Further evidence of oxygen diffusion as the determining factor in the relation between disk thickness and respiration of potato tissue

The effect of oxygen tension above atmospheric pO₂ on the development of respiratory capacity in potato disks has been examined. Raising the oxygen tension of the aqueous environment to 40% during the aging of 2.0 mm or 3.0 mm thick disks at 25° progressively increased the respiration rate of the tissue as shown by subsequent assay in 100% oxygen. Disks 3.0 mm thick showed a greater response to increased pO₂ than did 2.0 mm disks. A comparison of center 1.0 mm sections excised from 3.0 mm disks after aging, showed that the respiration rate of internal tissue from disks aged in high pO₂ was approximately 40% greater than such tissue aged with atmospheric pO₂. The characteristic inverse relationship between respiration rate and thickness in aged disks can be modified from a concave-downwards curve to a convex-downwards curve by pretreating the tissue with increased pO₂, thus indicating that raising the pO₂ during aging can increase the thickness threshold at which the transition from tissue manifesting the respiratory characteristics of thin disks to that manifesting the characteristics of thick disks, occurs. Similarly increased pO₂ during aging can modify the hyperbolic relationship obtaining between pretreatment temperature in the range 10° to 25° and respiratory capacity of aged 3.0 mm disks, to approximate to the linear relationship observed with 0.75 mm disks. It is concluded that the development of respiratory capacity in disks between 0.75 mm and 3.0 mm thick is restricted by oxygen dificiency and that the characteristic inverse relationship between respiration rate and thickness in aged disks is largely attributable to this factor, the influence of which is discernible both on the development of respiratory capacity and on its subsequent assay.     

Effect of oxygen concentrations and branched-chain amino acids on the growth and development of sub-seafloor fungus,Schizophyllum commune 20R-7-F01

Fungi have been reported to be the dominant eukaryotic group in anoxic sub-seafloor sediments, but how fungi subsist in the anoxic sub-marine sedimental environment is rarely understood. Our previous study demonstrated that the fungus, Schizophyllum commune 20R-7-F01 isolated from a ~2 km sediment below the seafloor, can grow and produce primordia in the complete absence of oxygen with enhanced production of branched-chain amino acids (BCAAs), but the primordia cannot be developed into fruit bodies without oxygen. Here, we present the individual and synergistic effects of oxygen and BCAAs on the fruit-body development of this strain. It was found that the fungus required a minimum oxygen concentration of 0.5% pO₂ to generate primordia and 1% pO₂ to convert primordia into mature fruit body. However, if BCAAs (20 mM) were added to the medium, the primordium could be developed into fruit body at a lower oxygen concentration up to 0.5% pO₂ where genes fst4 and c2h2 playing an important role in compensating oxygen deficiency. Moreover, under hypoxic conditions, the fungus showed an increase in mitochondrial number and initiation of auto-phagocytosis. These findings suggest that the fruit-body formation of S. commune may have multiple mechanisms, including energy and amino acid metabolism in response to oxygen concentrations.     

Tissue oxygen partial pressure in organs of chickens in the second half of embryogenesis and first days after hatching

