THE EFFECT OF CARBON DIOXIDE TENSION ON TISSUE METABOLISM (RETINA)

The metabolism of rat retina was found to be sensitive to the concentration of the carbon dioxide-bicarbonate buffer system. Increasing the carbon dioxide from 1 per cent to 5 per cent at constant pH nearly doubled both respiration and glycolysis. Increasing the carbon dioxide at constant pH from 5 per cent to 20 per cent had no effect on glycolysis, but depressed the Q _OO2 from 31 to 19. In a medium containing glucose and the 1 per cent carbon dioxide-bicarbonate buffer, the addition of succinate increased the Q _OO2 from 12 to 26, without affecting glycolysis. In a medium containing glucose and phosphate, succinate had no significant effect.     

Dinitrocresol, Cyanide, and the Pasteur Effect in Yeast

At pH 5·0 the respiration of yeast is stimulated by lowconcentrations of 3:5-dinitro-o-cresol, reaching a peak levelof 170 per cent, at 10⁵ M. Concentrations above this inhibitoxygen uptake and cause aerobic fermentation to appear, whichin turn reaches a peak value and is then inhibited. The rateof carbohydrate breakdown, or glycolysis, calculated from therates of respiration and aerobic fermentation, increases steadilyup to 3 x 10^–5 M., at which concentration it is 5 timesfaster than the control: higher concentrations depress the rateof glycolysis. The rate of fermentation under nitrogen is abouttwice that of respiration, and it is inhibited over the sameconcentration range as aerobic fermentation. It was found earlier that oxidative assimilation of glucoseby yeast is progressively inhibited by increasing concentrationsof dinitrocresol, and it is now shown that this parallels theincrease in the rate of aerobic glycolysis. It is argued thatdinitrocresol is here acting as an uncoupling agent and thatboth oxidative assimilation and the rate of glycolysis are controlledby the level of energy-rich phosphate. With cyanide there is no stimulation of oxygen uptake, aerobicfermentation only appears when respiration becomes inhibited,and after an initial slight decrease the rate of glycolysisrises to 575 per cent. of the control value at 5 x 10^–4M. It is suggested that the rate of glycolysis only increaseswhen respiration has been inhibited sufficiently to reduce therate of formation of energy-rich phosphate.     

RESPIRATORY ACTIVITY OF GUINEA PIG BRAIN NUCLEI

Abstract— Preparations of guinea pig brain nuclei, obtained by discontinuous gradient centrifugation in sucrose solutions of pH 6.7–6.8, containing 3 mM-MgCl₂ and phosphate exhibited steady and reproducible oxygen uptake. Oxygen uptake was stimulated 60–70 per cent by glucose, pyruvate, oxalacetate or α-ketoglutarate and 267 per cent by succinate. This respiratory activity was unaffected by the relative sodium or potassium ion content of the medium and by variations in the concentration of inorganic phosphate. Agents known to inhibit citric acid cycle oxidation, oxidative phosphorylation and glycolysis diminished oxygen uptake, but antibiotics inhibiting nucleic acid or protein synthesis did not. Treatment of the nuclear preparation with DNase decreased respiratory capacity, which was partially restored by the addition of polyacrylic acid.     

The tricarboxylic acid cycle and glycolysis in relation to ion transport by the ciliary body

1. The respiration and aerobic glycolysis of pig ciliary processes in oxygenated phosphate and bicarbonate buffers have been investigated. 2. Significant amounts of lactic acid are produced only in the presence of added glucose, but this does not change the endogenous respiration rate. 3. Succinate and citrate increase the oxygen uptake considerably, but pyruvate has almost no effect; oxaloacetate and fumarate stimulate slightly in the presence of glucose. Aspartate and fumarate together stimulate pyruvate utilization and are oxidized as fast as citrate. 4. Ouabain inhibits the oxidation of glucose and other substrates by limiting the ADP supply from the sodium transport system. Cyanide and azide inhibit respiration and stimulate glycolysis. 5. The transport mechanism depends largely on ATP from oxidative phosphorylation and regulates the rate of respiration and glycolysis by controlling ADP production from the Na(+)-K(+)-activated adenosine triphosphatase.     

