Correlation between Oxygen Availability, Energy Charge, and Protein Synthesis in Squash Cotyledons Isolated from Germinating Seeds

The influence of O₂ availability on the rate of protein synthesis, the levels of RNA and of adenylates, and the value of the energy charge in squash (Cucurbita maxima) cotyledons isolated from seeds germinated for 15 or 28 hours at different O₂ concentration (3% or 20% O₂) has been investigated.

The rate of protein synthesis is five times lower in cotyledons maintained in 3% O₂ than in those maintained in 20% O₂. Also net RNA synthesis is almost blocked in 3% O₂, while in 20% O₂ it proceeds almost linearly for 48 hours.

The different RNA contents cannot explain the different rates of protein synthesis.

The results of shift experiments (cotyledons shifted from 20% to 3% O₂ or vice versa) show that the rate of protein synthesis is strictly correlated with actual O₂ availability and is largely independent of the one in the previous period. O₂ controls the development of the adenylate pool and particularly the increase of ATP level. Thus, both the adenylate pool and the values of the energy charge ratio are lower in cotyledons grown in 3% than in 20% O₂.

The shifts of O₂ availability induce rapid changes of ATP, ADP, and AMP levels and thus of the values of the energy charge, which are about 0.7 at 3% O₂ and higher than 0.8 at 20% O₂, independent of previous O₂ availability.

The rate of protein synthesis appears to be largely independent of the levels of the single nucleotides and better correlated to the energy charge values.

     

The relationship between nodule adenylates and the regulation of nitrogenase activity by O2 in soybean

Nodulated soybeans (Glycine max L. Merr, cv. Maple Arrow) were exposed to various physiological and environmental treatments to determine the relationship between nodule adenylate pools and the degree of O₂ limitation of nitrogenase. Adenylate energy charge (AEC = [ATP + 0.5 ADP]/[ATP + ADP + AMP]) and ATP/ADP ratios declined under conditions of decreased (10%) external pO₂ but increased in nodules exposed to elevated (30%) external pO₂. Nitrogenase activity was inhibited by both pO₂ treatments, but recovered towards initial levels within 45 min. AEC also returned to initial levels during this period. To account for these and related data in the literature, it was hypothesized that 1) legume nodules regulate infected cell O₂ concentration (Oi) to maintain adenylate pools at levels which limit respiratory metabolism: 2) treatments which decrease Oi alter the adenylate pools and further limit nodule metabolism; 3) treatments which increase Oi to levels in excess of a narrow range alter the adenylate pools and activate biochemical pathways which are not conducive to nitrogenase activity. In a preliminary test of these hypotheses, changes in AEC and ATP/ADP ratio were studied in nodules in which nitrogenase activity was inhibited by stem girdling, nitrate fertilization and exposure to an Ar:O₂ atmosphere. All three treatments caused an increased O₂ limitation of nodule respiration and nitrogenase activity. However, decreases in AEC were observed only in the stem girdling and nitrate fertilization treatment: Ar:O₂ exposure had no effect on whole nodule AEC. While this result challenged the hypotheses suggesting a central role for adenylates in the regulation of O₂-limited metabolism, it was noted that the Ar:O₂ treatment would differ from the other treatments in that it would have a specific effect on the ATP demands for NH₃ assimilation in the plant fraction. Since AEC and ATP/ADP ratio would be affected by both the rate of ATP synthesis (potentially an O₂-limited process) and the demand for ATP, changes in these parameters in the whole nodule may not be a reliable indicator of adenylate-mediated O₂ limitation. Futher studies are needed to examine in vivo changes in adenylate pools in the plant and bacteroid fractions in nodules which vary in their degree of O₂-limited metabolism.     

