Effect of venous (gut) CO2 loading on intrapulmonary gas fractions and ventilation in the tegu lizard

Summary Studies were conducted to determine regional pulmonary gas concentrations in the tegu lizard lung. Additionally, changes in pulmonary gas concentrations and ventilatory patterns caused by elevating venous levels of CO₂ by gut infusion were measured.It was found that significant stratification of lung gases was present in the tegu and that dynamic fluctuations of CO₂ concentration varied throughout the length of the lung. Mean was greater and less in the posterior regions of the lung. In the posterior regions gas concentrations remained nearly constant, whereas in the anterior regions large swings were observed with each breath. In the most anterior sections of the lung near the bronchi, CO₂ and O₂ concentrations approached atmospheric levels during inspiration and posterior lung levels during expiration.During gut loading of CO₂, the rate of rise of CO₂ during the breathing pause increased. The mean level of CO₂ also increased. Breathing rate and tidal volume increased to produce a doubling ofV _E.These results indicate that the method of introduction of CO₂ into the tegu respiratory system determines the ventilatory response. If the CO₂ is introduced into the venous blood a dramatic increase in ventilation is observed. If the CO₂ is introduced into the inspired air a significant decrease in ventilation is produced. The changes in pulmonary CO₂ environment caused by inspiratory CO₂ loading are different from those caused by venous CO₂ loading. We hypothesize that the differences in pulmonary CO₂ environment caused by either inspiratory CO₂ loading or fluctuations in venous CO₂ concentration act differently on the IPC. The differing response of the IPC to the two methods of CO₂ loading is the cause of the opposite ventilatory response seen during either venous or inspiratory loading.Abbreviations IPC intrapulmonary chemoreceptors - UAC upper airway chemoreceptors - V _T inspiratory tidal volume - CO₂ gas fraction - O₂ gas fraction - V _E minute ventilation     

Cutaneous gas exchange in snakes

Summary Cutaneous aquatic gas exchange and pulmonary gas exchange have been compared in an aquatic snakeAchrochordus javanicus and the terrestrial snakeConstrictor constrictor.Gas exchange was measured by closed respirometry with the snakes in air and in water with access to air. Frequency of air breathing, tidal volumes and total lung volumes were also compared in the two species. All measurements were done at 20–22 ° C.The aquaticAchrochordus showed long periods of apnea in submerged condition interrupted by short periods of breathing activity at the surface. Average frequency of air breathing activity was 2.6 times per hour. Breathing in constrictor was more frequent but irregular with an average frequency of 143 breaths per hour.Total lung volume was 66±31 ml/kg body weight and 72.5±59 ml/kg body weight inAchrochordus andConstrictor, respectively. Tidal volumes were 41.5±4.4 ml/kg body weight and 29.5±14.8 ml/kg body weight, largest inAchrochordus. Constrictor had the highest total O₂ uptake ( ) correlating with a higher activity. Total gas exchange ratio (R _E ) was 0.69 forConstrictor and 0.77 forAchrochordus. InConstrictor air breathing accounted for 97% of the total whereas 21% of the CO₂ exchange was aquatic. Corresponding figures forAchrochordus were 92% of total by air breathing with as much as 33% of the CO₂ elimination as aquatic gas exchange.The results demonstrate that the trend among early air breathing vertebrates (fishes and amphibians) of a conservative evolution of CO₂ elimination by air breathing also extends to snakes.Significantly the cutaneous exchange component was highest in the more aquatic species.The results are discussed in relation to recent reports of a higher than alleged role of the skin of reptiles in evaporative water loss.This study was supported by grant HE 12071 from the National Institutes of Health in the U. S. A.     