Net movements of monovalent and bivalent cations, and their relation to energy metabolism, in slices of hepatoma 3924A and of a mammary tumour

1. During incubation at 1° in saline medium buffered either with phosphate or bicarbonate, slices of Morris hepatoma 3924A, and of a chemically induced tumour of rat mammary gland, lost K⁺ and gained Na⁺, Ca²⁺ and water.

2. Upon subsequent incubation at 38° in oxygenated medium, these changes were partially reversed. In the hepatoma, the reaccumulation of K⁺ was equally efficient in phosphate or bicarbonate medium, and in the presence and absence of glucose. Ca²⁺ was extruded in bicarbonate, but not in phosphate medium, and its extrusion was reduced in the presence of glucose.

3. When respiration was inhibited in the presence of glucose, K⁺ transport by the hepatoma continued to an extent which varied with the glycolytic activity of the slices, suggesting that the rate of ATP synthesis was a limiting factor under these conditions.

4. In the absence of glucose, the transport of Na⁺ and K⁺ was completely stopped by respiratory inhibition. However, more than 50% of the O₂ uptake had to be inhibited before any effect on transport was observed, suggesting that the rate of synthesis of ATP from endogenous respiration is in excess of that required to maintain transport.

5. Inhibition of transport by ouabain was accompanied by a 30% fall in the rate of endogenous respiration, and by a fall of 33% in the rate of glycolysis in the presence of cyanide plus glucose.

6. Comparison of the minimum rates of respiration and of glycolysis (in the presence of glucose plus cyanide) required to maintain the maximal extent of K⁺ transport in the hepatoma slices, suggests that ATP derived from oxidative phosphorylation or from anaerobic glycolysis is equally efficient as a source of energy for ion transport.     

Norepinephrine-stimulated fatty-acid release and oxygen consumption in isolated hamster brown-fat cells. Influence of buffers, albumin, insulin and mitochondrial inhibitors.

Brown fat cells isolated from adult golden hamsters have earlier been found to respond to addition of the physiological agonist norepinephrine with an increased rate of oxygen consumption and with fatty acid release. Working with these cells, we found the following. 1. The presence of albumin in the incubation medium (phosphate buffer) increases norepinephrine-induced fatty acid release and tends to stabilize the rate of oxygen consumption; bubbling of phosphate buffer with 5% CO2 in air has only a slight effect on fatty acid release. 2. In the presence of albumin, the norepinephrine-induced rate of oxygen consumption is also stable in bicarbonate buffer; it is higher than in the phosphate + CO2 buffer and the brown fat cells have a higher sensitivity to norepinephrine. 3. 20 mM phosphate (as e.g. present in a phosphate buffer) inhibits both fatty acid release and oxygen consumption. 4. Insulin inhibits the rate of oxygen consumption, but only at suboptimal concentrations of norepinephrine. 5. Atractylate inhibits submaximal norepinephrine-induced respiration, indicating that some oxidative phosphorylation takes place in norepinephrine-stimulated brown fat cells. 6. Fatty acid export from brown fat should be regarded as physiologically important.     