The aim of this study is to measure the oxygen partial pressure (pO₂) in developing chicken tissues, namely, in the cerebral hemispheres, liver, m. pectoralis, and m. gastrocnemius, and to estimate the correlation of pO₂ with the earlier measured values (laser Doppler flowmetry) of volume blood flow (BF) in these organs. We have studied 10-, 15-, and 19-day-old embryos and 4-day-old chickens anesthetized with urethane. The pO₂ has been measured in the surface layers of organs with a membrane amperometric Clark-type O₂ electrode (cathode diameter of approximately 50 μm) placed in the center of the sensor unit (outer diameter of 3.4 mm). Noticeable distinctions between both the tissue pO₂ values in different organs and the dynamics of their changes during the observation time have been recorded. The following differences are the most important: (1) the lowest pO₂} {cm(and BF) is observed in the brain and, especially, in the liver of 10-day-old embryos; (2) in the subsequent period of embryogenesis, the pO₂ in the brain increases 1.9-fold (BF also increases), falls 1.7-fold in m. pectoralis, and displays minor changes in the liver and m. gastrocnemius on the background of constant BF value in the liver and both muscles; and (3) after hatching, pO₂ in the liver and m. pectoralis increases severalfold (BF increases too) but does not change in a statistically significant manner in the brain and m. gastrocnemius despite an increase in BF (more pronouncedly in the muscle). Two possible mechanisms underlying the changes in the tissue pO₂ in developing chicken organs have been proposed: one is determined by the specific features of intracardiac blood flows and the other is associated with the oxyhemoglobin dissociation pattern in the blood capillary circulation in the organs, determined by the specific features in its oxidative metabolism.     

Oxygen supply of the brain cortex in acute nitrite hypoxia in rodents with different ecological specialization

Microhemodynamics and oxygen tension (pO₂) in the brain cortex tissues as well as the heart rate were studied in rodents with different ecological specialization during hypoxia produced by subcutaneous injection of sodium nitrite (3 mg/100 g body mass). It was shown that the blood flow in animals with low (rats) and high (muskrats) resistance to hypoxia decreased by the 30th min of the nitrite action, with its subsequent restoration to 85% and 83% of the initial level by the 60th min. The interspecies difference consisted in an increase of the brain blood flow (by 24%) in muskrats and a decrease (by 33%) in rats 15 min after the injection. In rats, simultaneously with the blood-flow dynamics, a pO₂ increase was observed in some brain cortex microareas, while in others—a pO₂ decrease 15 min after the NaNO₂ injection: meanwhile, in muskrats, at this time period a significant pO₂ decrease was observed on the background of a blood flow increase. In both animal species, the pO₂ minimal value was reached by the 45th min, while restoration almost to the initial levels—by the 60th min of the nitrite action. Changes in the rats, synchronous and unidirectional with the heart rate frequency, of the brain blood-flow, as well as tachycardia developing throughout the whole experiment in rats allow suggesting that restoration of the oxygen regime in the brain cortex microareas is provided by activation of systemic mechanisms of regulation of circulation.     

Blocking of glutamate ionotropic receptors: Influence on the respiratory activity generated by medullo-spinal preparations of rats in hypoxia

We studied the influences of a non-competitive blocker of glutamate NMDA-receptors ketamune and of a competitive blocker of AMPA-kainate non-NMDA receptors, CNQX, on the respiratory activity generelated by superfusedin situ semi-isolated medullo-spinal preparations (SIMSP) of 3- to 4-day-old rats. We compared the ampes recorded under conditions of superfusion, a standard solution and the solution saturated with an anoxic isocapine gas mixture were compared; pO₂ in these solutions were 440±22 and 41±8 mm Hg, respectively. The experments were carried out with the ventrolateral medullary region (VLMR) left intact or after separation of its rostral part, which propertchonally corresponded to the chemosensitiveM zone. A 3-min-long hypoxic test initially evoked an increase in the frequency of inspiratory discharges (IR) in the phrenic nerve followed by a frequency drop within the final half of the test. After the rostral VLMR had been separated, the hypoxic test did not elicit a significant decrease in the IR frequency. After preliminary application of 1.0 or 10.0 μM ketamine or CNQX on intact preparations, the IR frequency under hypoxic conditions dropped within the first half of the test and increased in the second half, while the amplitude and integral intensity of these discharges were depressed more intensively than in hypoxia with no applications. Using ketamme and CNQX in the same concentrations resulted in significant drops in the amplitude, frequency, and integral intensity of IR recorde din the hypoxic test. Our experiments showed that in the early postnatal period glutamate ionotropic receptors of rostral VLMR neurons are involved in the control of IR frequency under hypoxic conditions. The possible role of glutamatergic control of the respiratory rhythm and mechanisms of the influences resulting from blocking of NMDA and non-NMDA receptors on the parameters of respiratory activity are discussed.     