Carbon dioxide desorption from fermentation broth by use of oxygen vectors

The ability of oxygen vector to extract produced carbon dioxide has been tested in an anaerobic fermentation. During the continuous culture of Clostridium acetobutylicum at pH 4.6 and at a dilution rate of 0.124 h^–1, a feed composed of an emulsion of 18.5% by volume of Forane F66E was able to extract about 9% of the total CO₂ produced under CO₂ partial pressure equal to 0.42 atm. A theoretical evaluation of the extracted amount, based on the hypothesis of total saturation of the vector by carbon dioxide, has lead to very good agreement.List of Symbols [AA] g/l acetic acid concentration - [BA] g/l butyric acid concentration - D 1/h Q _w /V dilution rate - [ETH] g/l ethanol concentration - H _w Henry constant of CO₂ for water at 37°C (=23.91 mmol/(l atm)) - H _F Henry constant of CO₂ for Forane at 37°C (=83.4 mmol/(l atm)) - H _i g/mol molar mass of componenti - P _i atm partial pressure of gasi - W _w l/h aqueous flow - Q_f 1/h Forane flow - mmol/(lh) dissolved CO₂ flow in aqueous effluent - mmol/(lh) CO₂ gas flow - mmol/(lh) CO₂ gas flow without Forane - mmol/(lh) CO₂ gas flow with Forane - mmol/(lh) total CO₂ production - r _X g/(lh) biomass production rate - r _G mmol/(lh) total gas flow - mmol/(lh) hydrogen production - mmol/(lh) nitrogen flow - r _S mmol/(lh) glucose input - V 1 fermentor volume     

Theoretical basis of single breath gas absorption tests

Absorption of gas from alveoli is examined in a simplified model of the respiratory system during a stylized single breath consisting of constant inspiratory flow, constant expiratory flow, and breathholding. The equations describing gas behavior are general since they are based upon conservation of mass. The equations simplify considerably when gases that are not soluble in pulmonary tissue and/or blood are utilized. In a three-compartment model, diffusing capacity of the lung for carbon monoxide (D _CO ) will be underestimated except when both uneven distribution of lung volume andD _CO are present; under most circumstances, the standard clinical 10-s method [9] is at least as accurate as any other. When pulmonary capillary blood flow is calculated by the one point method [2] in a one-compartment lung, it is underestimated; in the three-compartment model, it is underestimated except when both uneven distribution of . and lung volume are present. The multiple single breath method [2] accurately measuresD _CO and . Measurement of pulmonary tissue volume is improved by correcting the value of the intercept of acetylene absorption to the time when carbon monoxide apparently began rather than utilizing the beginning of inspiration.Nomenclature D _CO diffusing capacity of the lung for CO (ml CO, STPD/min/mm Hg) - pulmonary capillary blood flow rate (L/min) - V _t pulmonary tissue volume (L) - V _A alveolar compartment volume (L) - V _Ao alveolar compartment volume at conclusion of inspiratory flow (L) - inspiratory flow rate (L/sec) - expiratory flow rate (L/sec) - Bunsen coefficient of pulmonary tissue for test gas (ml test gas/ml tissue/atm) - Bunsen coefficient of pulmonary tissue for test gas (ml test gas/ml blood/atm) - F _A fractional pressure of test gas in the alveolar compartment (atm)     

Growth parameters (K s, μmax,Y s) of Methanobacterium thermoautotrophicum

Methanobacterium thermoautotrophicum was grown on a mineral salts medium in a fermenter gassed with H₂ and CO₂, which were the sole carbon and energy sources. Under the conditions used the bacterium grew exponentially. The dependence of the growth rate () on the concentration of H₂ and CO₂ in the incoming gas and the dependence of the growth yield ( ) on the growth rate were determined at pH 7 (the pH optimum) and 65° C (the temperature optimum).The curves relating growth rate to the H₂ and CO₂ concentration were hyperbolic. From reciprocal plots apparent K _s values for H₂ and CO₂ and _max were obtained: app. = 20%; app. = 11%; = 0.69 h^-1; t (max)=1 h. was 1.6 g mol^-1 and almost independent of the growth rate, when the rate of methane formation was not limited by the supply of either H₂ or CO₂. The yield increased to near 3 g mol^-1 when H₂ or CO₂ were limiting. These findings indicate that methane formation and growth are less tightly coupled at high concentrations of H₂ or CO₂ in the medium than at low concentrations. The physiological significance of these findings is discussed. K _s: H₂ and CO₂ concentration supporting 0.5 _max; _max: specific growth rate at infinite substrate concentration; Y _s:growth yield (g dry weight/mol substrate); t : doubling time     

Can CO2 assimilation in maize leaves be predicted accurately from chlorophyll fluorescence analysis?