THE EFFECT OF CARBON DIOXIDE TENSION ON THE METABOLISM OF CEREBRAL CORTEX AND MEDULLA OBLONGATA

Manometric measurements were made of oxygen uptake (Q _OO2) and aerobic lactic acid output (Q_G) by slices of cerebral cortex and medulla oblongata of the cat in the presence of mixtures of 1, 5, and 20 volumes per cent of carbon dioxide in oxygen. The concentrations of NaHCO₃ and NaCl in the medium were varied to maintain constant pH and sodium ion concentrations. The calcium ion concentration was 0.0002 M. At pH 7.5 under these conditions, an increase in carbon dioxide from 1 per cent to 5 per cent doubled the Q_G of both tissues but did not alter Q _OO2; an increase from 5 per cent to 20 per cent carbon dioxide had no further effect on Q_G in either tissue or Q _OO2 of cortex, but did depress the Q _OO2 of medulla. At pH 8.1, an increase in carbon dioxide from 1 per cent to 5 per cent raised the Q _OO2 and Q_G of cortex by about 60 per cent. Measurements at low oxygen tension carried out previously in phosphate medium were repeated in bicarbonate medium to obtain data for the combined output of lactic acid and carbon dioxide (Q_A). When the oxygen in the gas phase was decreased from 95 to 3 volumes per cent, the lactic acid output as measured colorimetrically increased by 114 mg./gm. in cortex and by 8 mg./gm. in medulla; Q_A increased from 12.3 to 13.5 in cortex and decreased from 5.1 to 3.8 in medulla.     

Carbohydrate metabolism of schistosoma mansoni

1. Schistosoma mansoni utilizes in 1 hour an amount of glucose equivalent to one-sixth to one-fifth of its dry weight. Over 80 per cent of the metabolized glucose is converted to lactic acid by this organism. 2. The rates of glucose utilization and of lactic acid production by S. mansoni are the same under aerobic and under anaerobic conditions. 3. A high rate of lactic acid production and the absence of a postanaerobic increase in the oxygen uptake differentiate S. mansoni from most other parasitic helminths whose metabolism has been studied. 4. Arsenite and p-chloromercuric benzoate inhibit in low concentrations the oxygen uptake and the rate of glycolysis of S. mansoni. This inhibition is not prevented or reversed by an excess of glutathione or of thioglycollate. 5. Fluoride inhibits the removal of glucose and the production of lactic acid by S. mansoni to the same degree. 6. Low concentrations of quinacrine (atabrine) do not affect the respiration or the carbohydrate metabolism of the schistosomes. 7. The inhibitory effect of aldehydes on the metabolism of S. mansoni has been measured. Among this group of compounds dl-glyceraldehyde and o-nitrobenzaldehyde are the most effective inhibitors of glycolysis. 8. In a concentration of 2.6 x 10(-6)M (1:1,000,000) a cyanine dye inhibits almost completely the respiration of the schistosomes, but has no effect on their rate of glycolysis. The oxygen uptake of the worms is inhibited by fuadin to a greater degree than their rate of glycolysis. 2-methyl-1,4-napthoquinone is a much more effective inhibitor of glycolysis than of the respiration of S. mansoni. The latter compound interacts with plasma albumin and, therefore, its inhibitory action on the metabolism of the schistosomes is greatly reduced in human serum or plasma. 9. Evidence is discussed which indicates that, in contrast to glycolysis, respiratory metabolism is not essential for the survival of S. mansoni.     

In suspension cultures of Catharanthus roseus the cyanide-resistant pathway is engaged in respiration by excess sugar in combination with phosphate or nitrogen starvation

Suspension cultured cells of Catharanthus roseus were used to study the effects of excess sugar, and phosphate or nitrogen starvation on growth and respiration. Excess sugar resulted in a higher dry weight but the cell number was not significantly higher than in the controls. After inoculation in phosphate-free medium almost no growth was observed, whereas in medium without nitrogen some growth still occurred, indicating that the medium contains more than enough nitrogen and only a limited amount of phosphate. The maintenance respiration in the nitrogen-free medium was lower than in the control, probably as a result of a lower protein production. In phosphate-free medium, however, the maintenance respiration was higher, because the cyanide-resistant pathway was engaged and the P/O ratio was decreased. In Catharanthus roseus cells the cyanide-resistant pathway is engaged upon phosphate or nitrogen starvation in combination with excess sugar, while excess sugar, as such, does not engage the cyanide-resistant pathway. In the presence of excess sugar the rate of glycolysis is adenylate-controlled. It is only in combination with mineral starvation that the rate of glycolysis does not match the capacity of the cytochrome pathway, resulting in an overflow via the alternative pathway. After combination of mineral starvation with a low sugar supply the rate of glycolysis is controlled by both the substrate supply and the adenylates, and the cyanide-resistant pathway is not engaged.     