Effect of pO(2) on the Formation and Status of Leghemoglobin in Nodules of Cowpea and Soybean

Nodulated cowpea (Vigna unguiculata [L.] Walp. cv Vita 3: Bradyrhizobium strain CB756) and soybean (Glycine max [L.] Merr. cv White Eye: Bradyrhizobium strain CB1809) were grown with their root systems maintained in a flowing gas stream containing a range of pO₂ (1-80%, v/v) in N₂ for up to 28 days after planting. At the extremes of sub- and supra-ambient pO₂, the levels of leghemoglobin (Lb) in nodules were reduced. However, neither the proportional composition of Lb component proteins (eight in soybean, three in cowpea) nor their oxidation state was affected by pO₂. Short-term changes in pO₂ (transferring plants grown with sub- or supra-ambient pO₂ in the rhizosphere to air or vice versa) caused a significant decline in Lb content and, in cowpea but not soybean, where pO₂ was increased, a higher percentage of oxidation of Lb. Combining data on changes in Lb level of cowpea nodules grown in sub-ambient pO₂ with those for their structural adaptation to an under supply of O₂ indicated that, despite the nodules having a lower level of Lb, the amount per infected cell was increased by up to twofold and per bacteroid up to fivefold (in those from 1% O₂) compared to those grown in air. Progressive decline in pO₂ resulted in a progressive increase on this basis, indicating a close relationship between Lb content and the adaptation of nodule functioning to external O₂ level.     

Adaptation of Nodulated Soybean (Glycine max L. Merr.) to Growth in Rhizospheres Containing Nonambient pO(2)

Nodulated soybean (Glycine max L. Merr. cv White Eye inoculated with Bradyrhizobium japonicum strain CB 1809) plants were cultured in the absence of combined N from 8 to 28 days with their root systems maintained continuously in 1, 2.5, 5, 10, 20, 40, 60, or 80% O₂ (volume/volume) in N₂. Plant dry matter yield was unaffected by partial pressure of oxygen (pO₂) and N₂ fixation showed a broad plateau of maximum activity from 2.5 to 40 or 60% O₂. Slight inhibition of nitrogenase activity occurred at 1% O₂ and as much as 50% inhibition occurred at 80% O₂. Low pO₂ (less than 10%) decreased nodule mass on plants, but this was compensated for by those nodules having higher specific nitrogenase activities. Synthesis and export of ureides in xylem was maintained at a high level (70-95% of total soluble N in exudate) over the range of pO₂ used. Measurements of nitrogenase (EC 1.7.99.2) activity by acetylene reduction indicated that adaptation of nodules to low pO₂ was largely due to changes in ventilation characteristics and involved increased permeability to gases in those grown in subambient pO₂ and decreased permeability in those from plants cultured with their roots in pO₂ greater than ambient. A range of structural alterations in nodules resulting from low pO₂ were identified. These included increased frequency of lenticels, decreased nodule size, increased volume of cortex relative to the infected central tissue of the nodule, as well as changes in the size and frequency of extracellular voids in all tissues. In nodules grown in air, the inner cortex differentiated a layer of four or five cells which formed a band, 40 to 50 micrometers thick, lacking extracellular voids. This was reduced in nodules grown in low pO₂ comprising one or two cell layers and being 10 to 20 micrometers thick in those from 1% O₂. Long-term adaptation to different external pO₂ involved changes which modify diffusive resistance and are additional to adjustments in the variable diffusion barrier.     