Analysis is made of the energetics of CO₂ fixation, the photochemical quantum requirement per CO₂ fixed, and sinks for utilising reductive power in the C₄ plant maize. CO₂ assimilation is the primary sink for energy derived from photochemistry, whereas photorespiration and nitrogen assimilation are relatively small sinks, particularly in developed leaves. Measurement of O₂ exchange by mass spectrometry and CO₂ exchange by infrared gas analysis under varying levels of CO₂ indicate that there is a very close relationship between the true rate of O₂ evolution from PS II and the net rate of CO₂ fixation. Consideration is given to measurements of the quantum yields of PS II ( _{PS II}) from fluorescence analysis and of CO₂ assimilation ( ) in maize over a wide range of conditions. The ratio was found to remain reasonably constant (ca. 12) over a range of physiological conditions in developed leaves, with varying temperature, CO₂ concentrations, light intensities (from 5% to 100% of full sunlight), and following photoinhibition under high light and low temperature. A simple model for predicting CO₂ assimilation from fluorescence parameters is presented and evaluated. It is concluded that under a wide range of conditions fluorescence parameters can be used to predict accurately and rapidly CO₂ assimilation rates in maize.     

Intercellular CO2 concentration and water-use efficiency of temperate plants with different life-forms and from different microhabitats

Summary Photosynthesis and transpiration were measured simultaneously, under near-optimum and constant environmental conditions, in intact leaves of plants native to the temperate forest region. A linear relationship between photosynthetic rate and stomatal conductance was found in every species tested irrespective of leaf age or season, indicating that the calculated intercellular CO₂ concentration and water-use efficiency were fairly constant within a species. The values of intercellular CO₂ concentration and water-use efficiency ranged from 221 to 271 l l^–1 and 4.46 to 8.20 mol CO₂ mmolH₂O^–1 (6.24±0.90 mol CO₂ mmolH₂O^–1), respectively. The variations in intercellular CO₂ concentration and water-use efficiency were not directly related to photosynthetic capacities, life-forms, or microhabitat preferences. The intercellular CO₂ concentrations found in this study were close to values reported from cultivated plants and plants native to more arid regions, suggesting a common mechanism to maintain the stomatal conductance proportional to photosynthetic capacity over a wide variety of C₃ plants.     

A method for estimating bicarbonate buffering of lactic acid during constant work rate exercise

A method to estimate the CO₂ derived from buffering lactic acid by HCO₃ ^– during constant work rate exercise is described. It utilizes the simultaneous continuous measurement of O₂ uptake ( O₂) and CO₂ output ( CO₂), and the muscle respiratory quotient (RQ_m). The CO₂ generated from aerobic metabolism of the contracting skeletal muscles was estimated from the product of the exercise-induced increase in O₂ and RQ_m calculated from gas exchange. By starting exercise from unloaded cycling, the increase in CO₂ stores, not accompanied by a simultaneous decrease in O₂ stores, was minimized. The total CO₂ and aerobic CO₂ outputs and, by difference, the millimoles (mmol) of lactate buffered by HCO₃ ^– (corrected for hyperventilation) were estimated. To test this method, ten normal subjects performed cycling exercise at each of two work rates for 6 min, one below the lactic acidosis threshold (LAT) (50 W for all subjects), and the other above the LAT, midway between LAT and peak O₂ [mean (SD), 144 (48) W]. Hyperventilation had a small effect on the calculation of mmol lactate buffered by HCO₃ ^– [6.5 (2.3)% at 6 min in four subjects who hyperventilated]. The mmol of buffer CO₂ at 6 min of exercise was highly correlated (r = 0.925, P < 0.001) with the increase in venous blood lactate sampled 2 min into recovery (coefficient of variation = ±0.9 mmol·l^–1). The reproducibility between tests done on different days was good. We conclude that the rate of release of CO₂2 from HCO₃ ^– can be estimated from the continuous analysis of simultaneously measured CO₂, O₂, and an estimate of muscle substrate.     