CO2-mediated control of fatty acid metabolism in isolated hamster brown-fat cells during norepinephrine stimulation.

1.Addition of norepinephrine to isolated hamster brown-fat cells suspended in Krebs-Ringer phosphate buffer induces a pronounced, but temporary increase in respiratory rate. 2. If Krebs-Ringer phosphate buffer is bubbled with CO2 prior to the addition of cells and norepinephrine, the respiratory capacity of the cells is further potentiated and most important, the respiration is maintained at a high rate until the medium becomes depleted of oxygen. 3. This respiratory pattern cannot be obtained in CO2-bubbled Krebs-Ringer bicarbonate buffer. 4. The results indicate that CO2 has a regulatory effect on fatty acid metabolism in isolated hamster brown-fat cells.     

The protein coats or ghosts or coliphage T2. III. Metabolic studies of Escherichia coli B infected with T2 bacteriophage ghosts

Assimilation of oxygen, inorganic phosphate, and ammonia nitrogen by normal T2 phage and T2 ghost-infected E. coli B was studied. The rate of oxygen and phosphorus uptake by ghost-infected bacteria is similar to that of normal and phage-infected cells. The R.Q. in glucose-salts medium remains approximately 1. Assimilation of ammonia nitrogen by ghost-infected bacteria is maintained at a rate approximately 80 per cent of normal. The inorganic phosphate which is assimilated was found to be incorporated into TCA-soluble compounds which were rapidly released into the medium. Within 5 minutes after absorption of the ghosts there was a loss from the cell of TCA-soluble constituents including organic phosphorus and compounds which absorb at 260 mmicro. No corresponding breakdown of nucleic acid present in the cell prior to infection could be detected. The incorporation of inorganic phosphate into organic linkages in the ghost-infected cell and its release into the medium were found to proceed at a rate approaching that of the incorporation of inorganic phosphorus into the nucleic acid of normal cells. The net increase in 260 mmicro absorbing compounds appeared to be inhibited.     

COMPARATIVE STUDIES ON RESPIRATION : XI. THE EFFECT OF HYDROGEN ION CONCENTRATION ON THE RESPIRATION OF PENICILLIUM CHRYSOGENUM.

1. Variations in pH value between 4 and 8 produce practically no effect on the normal rate of respiration (the rate at neutrality is called normal). 2. Increasing the pH value to 8.80 causes respiration to fall to 60 per cent of the normal, after which it remains stationary for the duration of the experiment. 3. Decreasing the pH value to 2.65 causes a gradual rise and a gradual return to normal; at pH 1.10 to 1.95 the preliminary rise amounts to 20 per cent and is followed by a fall to below the normal. 4. The decrease in respiration brought about by solutions of a pH value of 1.95 or less are irreversible, while a similar decrease which occurs at pH 8.80 is reversible, the rate coming back to practically normal after the material is replaced in a neutral solution. 5. Determinations by means of Winkler''s method showed an increase in the consumption of oxygen in acid solutions and a decrease in alkaline solutions.     