Respiration and oxygen transport in soybean nodules

Summary The respiration rate of individual soybean (Glycine max Merr.) nodules was measured as a function of pO₂ and temperature. At 23°, as the pO₂ was increased from 0.1 to 0.9 atm, there was a linear increase in respiration rate. At 13°, similar results were obtained, except that there was an abrupt saturation of respiration at approximately 0.5 atm pO₂. When measurements were made on the same nodule, the rate of increase in respiration with pO₂ was the same at 13° and 23°. Additional results were that 5% CO in the gas phase had no effect on respiration, except for a small decrease in the pO₂ at which respiration became saturated. Also, nodules still attached to the soybean root displayed the same respiratory behavior as detached nodules. A model for oxygen transport in the nodule is presented which explains these results quantitatively. The essence of the model is that the respiration rate of the central tissue of the nodule is almost entirely determined by the rate of oxygen diffusion to the respiratory enzymes. Evidence is given that the nodule cortex is the site of almost all of the resistance to oxygen diffusion within the nodule.     

Oxygen regime in rat brain tissues under conditions of acute nitrite methemoglobinemia

Oxygen regime in rat brain tissues was studied under conditions of nitrite hypoxia. The local brain circulation (LCC) and pO₂ were recorded by polargraphic method in microareas of the brain cortex one hour after a subcutaneous injection of NaNO₂ (3 mg/100 g body mass). A LCC decrease by 55% was shown by the 30th min of the nitrite intoxication, with its restoration to 85% of the initial blood-flow by the 60th min. In some brain microareas, a pO₂ increase by 40.7% was observed by the 45th min of the action and its decrease by 32.2% by the 60th min, whereas in other microareas, a pO₂ decrease by 24.5% with its subsequent increase to 78.7% of the initial level, respectively. A statistically significant correlation is revealed between changes of the oxygen pressure in the process of development of nitrite hypoxia and the LCC dynamics. It is concluded that the circulatory disturbances developing at the first moments of the nitrite action lead to an increase of the degree of the pO₂ differentiated distribution in the brain: to hyperoxygenation in some microareas and to severe hypoxia in others, what can be the cause of functional brain disturbances under the effect of nitrogen oxides.     

Some Factors Controlling the Distribution of Two Pond-Dwelling Ciliates with Algal Symbionts (Frontonia vernalis and Euplotes daidaleos)1

The vertical distributions of two pond-dwelling zoochlorellae-bearing ciliates (Euplotes daidaleos Diller & Kounaris, 1966 and Frontonia vernalis Ehrenberg, 1838) were monitored over a 24-h period. Both species maintained peak abundance at a low O₂ level (usually < 1 mg/liter). They did not migrate in response to the changing light level. Experiments with laboratory cultures indicated that the characteristic distribution in an O₂ gradient in the dark was largely controlled by the oxygen tension. The increased motility in anoxia and high pO₂ was independent of large changes in pCO₂ and pH. Ciliates living in anoxia or a very low pO₂ would migrate out of the dark and into the dimly lit (10 μE m_-2 sec_-1) part of a glass cell because there they could photosynthesize, produce O₂, and create a suitable oxygenated microenvironment; a further increase in the light level caused a slow migration out of the light. Similar migrations were observed when the light level remained low but the pO₂ was artificially raised. Ciliates suspended in 1 μM DCMU (an inhibitor of photosynthetic O₂ evolution) took longer to migrate into the light and they did not avoid high light levels (> 100, μE m_-2 sec_-1)- Frontonia suspended in water with a pO₂ of 1% aggregated at a low light level (1 μE m_-2 sec_-1); peak daytime abundance in the pond occurred at about this light level. Frontonia vernalis tends to swim vertically upwards (anterior end up) when suspended in anoxic water. This apparent negative geotaxis compensates for the high sedimentation velocity (0.36 mm sec_-1) of this large ciliate and facilitates its aggregation at the metalimnion. The O₂ tension appears to be the principal factor controlling the vertical distributions of both species. Occasional, enhanced convection within the metalimnion has a secondary influence. Light influences the vertical profile only if it promotes photosynthesis and increases the intracellular pO₂.     