Oxygen Transport and Root Respiration of Maize Seedlings: A Quantitative Approach Using the Correlation between ATP/ADP and the Respiration Rate Controlled by Oxygen Tension

Oxygen uptake and ATP/ADP ratio were simultaneously monitored during incubation of excised maize (Zea mays L. INRA 508) root tips under varying O₂ partial pressure. Both variables were independent of O₂ tension until a critical O₂ pressure was reached. Below this pressure, ATP/ADP ratio and respiratory rate declined. However, in tissues having a high glycolytic capacity, the correlation between the ATP/ADP ratio and the respiratory rate breaks down as O₂ tension decreases, due to the increasing contribution of fermentative processes.

In presence of 2 millimolar NaF, the ATP/ADP ratio varied solely as a function of the O₂ tension, without interference by fermentative activity, and a close correlation links the ATP/ADP ratio and the respiratory rate of excised maize root tips over the whole range of O₂ tensions tested.

Using this correlation, a method is proposed for the quantitative determination of the relative cellular respiratory rate permitted by O₂ transport from the aerial part of young maize seedlings along the seminal root placed in an anoxic environment.

Data are presented which demonstrate the preeminent part played by the cortical air spaces in O₂ transport. Their contribution to respiration was high in the first few centimeters nearest the seed and decreased rapidly as the distance from the aerated source increased. It is concluded that O₂ transport might contribute to the survival or to adaptive responses of root tissues in flooded soils but that the ventilation of the apical growing zone was inadequate to sustain the growth.

     

Critical oxygen pressure for growth and respiration of excised and intact roots

A method based on the measurement of ATP/ADP ratios is described. It permits the determination of the critical respiratory oxygen pressure of any organ, or part of any organ, of an intact plant. The data obtained by this method with intact maize (Zea mays L. INRA 508) root tips are compared with polarographic determinations on similar excised tissues.

When internal O₂ transport from the aerial part was prevented, the critical oxygen pressure found for the respiration of intact tips was similar to that found with excised tips. It was close to 10 kilopascals in a humid atmosphere and about 30 kilopascals in a liquid medium. Flooding of the gas spaces by vacuum infiltration did not modify these results. When internal O₂ transport from the aerial parts of the plant occurred, significantly lower values were obtained in liquid medium for the critical oxygen pressure, which shifted from more than 21 to 6 kilopascals. The higher values observed with excised root tips, compared to those obtained with intact tissues, can be explained by the lack of internal O₂ transport, rather than by the flooding of gas spaces.

Data are presented which show that root growth started to be limited at a significantly higher pressure than the respiration. These results are attributed to nonrespiratory oxidative processes with a low affinity for O₂ involved in root elongation.

     

Relationships between energy reserves and function in rat superior cervical ganglion

—Major components of the energy reserves of the isolated superior cervical ganglion (ATP, phosphocreatine, glucose, glycogen and lactate) were measured under aerobic and anaerobic conditions. Complete anaerobiosis was maintained by incubation in mineral oil through which N₂ had been bubbled. From the initial rate of change in the energy reserves, a metabolic rate was calculated which would be equivalent to the consumption of 93 m-moles of O₂ per kg per hour. Under aerobic conditions (oxygenated moist chamber) a similar metabolic rate was calculated. In contrast to the anaerobic state, initial energy expenditure was almost exclusively at the expense of glucose. Continuous supramaximal stimulation in O₂ increased energy expenditure by a factor of three; both glucose and glycogen were utilized from the outset, and lactate accumulated in the initial periods. Ganglionic transmission failed in both resting and stimulated states in spite of the continued presence of very substantial levels of ATP and phosphocreatine. Failure seemed to be associated not with ATP depletion but rather with the complete disappearance of glucose and glycogen.     