Ventilation and gas exchange in the Carpet Python,Morelia spilotes variegata

Summary The structure, dimensions and gas exchanging properties of the lungs of the Australian Carpet PythonMorelia spilotes variegata have been studied by dissection, by sampling lung gas and pulmonary venous blood and by using radioactive techniques to monitor distribution of ventilation ( ) and blood flow ( ). The lungs have alveolar and saccular parts (mean capacities 10.2 and 129.3 ml/kg body weight, respectively). The sacs store inspired air creating a flow through situation which abolishes the dead space effect, prevents large expansions of the alveolar lung and allows gas exchange during both inspiration and expiration. Gas exchange was measured in intubated snakes in the resting and active states at 20–26 °C. In the resting state, respiratory frequency, tidal volume and ventilation were 1.72±0.56/min, 14.8±10.8 ml/kg, 22.04±7.75 ml/kg · min and pulmonary venousP _{O 2},P _{CO 2} and pH were 58.9±14.5 Torr, 21.5±4.2 Torr, and 7.55±0.07 Torr, respectively. R. Q. was low, 0.65±0.11. In the active state both ventilation ( ) and cardiac output increase and blood flow is redistributed more evenly along the alveolar lung, enabling increased O₂ uptake. Since blood flow ( ) in the alveolar lung is stratified (Read and Donnelly, 1972) redistribution of during activity is proposed as a possible reserve capacity for O₂ extraction by reptilian lungs.     

Energetics of CO formation and CO oxidation in cell suspensions of Acetobacterium woodii

Cell suspensions of Acetobacterium woodii produced CO from H₂ and CO₂. Depending on the conditions, more than 1,000 ppm CO were measured in the gas phase. This concentration was more than 10-fold higher than the thermodynamic equilibrium concentration that can be calculated to be 83.5 ppm for the experimental conditions used. This finding is taken as evidence that, besides the activation of formate, also CO production from CO₂ is an energy-dependent step in the reduction of CO₂ to acetate. Studies on the influence of ionophores and dicyclohexylcarbodiimide (DCCD) as well as that of CO and formaldehyde on acetate synthesis were undertaken in order to determine whether ATP or is the driving for CO₂ reduction to CO.Cells of A. woodii also catalyzed the conversion of CO (5% in the gas phase) to CO₂ and H₂. This process was coupled to the generation of metabolic energy, which could be used by the cells to drive the uptake of histidine into the cells; histidine uptake was almost completely inhibited by the ionophores valinomycin plus nigericin. The data were taken to indicate that in this acetogen the energy derived from CO oxidation can be converted to metabolic energy.Abbreviations DCCD dicyclohexylcarbodiimide - THF tetrahydrofolate - TCS tetrachlorosalicylanilide - TPP⁺ tetraphenylphosphonium ion - Val valinomycin; Nig, nigericin - DTT dithiothreitol - DTE dithioerythritol - DTE dithioerythritol - membrane potential - electrochemical proton potential - ppm parts per million     

Effect of chronic acidosis on discharge frequency of intrapulmonary chemoreceptors in the chicken

Summary In order to determine the pH effect on the discharge of intrapulmonary chemoreceptors (IPC) not mediated through , we determined discharge frequency-ln relationships of 28 IPC from ten adult cockerels made acidotic by ingestion of feed containing 6% NH₄Cl for 2 to 5 days. Blood buffer curves — the relationships between pH and — from these cockerels were shifted in parallel towards acidosis by 0.24 pH units (SE=±0.05) compared to control curves. The average slope of the IPC discharge frequenc-ln relationships was less negative than that reported for similar cockerels with normal acid-base balance and the average intercept was decreased. We conclude that pH has an effect on IPC discharge, independent of changes in ; this effect decreases IPC sensitivity to CO₂. We calculate that a shift towards acidosis in the blood buffer curve of one pH unit causes the slope of the IPC discharge frequency-ln relationship to be less negative by 14.7±3.3 imp (s·ln )^–1 and that for any acidotic shift in the blood buffer curve (pH), the average IPC discharge frequency=[–10.7+(14.7·pH)][ln( /25.5)]+3.37. Since IPC discharge is altered by changes in acid-base balance, IPC may contribute to the implementation of respiration responses during metabolic disturbances.Abbreviation IPC intrapulmonary chemoreceptor     