Effect of pO(2) on Growth and Nodule Functioning of Symbiotic Cowpea (Vigna unguiculata L. Walp.)

Nodulated cowpea (Vigna unguiculata L. Walp. cv Vita 3:Bradyrhizobium CB 756) plants were cultured with their whole root system or crown root nodulation zone maintained for periods from 5 to 69 days after planting in atmospheres containing a range of pO₂ (1-80%, v/v) while the rest of the plant grew in normal air. Growth (dry matter yield) and N₂ fixation were largely unaffected by pO₂ from 10 to 40%. Decrease in fixation at pO₂ below 5% was due to lower nodulation and nodule mass and, at pO₂ above 60%, to a fall in specific N₂-fixing activity of nodules. Root:shoot ratios were significantly lower at pO₂ below 2.5%. The effect of pO₂ on nitrogenase activity (acetylene reduction), both of whole nodulated root systems and crown root nodulation zones, varied with plant age but was generally lower at supra- and subambient extremes of O₂. H₂ evolution showed a sharp optimum at 20% O₂ but was at most 4% of total nitrogenase activity. The ratio of CO₂ evolved to substrate (C₂H₂+H⁺) reduced by crown root nodulation zones was constant (6 moles CO₂ per mole substrate reduced) from 2.5 to 60% O₂ but at levels below 2.5 and above 80% O₂ reached values between 20 and 30 moles CO₂ per mole substrate reduced. Effects of long-term growth with nonambient pO₂ on adaptation and efficiency of functioning of nodules are discussed.     

Accurate control of oxygen level in cells during culture on silicone rubber membranes with application to stem cell differentiation

Oxygen level in mammalian cell culture is often controlled by placing culture vessels in humidified incubators with a defined gas phase partial pressure of oxygen (pO_2gas). Because the cells are consuming oxygen supplied by diffusion, a difference between pO_2gas and that experienced by the cells (pO_2cell) arises, which is maximal when cells are cultured in vessels with little or no oxygen permeability. Here, we demonstrate theoretically that highly oxygen‐permeable silicone rubber membranes can be used to control pO_2cell during culture of cells in monolayers and aggregates much more accurately and can achieve more rapid transient response following a disturbance than on polystyrene and fluorinated ethylene‐propylene copolymer membranes. Cell attachment on silicone rubber was achieved by physical adsorption of fibronectin or Matrigel. We use these membranes for the differentiation of mouse embryonic stem cells to cardiomyocytes and compare the results with culture on polystyrene or on silicone rubber on top of polystyrene. The fraction of cells that are cardiomyocyte‐like increases with decreasing pO₂ only when using oxygen‐permeable silicone membrane‐based dishs, which contract on silicone rubber but not polystyrene. The high permeability of silicone rubber results in pO_2cell being equal to pO_2gas at the tissue‐membrane interface. This, together with geometric information from histological sections, facilitates development of a model from which the pO₂ distribution within the resulting aggregates is computed. Silicone rubber membranes have significant advantages over polystyrene in controlling pO_2cell, and these results suggest they are a valuable tool for investigating pO₂ effects in many applications, such as stem cell differentiation. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Arterial Levels of Oxygen Stimulate Intimal Hyperplasia in Human Saphenous Veins via a ROS-Dependent Mechanism