ATP Accelerates Respiration of Mitochondria From Rat Lung and Suppresses Their Release of Hydrogen Peroxide

Lung mitochondria were isolated by differential centrifugation from pentobarbital-anesthetized male rats. One to three millimolar Mg²⁺-ATP increased the consumption of oxygen of lung mitochondria oxidizing 10 mM succinate > fourfold (P < 0.01) whereas ATP increased the respiration of liver mitochondria by < 35%. ATP also hyperpolarized partially uncoupled lung mitochondria in the presence of the mitochondria-specific antagonist, oligomycin. However, only 20% of the ATPase activity in the lung mitochondria was blocked by oligomycin compared to a blockade of 91% for liver mitochondria. We investigated the effect of reducing the non-mitochondrial ATPase activity in the lung preparation. A purer suspension of lung mitochondria from a Percoll gradient was inhibited 95% by oligomycin. The volume fraction identified as mitochondria by electron microscopy in this suspension (73.6± 3.5%) did not differ from that for liver mitochondria (69.1± 4.9%). ATP reduced the mean area of the mitochondrial profiles in this Percoll fraction by 15% (P <0.01) and increased its state 3 respiration with succinate as substrate by 1.5-fold (P < 0.01) with no change in the state 4 respiration measured after carboxyatractyloside. Hence, ATP increased the respiratory control ratio (state 3/state 4, P <0.01). In contrast, state 3 respiration with the complex 1-selective substrates, glutamate and malate, did not change with addition of ATP. The acceleration of respiration by ATP was accompanied by decreased production of H₂O₂. Thus ATP-dependent processes that increase respiration appear to improve lung mitochondrial function while minimizing the release of reactive oxygen species.     

Effect of supra-ambient oxygen on nitrogenase activity (c(2)h(2)) and root respiration of soybeans and isolated soybean bacteroids

Isolated soybean (Glycine max [L.] Merr. cv Wilkin) bacteroids have O₂-dependent nitrogenase activity which is strongly inhibited by supraoptimal O₂ concentrations. Oxygen-inhibited nitrogenase activity is recovered by addition of 10 millimolar sodium succinate or by lowering the O₂ concentration.

Brief treatment of roots of intact soybean plants with 1.0 atmosphere O₂ reduces nitrogenase activity (C₂H₂). There is a rapid partial recovery of activity within 2 to 3 hours, and a slower return to near normal levels by 36 hours. The drop and recovery of nitrogenase activity is accompanied by a parallel drop and increase in root respiration. There is a direct relationship between the change in respiration and the change in acetylene reduction following O₂ treatment. The O₂-mediated changes in nitrogenase activity and root respiration are not affected by the planting medium. The ratio of the change in respiration to the change in nitrogenase activity was the same in 13 soybean cultivars.

     

Effect of oxygen on photosynthesis, photorespiration and respiration in detached leaves. I. Soybean

The effect of O₂ on the CO₂ exchange of detached soybean leaves was measured with a Clark oxygen electrode and infrared carbon dioxide analysers in both open and closed systems.

The rate of apparent photosynthesis was inhibited by O₂ while the steady rate of respiration after a few minutes in the dark was not affected. Part of the inhibition of apparent photosynthesis was shown to be a result of increased photorespiration. This stimulation of photorespiration by O₂ was manifested by an increase in the CO₂ compensation point.

The differential effects of O₂ on dark respiration (no effect) and photorespiration (stimulation) indicated that these were 2 different processes.

Moreover the extrapolation of the CO₂ compensation point to zero at zero O₂ indicated that dark respiration was suppressed in the light at least at zero O₂ concentration.

     

Inhibition of succinate-linked respiration and complex II activity by hydrogen peroxide

Hydrogen peroxide produced from electron transport chain derived superoxide is a relatively mild oxidant, and as such, the majority of mitochondrial enzyme activities are impervious to physiological concentrations. Previous studies, however, have suggested that complex II (succinate dehydrogenase) is sensitive to H₂O₂-mediated inhibition. Nevertheless, the effects of H₂O₂ on succinate-linked respiration and complex II activity have not been examined in intact mitochondria. Results presented indicate that H₂O₂ inhibits succinate-linked state 3 mitochondrial respiration in a concentration dependent manner. H₂O₂ has no effect on complex II activity during state 2 respiration, but inhibits activity during state 3. It was found that conditions which prevent oxaloacetate accumulation during state 3 respiration, such as inclusion of rotenone, glutamate, or ATP, blunted the effect of H₂O₂ on succinate-linked respiration and complex II activity. It is concluded that H₂O₂ inhibits succinate-linked respiration indirectly by sustaining and enhancing oxaloacetate-mediated inactivation of complex II.     

