing red cell velocity and input pO2 and reducing oxygen consumption. The low perivascular oxygen tensions observed near the center also suggest that conditions conducive to increased red cell rigidity exist, that drugs which can decrease red cell rigidity could improve tumor blood flow and oxygenation, and that the endothelium of those vessels may be susceptible to hypoxia-reoxygenation injury.     

Gramicidin channel kinetics under tension.

We have measured the effect of tension on dimerization kinetics of the channel-forming peptide gramicidin A. By aspirating large unilamellar vesicles into a micropipette electrode, we are able to simultaneously monitor membrane tension and electrical activity. We find that the dimer formation rate increases by a factor of 5 as tension ranges from 0 to 4 dyn/cm. The dimer lifetime also increases with tension. This behavior is well described by a phenomenological model of membrane elasticity in which tension modulates the mismatch in thickness between the gramicidin dimer and membrane.     

Mediated spectroelectrochemical titration of proteins for redox potential measurements by a separator-less one-compartment bulk electrolysis method

One-compartment bulk electrolysis and simultaneous spectroscopic measurements are realized in a conventional spectroscopic cuvette without separator by using a mesh-type working electrode with extremely large surface area and a wire-type counter electrode with very small surface area. Spectrophotometric monitoring revealed complete electrolysis in a first-order kinetics. This technique was applied to mediated titration of cytochrome c and bilirubin oxidase for determining their redox potentials. Kinetics for the solution redox reaction between protein and mediator is described. The subtraction of spectral background due to mediator adsorption is very easy because of high reproducibility. The experiments can be done under completely anaerobic conditions. Low-absorbance protein samples (of low concentrations or small absorption coefficients) and hydrophobic proteins (such as membrane-bound proteins) are acceptable for measurements.