Saphenous veins used as arterial grafts are exposed to arterial levels of oxygen partial pressure (pO₂), which are much greater than what they experience in their native environment. The object of this study is to determine the impact of exposing human saphenous veins to arterial pO₂. Saphenous veins and left internal mammary arteries from consenting patients undergoing coronary artery bypass grafting were cultured ex vivo for 2 weeks in the presence of arterial or venous pO₂ using an established organ culture model. Saphenous veins cultured with arterial pO₂ developed intimal hyperplasia as evidenced by 2.8-fold greater intimal area and 5.8-fold increase in cell proliferation compared to those freshly isolated. Saphenous veins cultured at venous pO₂ or internal mammary arteries cultured at arterial pO₂ did not develop intimal hyperplasia. Intimal hyperplasia was accompanied by two markers of elevated reactive oxygen species (ROS): increased dihydroethidium associated fluorescence (4-fold, p<0.05) and increased levels of the lipid peroxidation product, 4-hydroxynonenal (10-fold, p<0.05). A functional role of the increased ROS saphenous veins exposed to arterial pO₂ is suggested by the observation that chronic exposure to tiron, a ROS scavenger, during the two-week culture period, blocked intimal hyperplasia. Electron paramagnetic resonance based oximetry revealed that the pO₂ in the wall of the vessel tracked that of the atmosphere with a ~30 mmHg offset, thus the cells in the vessel wall were directly exposed to variations in pO₂. Monolayer cultures of smooth muscle cells isolated from saphenous veins exhibited increased proliferation when exposed to arterial pO₂ relative to those cultured at venous pO₂. This increased proliferation was blocked by tiron. Taken together, these data suggest that exposure of human SV to arterial pO₂ stimulates IH via a ROS-dependent pathway.     

Arterial pO2 stimulates intimal hyperplasia and serum stimulates inward eutrophic remodeling in porcine saphenous veins cultured ex vivo

Ex vivo culture of arteries and veins is an established tool for investigating mechanically induced remodeling. Porcine saphenous veins (PSV) cultured ex vivo with a venous mechanical environment, serum-supplemented cell-culture medium and standard cell-culture conditions (5% CO₂ and 95% balance air ~140 mmHg pO₂) develop intimal hyperplasia (IH), increased cellular proliferation, decreased compliance and exhibit inward eutrophic remodeling thereby suggesting that nonmechanical factors stimulate some changes observed ex vivo. Herein we explore the contribution of exposure to greater than venous pO₂ and serum to these changes in cultured veins. Removing serum from culture medium did not inhibit development of IH, but did reduce cellular proliferation and inward eutrophic remodeling. In contrast, veins perfused using reduced pO₂ (75 mmHg) showed reduced IH. Among the statically cultured vessels, veins cultured at arterial pO₂ (95 mmHg) and above showed IH as well as increase in proliferation and vessel weight compared to fresh veins; veins cultured at venous pO₂ did not. Taken together, these data suggest that exposure of SV to arterial pO₂ stimulates IH and cellular proliferation independent of changes in the mechanical environment, which might provide insight into the etiology of IH in SV used as arterial grafts.     

Prostaglandin E2 production by renal inner medullary tissue slices: Effect of metabolic inhibitors

Increasing oxygen from 5 to 95% has previously been shown to increase prostaglandin (PG) production in renal inner medullary slices. The possible role of oxidative phosphorylation in this process was investigated. The oxidative phosphorylation inhibitors, dinitrophenol (DNP), oligomycin, and cyanide were evaluated for their effects on PGE₂ production and ATP levels. None of the inhibitors affected PGE₂ synthesis, although they lowered ATP levels at the concentrations tested. In contrast, incubation of inner medullary tissue slices with 0% oxygen resulted in decreases both in PGE₂ and ATP levels. This suggest that the effect of oxygen on prostaglandin synthesis may be due to substrate limiting effects rather an effect on oxidative phosphorylation.When 22 mM 2-deoxyglucose was added to the incubation medium or when glucose was ommitted, PGE₂ levels increased. Sodium fluoride, presumably acting as a glycolytic inhibitor, increased PGE₂ levels, with a maximal effect at 10mM. ATP levels were 37% of control values with 20 mM NaF. This indicates that glucose may inhibit prostaglandin synthesis.These results indicate that oxygen (substrate) availability can limit inner medullary PGE₂. In view of the low pO₂ in the inner medulla, especially during antidiuresis, oxygen can potentially regulate prostaglandin productin in this tissue.     