Relationships Between Seed Respiration During Imbibition and Subsequent Seedling Growth in Zea mays L

Corn (Zea mays L.) seed respiration rates during the first 30 hours of germination were compared with seedling growth 3 to 5 days after planting. Significant positive correlations were observed between rates of O₂ uptake during imbibition and later stages of germination and seedling growth. Glutamic acid decarboxylase activity also was positively correlated with seedling growth. The highly significant correlations between respiratory quotients and seedling growth were negative.

Seed metabolism during the initial hours of germination is evidently related somehow to seedling growth rates several days later. Whether this relationship is due to the dependence of synthetic processes and growth on respiratory energy, the fact that high respiration rates reflect high levels of metabolic activity, or to some other cause, remains to be determined.

     

Physiological and biochemical changes in frog sciatic nerve during anoxia and recovery

Frog (Rana pipiens) sciatic nerve was incubated, with and without stimulation, in an oil bath. The correlation between changes in the magnitude of the compound action potential (α and β) and changes in metabolites, particularly energy reserves, during anoxia and recovery from anoxia was studied. The time to extinction of the action potential in anoxia was frequency-dependent. The action potential could not be restored, nor its extinction delayed, by washing the nerve in O₂-free Ringer's solution. Therefore, in this system extracellular K⁺ accumulation was not a significant factor in blocking impulse conduction. At the time of complete nerve block resulting from anoxia (90 min at rest), ATP, P-creatine and glucose were 30, 10 and 10 per cent, respectively, of initial levels. Glycogen did not fall below 42 per cent of control levels even after 5 h of anoxia. Changes in the levels of energy reserves during anoxia were used to calculate the metabolic rate of nerves at rest and during stimulation. In one series of experiments, the resting metabolic rate was 0·12 mequiv. of ‘high-energy phosphate’ (～P)/kg/min. Stimulation increased the metabolic rate to 0·22 mequiv. of ～P/kg/min at 30 Hz and to 0·29 mequiv. of ～P/kg/min at 100 Hz. The change in metabolic rate when the nerve passed from the resting to the stimulated state was quite abrupt, an observation suggesting that the slow transition observed with methods monitoring O₂, consumption was largely instrumental. In nerve stimulated to exhaustion in the absence of O₂, neither ATP nor P-creatine had fully recovered within 60 min after O₂, was readmitted, although the action potential reached supranormal levels 15 min after return to O₂. The ratio of lactate: pyruvate, which increased as expected during anoxia, paradoxically increased even further after O₂, was readmitted. The rate of energy utilization during recovery was 0·30 mequiv. of ～P/kg/min. Nerves stimulated at 100–200 Hz in O₂, exhibited no changes in levels of P-creatine, ATP or lactate, an observation implying that the nerve could not be made to use ～P faster than oxidation of glucose could provide it. This meant that the maximal metabolic rate was not limited by the rate of supply of chemical energy. Instead, the limitation may have arisen as a result of a limited rate at which ionic imbalance can result from stimulation or a limited pump capacity of the axonal membrane. Nerves stimulated at 200 Hz in O₂ for 20 min and then transferred to an O₂-free environment without further stimulation exhibited an increase in the rate of energy utilization (nearly two-fold) over the resting rate, a finding that suggested a metabolic (ionic?) debt as a result of activity which could not be met even though the energy supply was adequate. Therefore, restriction of energy expenditure by a limiting pumping rate seemed to be the most likely explanation. The resting metabolic rate of frog sciatic nerve was only one-quarter to one-third of the rate for rat sciatic nerve, when compared at the same temperature (25°C).     