Inhibition of respiration by sodium fluoride and monoiodoacetic acid in wheat leaves at different oxygen tensions and in the presence of methylene blue and L-cysteine

Six-day leaves of wheat (Triticum vulgare) were used to test the effect of oxygen, nitrogen and different mixtures of these gases, methylene blue and L-cysteine on the inhibition of respiration by sodium fluoride and monoiodoacetic acid using the Warburg manometric method. In an atmosphere of 100% oxygen total respiration was increased by an average of 45%, 10% oxygen led to a decrease in respiration by 20%. However, no simultaneous changes were found in the degree of inhibition by these enzyme poisons. On decreasing the oxygen content to 5% inhibition of respiration was almost doubled while at the same time respiration fell by an average of 23%. In nitrogen, the respiration rate varied around 10% and inhibition was almost 100%. The results showed that the action of enzyme poisons is only influenced by different oxygen content at low oxygen tension and is evidently associated with the dominance of a given energy system (glycolysis). On using methylene blue and L-cystein in concentrations of 10-3M a decrease in the relative inhibition of respiration by enzyme poisons was also found. The total respiration rate, however, was only raised by 6–8%. Since the change in the degree of inhibition on using these substances is caused by an increase in the participation of respiratory processes resistant to glycolytic inhibitors it can, in this case be assumed that there is an increase in the activity of the pentose cycle in such tissue.     

Light-enhanced dark respiration in mesophyll protoplasts from leaves of pea

The respiratory oxygen uptake by mesophyll protoplasts of pea (Pisum sativum cv Arkel) was stimulated up to threefold after 15 minutes of illumination at an intensity of 1250 microeinsteins per square meter per second in the presence of 5 millimolar bicarbonate at 30°C. The extent of light-enhanced dark respiration (LEDR) increased progressively with duration of preillumination. The LEDR exhibited two phases. The initial high rate of respiration decreased in about 10 minutes to a lower steady value similar to that before illumination. The promotion of LEDR by the presence of bicarbonate and inhibition by glyceraldehyde or 3-(3,4-dichlorophenyl)-1,1-dimethylurea suggested that LEDR was dependent on products of photosynthetic carbon assimilation/electron transport. Thus, the photosynthetic products exert a markedly quick influence on dark respiration in mesophyll protoplasts.     

Balancing of mitochondrial and glycolytic ATP production and of the ATP-consuming processes of Ehrlich mouse ascites tumour cells in a high phosphate medium

A balance of energy budgeting of Ehrlich mouse ascites tumour cells including mitochondrial and glycolytic ATP production and about 80% of ATP consumption in a high phosphate medium is presented. In the share of glycolysis was about one-third of the total ATP production, more than twice that found in a low phosphate medium. The extent of a single energy reaction was assessed from the decrease of coupled oxygen consumption and lactate formation following the specific inhibition of this process. The inhibitory effects on coupled respiration and glycolysis were identical for the energy consuming processes measured: protein turnover, Na+/K(+)-ATPase, Ca2(+)-transport and RNA synthesis.     

The role of molecular oxygen and energy metabolism in the onset of Bacillus cereus spore germination

Bacillus cereus 96 spore germination was shown to depend on the content of molecular oxygen in the growth medium. When oxygen was removed from the medium, the spores germinated 50 min later as compared with this process under aerobic conditions. Likewise, spore initiation was delayed by 50 min in a growth medium containing oxygen in quantities optimal for respiration if 100mM KCN was added to it. The spores did not germinate when they had been treated simultaneously with glycolysis and respiration inhibitors.     

Features of glycolysis and pentose phosphate pathway in novobiocin sensitive and novobiocin resistant staphylococci

Intensity of glycolysis and the pentose phosphate cycle in staphylococci sensitive and resistant to novobiocin was studied. The resistant variants did not practically store lactate and the activity of glycolytic enzymes i.e. hexokinase and aldolase was lowered by 15-20 and 53-59 per cent, respectively. Monoiodoacetate, a glycolysis inhibitor suppressed the glucose oxidation rate by 53.3-66.9 per cent in the sensitive variants and by 16-21.8 per cent in the resistant variants. At the same time it was characteristic of the resistant variants to increase the activity of the pentose phosphate cycle enzymes; glucose-6-phosphate dehydrogenase by 25-38.1 per cent transketolase by 21.5-27.3 per cent and transaldolase by 30-57.1 per cent. No differences in the transhydrogenase reaction kinetics of both the novobiocin sensitive and the novobiocin resistant variants were observed.     