Thermoregulation in a large bird,the emu (Dromaius novaehollandiae)

The emu is a large, flightless bird native to Australia. Its habitats range from the high snow country to the arid interior of the continent. Our experiments show that the emu maintains a constant body temperature within the ambient temperature range-5 to 45°C. The males regulate their body temperature about 0.5°C lower than the females. With falling ambient temperature the emu regulates its body temperature initially by reducing conductance and then by increasing heat production. At-5°C the cost of maintaining thermal balance is 2.6 times basal metabolic rate. By sitting down and reducing heat loss from the legs the cost of homeothermy at-5°C is reduced to 1.5 times basal metabolic rate. At high ambient temperatures the emu utilises cutaneous evaporative water loss in addition to panting. At 45°C evaporation is equal to 160% of heat production. Panting accounts for 70% of total evaporation at 45°C. The cost of utilising cutaneous evaporation for the other 30% appears to be an increase in dry conductance.Abbreviations A _r Effective radiating surface area - BMR basal metabolic rate - C _dry dry conductance - CEWL cutaneous evaporative water loss - EHL evaporative heat loss - EWL evaporative water loss - FECO₂ fractional concentration of CO₂ in excurrent air - FF_H2O water content of chamber excurrent air - FEO₂ fractional concentration of O₂ in chamber excurrent air - FICO₂ fractional concentration of CO₂ in incurrent air - FIO₂ fractional concentration of O₂ in chamber incurrent air - MHP metabolic heat production - MR metabolic rate - REWL respiratory evaporative water loss - RH relative humidity - RQ respiratory quotient ; - SA surface area - SEM standard error of the mean - SNK Student-Newman-Keuls multiple range test - STPD standard temperature and pressure dry - T _a ambient temperature(s) - T _b body temperature(s) - T _e surface temperature(s) - flow rate of air into the chamber - carbon dioxide production - oxygen consumption - vapour pressure of water     

Effects of temperature on respiration and acid-base balance in a monitor lizard

Summary Ventilation, gas exchange, blood gas tensions and arterial pH were measured simultaneously in monitor lizards,Varanus exanthematicus. In contrast to previously studied poikilotherms, the arterial pH is independent of body temperature within the normally encountered temperature range (Fig. 1). This exception to the relative alkalinity concept (Rahn, 1966) is correlated with the finding thatV. exanthematicus maintains a constant ratio of ventilation to oxygen uptake (and CO₂ production) at different temperatures (Fig. 3). The increase in arterial (Fig. 1) is related to an increase in physiological dead space; i.e., alveolar ventilation increases less with temperature than total ventilation (Fig. 4). This may result from the increased frequency of breathing which results in a reduced breath holding time (Fig. 2). Varanid lizards have a higher oxygen requirement than other reptiles. This is reflected in the control of ventilation, the specialized lung morphology, the high arterial saturation due to low intracardiac shunting, pH regulation and other mammal-like features ofVaranus.     

Carbon dioxide excretion and carbonic anhydrase function in the Red Rock CrabCancer productus

Summary The function of carbonic anhydrase (CA) in the Red Rock Crab,Cancer productus Randall, was investigated. CA activity was found to varying degrees in the gills and many other tissues but not in hemolymph. Crabs injected with acetazolamide, a specific CA inhibitor, demonstrated a significant hemolymph acidosis. Hemolymph CO₂ tension ( ) and CO₂ content ( ) also increased and remained significantly elevated for 96 h following treatment. No significant changes could be detected in either hemolymph oxygenation or ionic status (except for HCO ₃ ^– ) as a result of acetazolamide treatment. Crabs treated with acetazolamide, and also exposed to air, exhibited a more pronounced hemolymph acidosis with significantly increased respiratory ( ) and metabolic (lactate) components compared with the control group. Upon reimmersion acetazolamide treated crabs showed a slower recovery of hemolymph pH compared with the control group and no significant removal of the total CO₂ load induced by air exposure. No significant differences between experimental and control groups during air exposure and recovery could be detected in hemolymph oxygenation, ionic status, NH₃+NH ₄ ⁺ levels or respiratory and cardiac pumping frequency and so the effects of acetazolamide treatment were apparently limited to CO₂ removal across the gills. These results indicate that branchial CA facilitates the removal of CO₂ from the hemolymph of SW adaptedC. productus largely by catalyzing the dehydration of hemolymph HCO ₃ ^– to molecular CO₂ at the gill. It is also recognized that gill CA may also serve to hydrate molecular CO₂ to H⁺ and HCO_3/– for use as counterions for ionic uptake mechanisms. Crab gill CA thus appears to play an important role in CO₂ excretion as well as hemolymph ionic regulation.     