Chronic stress,energy transduction,and free-radical production in a reptile

Stress hormones, such as corticosterone, play a crucial role in orchestrating physiological reaction patterns shaping adapted responses to stressful environments. Concepts aiming at predicting individual and population responses to environmental stress typically consider that stress hormones and their effects on metabolic rate provide appropriate proxies for the energy budget. However, uncoupling between the biochemical processes of respiration, ATP production, and free-radical production in mitochondria may play a fundamental role in the stress response and associated life histories. In this study, we aim at dissecting sub-cellular mechanisms that link these three processes by investigating both whole-organism metabolism, liver mitochondrial oxidative phosphorylation processes (O₂ consumption and ATP production) and ROS emission in Zootoca vivipara individuals exposed 21 days to corticosterone relative to a placebo. Corticosterone enhancement had no effect on mitochondrial activity and efficiency. In parallel, the corticosterone treatment increased liver mass and mitochondrial protein content suggesting a higher liver ATP production. We also found a negative correlation between mitochondrial ROS emission and plasma corticosterone level. These results provide a proximal explanation for enhanced survival after chronic exposure to corticosterone in this species. Importantly, none of these modifications affected resting whole-body metabolic rate. Oxygen consumption, ATP, and ROS emission were thus independently affected in responses to corticosterone increase suggesting that concepts and models aiming at linking environmental stress and individual responses may misestimate energy allocation possibilities.     

Efficiency and regulation of root respiration in a legume: Effects of the N source

A comparison was made of energy metabolism of nodulated N₂ fixing plants and non-nodulated NO₃-fed plants of Lupinus albus L. Growth, N-increment, root respiration (O₂ uptake and CO² production) and the contribution of a SHAM-sensitive oxidative pathway (the alternative pathway) in root respiration were measured. Both growth rate and the rate of N-increment were the same in both series of plants. The rate of root respiration, both O₂ uptake and CO₂ production, and the activity of the SHAM-sensitive pathway were higher in NO₃-fed plants than in N₂ fixing plants. The rate of ATP production in oxidative phosphorylation was computed also to be higher in NO₃-fed plants. It is concluded that both carbohydrate costings and ATP costings for synthesis + maintenance of root material were lower in N₂ fixing than in NO₃-fed plants. The respiratory quotient of root respiration was 1.6 in N₂-fixing plants and 1.4 in NO₃-fed plants. These values were slightly higher than the values calculated on the basis of CO₂ output due to N-assimilation and the experimental values of O₂ uptake, but showed the same trend: highest in N₂ fixing plants. Root respiration of NO₃-fed plants showed a diurnal pattern (both O₂ uptake, CO₂ production and the activity of the SHAM-sensitive pathway), whilst no diurnal variation in root respiration was found in N₂ fixing plants. However, C₂H₂ reduction did show a diurnal rhythm, which is suggested to be related to the diurnal variation in transpiration. Addition of NO₃ to N₂ fixing plants increased the rate of root respiration and the activity of the alternative pathway. This treatment did not decrease C₂H₂ reduction and H₂ evolution within 4 days. Withdrawal of NO₃-supply from NO₃-fed plants decreased the rate of root respiration but had no effect on the relative activity of the alternative pathway. It is suggested that the higher rate of root respiration and the higher activity of the SHAM-sensitive pathway in NO₃-fed plants is due to a larger supply of carbohydrates to the roots, partly due to a better photosynthetic performance of the shoots and partly due to a higher capacity of the roots to attract carbohydrates.     