Metabolic changes during phosphate deprivation in Englena in air and in oxygen

1. Euglena cells were grown in culture media containing either 20mm-phosphate or 20mum-phosphate, with ethanol or glucose as the sole source of carbon, and gassed with either air+carbon dioxide (95:5) or oxygen+carbon dioxide (95:5) at atmospheric pressure. 2. After growth in low-phosphate medium with ethanol as substrate, the cells developed signs of oxygen toxicity, as indicated by a decreased rate of respiration, a decreased net synthesis of paramylum and a failure to resume growth on replenishment of phosphate. 3. After growth in low-phosphate medium with glucose as substrate, the signs of oxygen toxicity were less apparent. 4. During phosphate deprivation the carotenoid content of Euglena increased more than threefold. This increase was largely prevented by exposure of the cells to oxygen+carbon dioxide (95:5) during growth. Oxygenation appears to interfere with ring closure of the common carotenoid precursor. 5. Mitochondria obtained from Euglena exposed to oxygen during phosphate deprivation, i.e. when signs of oxygen toxicity were evident, had greatly decreased activities of succinate dehydrogenase, succinate-cytochrome c oxidoreductase and NADH-cytochrome c oxidoreductase, compared with mitochondria obtained from Euglena exposed to oxygen in medium containing 20mm-phosphate.     

OXYGEN TENSION AND THE RATES OF MITOSIS AND INTERPHASE IN ROOTS

The object of this work was to determine the influence of a wide range of oxygen tensions upon the relative rates of respiration, mitosis, and interphase in pea root tips, compared with the normal rates of these processes in air. From the rates of disappearance of mitotic figures in excised tips kept in various oxygen tensions, the relative rates of mitosis were found to decrease gradually from 122 per cent in 100 per cent oxygen to 24 per cent in 0.0007 per cent oxygen. From the mitotic indices of intact seedlings, the relative rates of interphase were found to decrease sharply from 82 per cent in 10 per cent oxygen to 6 per cent in 5 per cent oxygen. The data on relative rates of respiration, mitosis, and interphase in root tips were compared, and it was shown that the three processes are perfectly distinct in their quantitative relationships to low oxygen tensions.     

The Influence of CO2 Concentration and pH on Two Chlorella Species Grown in Continuous Light

Both Chlorella pyrenoidosa and Chlorella vulgaris grow equally well at 20°C aerated with ordinary air or mixtures of air with 5 or 12 per cent CO₂ (5 klux continuous light). Whereas C. vulgaris relatively rapidly adapts to a higher CO₂ tension, adaptation takes about 24 hours for C. pyrenoidosa. In Chlorella vulgaris pH in the range 3.6–7.6 has no apparent influence on the rate of photosynthesis in experiments having a duration of two hours. This is true both for algae grown aerated by ordinary air and for algae grown with a mixture of 5 per cent CO₂ in air. The adaptation time must be short. In Chlorella pyrenoidosa the same is found for algae in ordinary air, whereas an influence of pH is seen in some experiments where the aeration was by 5 per cent CO₂ in air. As is to be expected, the rate of photosynthesis in C. pyrenoidosa during the first two hours is very much influenced by the concentration of free CO₂. The highest rate is found at the CO₂ concentration at which the algae had been growing previously. The influence on the rate of photosynthesis in C. vulgaris is very much less, although in principle the same. The investigation of the corresponding influence on the rate of respiration is complicated by considerable variation from one series to another. In C. vulgaris this is particularly of importance. In C. pyrenoidosa, the highest rate of respiration is generally found at the CO₂-concentration at which the alga had been growing before the experiment. It seems probable that variations between similar series is due to the fact that the algae were grown in continuous light but with dilution with fresh culture medium when the optical density had reached a certain magnitude. Algae grown in this way are neither synchronized nor non-synchronized.Our thanks are due to the Danish State Research Foundation for financial support.