Ventilation and gas exchange in the diamondback water snake,Natrix rhombifera

Summary Simultaneous measurements of pulmonary and cutaneous oxygen and carbon dioxide exchange, pulmonary ventilation and heart rate were made on the diamondback water snake,Natrix rhombifera at 28°C using body plethysmography. Resting lung volume, maximum lung volume and tracheal volume were also measured.The following mean values were measured in undisturbed snakes breathing room air: total (pulmonary and cutaneous) O₂ uptake 46 mol · (kg min)^–1; total CO₂ output, 49 mol · (kg min)^–1; tidal volume, 12 ml (BTPS) · kg^–1; ventilatory rate, 6.9 min^–1; heart rate, 42 min^–1. From the measurements of tracheal volume, the effective (alveolar) ventilation was estimated as approximately 70% of total ventilation resulting in effective pulmonary and of 130 Torr and 20 Torr respectively. Cutaneous exchange accounted for 8.1% of the total and 12.4% of the total .Resting lung volume of anaesthetized snakes was 75 ml (BTPS) · kg^–1, maximum lung volume was 341 ml (BTPS) · kg^–1 and tracheal volume was 3.9 ml (BTPS) · kg^–1.     

Ventilatory responses to exercise and carbon dioxide in elderly and younger humans

The present investigation examined the relationship between CO₂ sensitivity [at rest (S _R) and during exercise (S _E)] and the ventilatory response to exercise in ten elderly (61–79 years) and ten younger (17–26 years) subjects. The gradient of the relationship between minute ventilation and CO₂ production ( _E/ CO₂) of the elderly subjects was greater than that of the younger subjects [mean (SEM); 32.8 (1.6) vs 27.3 (0.4); P<0.01]. At rest, S _R was lower for the elderly than for the younger group [10.77 (1.72) vs 16.95 (2.13) 1 · min^–1 · kPa^–1; 1.44 (0.23) vs 2.26 (0.28) 1 · min^–1 · mmHg^–1; P<0.05], but S _E was not significantly different between the two groups [17.85 (2.49) vs 19.17 (1.62) l · min^–1 · kPa^–1; 2.38 (0.33) vs 2.56 (0.21) 1 · min^–1 · mmHg^–1]. There were significant correlations between both S _R and S _E, and _E/ CO₂ (P<0.05; P<0.001) for the younger group, bot none for the elderly. The absence of a correlation for the elderly supports the suggestion that _E/ CO₂ is not an appropriate index of the ventilatory response to exercise for elderly humans.     

Effect of chronic acidosis on extra- and intrapulmonary chemoreceptor control of ventilatory movements in the chicken

• 1.1. In 20 cockerels with various degrees of NH₄Cl-induced chronic acidosis, we separated the p_CO2 affecting intrapulmonary chemoreceptors (IPC) from P_aCO2 by ligating the left pulmonary artery, denervating the IPC in the right lung and artificially ventilating each lung separately.
• 2.2. Increased ventilatory depth and decreased ventilatory frequency resulted from (a) increasing P_1CO2 to the innervated non-perfused lung (P_IPCCO2) during constant P_aCO2, (b) increasing P_aCO2 during constant P_IPCCO2 and (c) increasing in the degree of chronic acidosis.
• 3.3. Ventilatory sensitivity to P_IPCCO2but not to P_aCO2 is decreased by chronic acidosis. This coincides with studies where IPC discharge was measured during chronic acidosis and suggests that the mechanism of IPC control of ventilation differs from those of other chemoreceptors.