Energy status and free fatty acid patterns in tissues of common carp (Cyprinus carpio,L.) and rainbow trout (Oncorhynchus mykiss,L.) during severe oxygen restriction

Common carp and rainbow trout were exposed to a severe level of oxygen restriction up to a near lethal value, to study the occurrence of tissue damage. Rainbow trout lost equilibrium at a PO₂ of 3.2 kPa, whereas carp were able to survive 1.5 hr of anoxia. In both species, the anaerobic metabolism was significantly activated and the energy status (PCr, ATP and energy charge) was significantly depressed in brain, liver, and red and white muscle. No marked release of PUFA to the FFA pool was observed, while membrane leakage was not increased as evidenced by plasma LDH-activity. These results indicate the absence of a marked hydrolysis of membrane lipids. Thus, even after a near lethal exposure to hypoxia or anoxia, no tissue damage occurs in fish liver and skeletal muscles. The changes of the FFA patterns in the skeletal muscles and liver of both species after oxygen deprivation may be related to changes in desaturase activities, a reduction of lipolytic activity and PUFA metabolism.     

Effect of hypoxen on bioenergetic processes in mitochondria and activity of ATP-sensitive potassium channel

The effect of Hypoxen (HX) on bioenergetic processes in the mitochondria of heart and liver of rats connected with respiration, generation of hydrogen peroxide and activity of ATP-sensitive K-channel (mitoKATP) has been studied. It is shown that HX in the range of 0.05–10 μg/mL stimulates respiration, increases the coupling in the respiratory chain, and increases the formation of H₂O₂ and energy-dependent swelling associated with potassium transport in mitochondria. HX removes the inhibitory effect of ATP on the energy-dependent swelling of mitochondria and partially reduces the accumulation of H₂O₂ in the presence of ATP. The role of antihypoxic and antioxidant action of HX associated with the activation of mitoK_ATP is discussed.     

The Control of Iron-Induced Oxidative Damage in Isolated Rat-Liver Mitochondria by Respiration State and Ascorbate

The reaction of iron (II) with H₂O₂ is believed to generate highly reactive species (e.g., OH) capable of initiating biological damage. This study investigates the possibility that the severity of oxidative damage induced by iron in hepatic mitochondria is determined by the level of mitochondrial-H₂O₂ generation, which is believed to be particularly prominent in state-4 respiration.

Iron-induced damage is found to be greater in state-4 than in state-3 respiration. Experiments using uncoupling agents and Ca⁺⁺ to mimic state-3 conditions indicate that this effect reflects differences in the steady-state oxidation-level of the electron carriers of the respiratory chain (and hence the level of H₂O₂ -generation). rather than changes in redox potential or transportation of the metal-ion. Evidence is also presented for a mechanism in which Fe(II) and H₂O₂ react inside the mitochondrial matrix.

Ascorbate (vitamin C) is shown to be pro-oxidant in this system. except when present at very high concentration when it becomes antioxidant in nature.     

The biochemical conversions of conjugated dienoic and trienoic fatty acids

The changes in phosphate metabolism induced in yeast by transition from fermentation to respiration have been studied. Orthophosphate added to respiring or fermenting yeast suspensions as Na₂HP³²O₄ is rapidly resorbed and incorporated into adenosine triphosphate (ATP) and other acid-labile fractions. During fermentation, the specific activity of the orthophosphate is higher than that of ATP. This is thought to be mainly due to a heterogeneity in the intracellular orthophosphate. In respiring yeast, pyrophosphate is formed. The specific activity of this pyrophosphate is very high when the cells are maintained from the start of the experiment under aerobic conditions. When respiration follows a prior period of fermentation lasting 30–60 min., an accumulation of lowly labeled pyrophosphate occurs. Concurrently an acidinsoluble phosphate fraction is mobilized. As indicated by labeling relations, this fraction may be an intermediary in the pathway between orthophosphate and pyrophosphate. The possible role of dinucleotides in primary aerobic phosphorylation is reviewed and it is shown that diphosphopyridine nucleotide (DPN) undergoes a temporary resynthesis in yeast during the first 5–6 hr. of respiration. The question whether this phenomenon may be regarded as a secondary consequence of an enzymatic adaptation which involves pyrophosphate accumulation is discussed.     