The effect of excision on O2 diffusion and metabolism in soybean nodules

Nitrogen-fixing nodules of soybean [Glycine max (L.) Merr. cv. Maple Arrow inoculated with Bradyrhizobium japonicum USDA 16] were studied before and after excision from the root to determine the role the O₂ regulation plays in the inhibition of nodule activity and the potential for using excised nodules nodules in studies of nodule metabolism. Relative nitrogenase (EC 1.7.99.2) activity (H₂ evolution in N₂:O₂) and nodule respiration (CO₂ evolution) were monitored first in intact nodulated roots and then in freshly excised nodules of the same plant to determine the time course of the decline in nodule metabolism. Folowing excision, nitrogenase activity and respiration declined rapidly in the first minute and then more gradually. After 40 min the rate of H₂ evolution was only 14–28% of that in the intact plant. In some nodules activity declined steadily, and in others there was a partial recovery in activity ca 10 min after detachment. Infected cell O₂ concentration (O_i), measured by a spectro-photometric technique, also declined after nodule detachment with a time course similar to the declines in nitrogenase activity and respiration. Following excision, O_i levels declined rapidly from ca 21 nM in attached nodules to 8–12 nM at 4–10 min after excision and then more gradually to 2–3 nM O₂ at 30–40 min after excision. These results show that the nodules' permeability to gas diffusion continued to be regulated for up to 40 min after detachement. At 40 min after detachment, when excised nodules displayed steady-state rates of gas exchange, linear increases in pO₂ from 20 to 100% at 4% min^?1 resulted in recoveries of H² and CO² evolution, indicating that O_i limited nitrogenase activity durig this period, and that energy reserves were greatly in excess of the O₂ available for respiration. When detached nodules were equilibrated for 12 h at 20, 30 and 50% O₂, O_i values measured at supra-ambient pO₂ were greater than those at 20% O₂ and were linked with a more rapid decline in nitrogenase activity. Also, increases in external pO₂ (O_c) failed to stimulate nodule metabolism, suggesting that the nodules' energy reserves were no longer greatly in excess of their respiratory demands. It was concluded that soybean nodules could provide useful material for steady-state studies of nodule metabolism between 40 and 240 min after detachment, but to attain metabolic rates equivalent to in vivo rates the nodules must be exposed to above-ambient pO₂.     

Effect of oxygen pressure on synthesis and export of nitrogenous solutes by nodules of cowpea

Nodules of cowpea plants (Vigna unguiculata (L.) Walp. cv. Vita 3 :Bradyrhizobium CB756) cultured for periods of 23 d with their root systems maintained in atmospheres containing a range of partial pressures of O₂ (pO₂; 1–80%, v/v, in N₂) formed and exported ureides (allantoin and allantoic acid) as the major products of fixation at all pO₂ tested. In sub-ambient pO₂ (1 and 2.5%) nodules contained specific activities of uricase (urate: O₂ oxidoreductase; EC 1.7.3.3) and allantoinase (allantoin hydrolyase; EC 3.5.2.5) as much as sevenfold higher than in those from air. On a cell basis, uninfected cells in nodules from 1% O₂ contained around five times the level of uricase. Except for NAD: glutamate synthase (EC 1.4.1.14), which was reduced in sub-ambient O₂, the activities of other enzymes of ureide synthesis were relatively unaffected by pO₂. Short-term effects of pO₂ on assimilation of fixed nitrogen were measured in nodules of air-grown plants exposed to subambient pO₂ (1, 2.5 or 5%, v/v in N₂) and¹⁵N₂. Despite a fall in total¹⁵N₂ fixation, ureide synthesis and export was maintained at a high level except in 1% O₂ where formation was halved. The data indicate that in addition to the structural and diffusional adaptations of cowpea nodules which allow the balance between O₂ supply and demand to be maintained over a wide range of pO₂, nodules also show evidence of biochemical adaptations which maintain and enhance normal pathways for the assimilation of fixed nitrogen. This work was supported by a grant from the Australian Research Council (to C.A.A.) and an Australian Development Assistance Bureau postgraduate fellowship (to F.D.D.).     