     

Distribution of greenhouse gases, nitrite, and δ13C of dissolved inorganic carbon in Lake Biwa: Implications for hypolimnetic metabolism

The vertical distribution of dissolved greenhouse gases (CH₄,CO₂ and N₂O), NO ,and ¹³C of CO₂ in Lake Biwa during a stagnantperiod was precisely determined. CO₂ as well as NO was accumulated in the hypolimnion, whereas NO and CH₄concen\-trations were generally higher in theepilimnion than in the hypolimnion. In August, NO andCH₄ were ephemerally accumulated at the thermocline. Theconcentration of CH₄ always exceeded equilibrium with respectto air/water exchange. N₂O was rather uniformly distributed inboth time and space, and remained near equilibrium with respect toair/water exchange. All of these observations are similar to otherstratified, oligotrophic lakes, in which the hypolimnia were welloxygenated. The ¹³C of CO₂ became morenegative with increasing depth, and showed a strong negativecorrelation with apparent oxygen utilization. From the data, the ¹³Cvalue of organic matter decomposed into CO₂ inthe hypolimnion was calculated by isotope mass-balance, and found tobe in a similar range to ¹³C of phytoplankton and benthic algaeand distinctively higher than ¹³C of both terrestrial andsedimentary organic matters. This suggests that autochthonous organicmatter was the major source of CO₂.     

Metabolic cost of sodium transport in toad urinary bladder

Summary The metabolic cost of active sodium transport was determined in toad bladder at different gradients of transepithelial potential, , by continuous and simultaneous measurements of CO₂ production and of transepithelial electric current. Amiloride was used to block active sodium transport in order to assess the nontransport-linked, basal, production of CO₂ and the passive permeability of the tissue. From these determinations active sodium transport,J _Na, and suprabasal CO₂ production, , were calculated. Since large transients inJ _Na and frequently accompanied any abrupt change in , steady state conditions were carefully defined.Some 20 to 40 min were required after a change in before steady state of transport activity and of CO₂ production were achieved. The metabolic cost of sodium transport proved to be the same whether the bladder expended energy moving sodium against a transepithelial electrical potential grandient of +50 mV or whether sodium was being pulled through the active transport pathway by an electrical gradient of –50 mV. In both cases the value of the ratio averaged some 20 sodium ions transported per molecule of CO₂ produced.When the Na pump was blocked by 10^–2 m ouabain, the perturbations of the transepithelial electrical potential did not elicit changes ofJ _Na nor, consequently, of .The independence of the ratio from over the range ±50 mV indicates a high degree of coupling between active sodium transport and metabolism.     

Effect of oxygen on the growth (yield) of Chlorella vulgaris

The growth yield of Chlorella vulgaris, Y _kJ defined as g cells harvested per kJ of light energy absorbed by the cells, was assessed in a turbidostat culture by varying CO₂ and O₂ partial pressures ( and ). The value of Y _kJ ranged from 3.1×10^-3 to 5.0×10^-3 g cells/kJ under light-limited conditions [ = 1.02.4%, = 065%; total pressure of gas (composed of CO₂, O₂ and N₂)=1 atm]. In the light-limited environment, the algal specific growth rate deteriorated appreciably with the increase of . The deterioration accounts for the above range of Y _kJ observed. The growth inhibition due to oxygen that was defined by subtracting from 1.0 the ratio of at given values of to that at = 0% extended from 0.07–0.30 (7–30%). However, glycolate could not be detected in the turbidostat culture. Isotopic experiments on the specific rate of ¹⁴CO₂ uptake also revealed that the inhibition due to oxygen was from 22–38% when was varied from 0 to nearly 100%. These effects of oxygen were discussed, referring to the activity of ribulose-1,5-bisphosphate carboxylase that is inhibited competitively by oxygen.Non-Standard Abbreviations INH isonicotinic acid hydrazide - PPO 2,5-diphenyloxazole - DCMU 3-(-3,4-dichlorophenyl)-1,1-dimetylurea - CA carbonic anhydrase - RuP₂ ribulose-1,5-bisphosphate