A study of the impaired growth of roots of Zea mays seedlings at low oxygen concentrations

Abstract. Seedlings of Zea mays L. were grown in the dark at 27°C. Four-day-old seedlings were then exposed for 3 days to solutions equilibrated with gas mixtures to give O₂ concentrations between 0.02 and 0.25 mol m^?3. Root growth was impaired just as severely at 0.06 as 0.02 mol O₂ m^?3 while growth at 0.16 mol O₂ m^?3 was about the same as in solutions in equilibrium with air (0.25 mol O₂ m^?3). Growth of young seedlings at low O₂ concentrations was inhibited to the same extent in nutrient solution and 0.5 ml m^?3 CaCl₂, showing that the adverse effect of O₂ deficits on growth was not due to less uptake of inorganic nutrients. Furthermore, at low O₂ concentrations neither exposure of the shoots to a relative humidity of 100% (26.0 g H₂O m^?3) nor excision of the entire shoot enhanced root growth relative to that in plants with shoots at a relative humidity of 50% (13.0 g H₂O m^?3). Therefore, for these seedlings growing in the dark, impairment of root growth at low O₂ concentrations was not a consequence of water deficits in the shoot or of other shoot-root interactions. Total soluble sugars and amino acid concentrations were generally greater at low (0.02–0.06 mol O₂m^?3) than at high O₂ concentrations (0.16–0.25 mol O₂ m ^?3). This applied specifically to the root apices (0–2 mm) and expanding (2–15 mm) tissue except in some experiments where sugar concentrations in expanding tissue were slightly greater at high than at low O₂ concentrations. Critical O₂ pressures for respiration of excised root segments were approximately 0.117 and 0.065 mol O₂ m^?3 in the expanding and expanded zones of the roots, respectively. In contrast, the critical O₂ pressure exceeded 0.20 mol O₂ m^?3 in the apex, suggesting that O₂ supply for metabolic processes is most likely to be sub-optimal in this zone. Our results show clearly that the adverse effects of low O₂ concentrations are unlikely to be a consequence of substrate shortage for either respiration or synthesis of macromolecules; low rates of ATP regeneration in growing root tissues are the logical cause for impaired growth in young seedlings while they are being sustained by seed reserves.     

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.     

Protective metabolic mechanisms during liver ischemia: Transferable lessons from long-diving animals

During periods of O₂ lack in liver of seals, mitochondrial respiration and adenosine triphosphate (ATP) synthesis are necessarily arrested. During such electron transfer system (ETS) arrest, the mitochondria are suspended in functionally protected states; upon resupplying O₂ and adenosine diphosphate (ADP), coupled respiration and ATP synthesis can resume immediately, implying that mitochondrial electrochemical potentials required for ATP synthesis are preserved during ischemia. A similar situation occurs in the rest of the cell since ion gradients also seem to be maintained across the plasma membrane; with ion-specific channels seemingly relatively inactive, ion fluxes (e.g., K⁺ efflux and Ca⁺⁺ influx) can be reduced, consequently reducing ATP expenditure for ion pumping. The need for making up energy shortfalls caused by ETS arrest is thus minimized, which is why anaerobic glycolysis can be held in low activity states (anaerobic ATP turnover rates being reduced in ischemia to less than 1/100 of typical normoxic rates in mammalian liver and to about 1/10 the rates expected during liver hypoperfusion in prolonged diving). As in many ectotherms, an interesting parallelism (channel arrest coupled with a proportionate metabolic arrest at the level of both glycolysis and the ETS) appears as the dominant hypoxia defense strategy in a hypoxia-tolerant mammalian organ.Abbreviations ADP Adenosine Diphosphate - ATP Adenosine Triphosphate - BSA Bovine Serum Albumin - ETS Electron Transfer System - RCR Respiratory Control Ratio - EGTA Ethyleneglycol-Bis-(-aminoethyl ether)N,N,N,N-Tetraacetate