Activation of Hsp90/NOS and increased NO generation does not impair mitochondrial respiratory chain by competitive binding at cytochrome C Oxidase in low oxygen concentrations

Nitric oxide (NO) is known to regulate mitochondrial respiration, especially during metabolic stress and disease, by nitrosation of the mitochondrial electron transport chain (ETC) complexes (irreversible) and by a competitive binding at O₂ binding site of cytochrome c oxidase (CcO) in complex IV (reversible). In this study, by using bovine aortic endothelial cells, we demonstrate that the inhibitory effect of endogenously generated NO by nitric oxide synthase (NOS) activation, by either NOS stimulators or association with heat shock protein 90 (Hsp90), is significant only at high prevailing pO₂ through nitrosation of mitochondrial ETC complexes, but it does not inhibit the respiration by competitive binding at CcO at very low pO₂. ETC complexes activity measurements confirmed that significant reduction in complex IV activity was noticed at higher pO₂, but it was unaffected at low pO₂ in these cells. This was further extended to heat-shocked cells, where NOS was activated by the induction/activation of (Hsp90) through heat shock at an elevated temperature of 42°C. From these results, we conclude that the entire attenuation of respiration by endogenous NO is due to irreversible inhibition by nitrosation of ETC complexes but not through reversible inhibition by competing with O₂ binding at CcO at complex IV.     

Production of Interferon in Mice: Effect of Altered Gaseous Environments

Effects of altered gaseous environments (parabarosis) on interferon production in mice were studied, with Newcastle disease virus (NDV) as the inducer. Increased levels of interferon in lung tissue were observed when mice were exposed to 11% O₂ in N₂ for 3 days before and after, or only after, injection of NDV. However, serum interferon levels remained unchanged. Exposure of mice to 77% O₂ for up to 7 days did not affect the response to interferon induction as assayed in lungs or sera. Interferon levels were significantly depressed in mice exposed to a simulated depth of 213 ft in seawater [with normal partial pressure of O₂ (pO₂) in N₂] for 2 or 4 weeks. Whereas definite depression of interferon was also observed in mice maintained at a simulated altitude of 37,000 ft (with normal pO₂) for 2 weeks, those maintained at the same condition for 4 weeks showed a normal level of interferon. The results obtained with hypoxia are compatible with other reports on the influence of O₂ tension on viral infection. The factors responsible for alterations observed in interferon level in mice kept in normal pO₂, but under altered pressure, have not yet been identified.     

Regulatory O2 tensions for the synthesis of fermentation products in Escherichia coli and relation to aerobic respiration

In an oxystat, the synthesis of the fermentation products formate, acetate, ethanol, lactate, and succinate of Escherichia coli was studied as a function of the O₂ tension (pO₂) in the medium. The pO₂ values that gave rise to half-maximal synthesis of the products (pO_0.5) were 0.2–0.4 mbar for ethanol, acetate, and succinate, and 1 mbar for formate. The pO_0.5 for the expression of the adhE gene encoding alcohol dehydrogenase was approximately 0.8 mbar. Thus, the pO₂ for the onset of fermentation was distinctly lower than that for anaerobic respiration (pO_0.5≤ 5 mbar), which was determined earlier. An essential role for quinol oxidase bd in microaerobic growth was demonstrated. A mutant deficient for quinol oxidase bd produced lactate as a fermentation product during growth at microoxic conditions (approximately 10 mbar O₂), in contrast to the wild-type or a quinol-oxidase-bo-deficient strain. In the presence of nitrate, the amount of lactate was largely decreased. Therefore, under microoxic conditions, the pO₂ appears to be too high for (mixed acid) fermentation to function and too low for aerobic respiration by quinol oxidase bo. Received: 7 February 1997 / Accepted: 2 May 1997