THE EXCRETION OF CARBON DIOXIDE BY FROG NERVE

1. Quiescent sciatic nerve of the frog discharges CO₂ at the average rate of 0.00876 mg. CO₂ per gram of nerve per minute. 2. Sciatic nerve steeped one minute in boiling water discharges CO₂ at first at a low rate and after an hour and a half not at all. 3. Degenerated sciatic nerve discharges CO₂ at a slightly higher rate than normal living nerve does. 4. Connective tissue from the frog discharges CO₂ at an average rate of 0.0097 mg. per gram of tissue per minute. 5. Assuming that a nerve is composed of from one-half to one-quarter connective tissue the CO₂ output from its strictly nervous components is estimated to be at a rate of 0.008 mg. CO₂ per gram of nerve per minute. 6. Stimulated sciatic nerve increases the rate of its CO₂ output over quiescent nerve by about 14 per cent. When this number is corrected for strictly nervous tissue the rate is about 16 per cent. 7. The increased rate of CO₂ production noted on stimulation in normal sciatic nerves was not observed when they were boiled, blocked, or degenerated. It was also not observed with stimulated strands of connective tissue.     

Prostanoid Receptors Involved in Regulation of the Beating Rate of Neonatal Rat Cardiomyocytes

Although prostanoids are known to be involved in regulation of the spontaneous beating rate of cultured neonatal rat cardiomyocytes, the various subtypes of prostanoid receptors have not been investigated in detail. In our experiments, prostaglandin (PG)F_2α and prostanoid FP receptor agonists (fluprostenol, latanoprost and cloprostenol) produced a decrease in the beating rate. Two prostanoid IP receptor agonists (iloprost and beraprost) induced first a marked drop in the beating rate and then definitive abrogation of beating. In contrast, the prostanoid DP receptor agonists (PGD₂ and BW245C) and TP receptor agonists (U-46619) produced increases in the beating rate. Sulprostone (a prostanoid EP₁ and EP₃ receptor agonist) induced marked increases in the beating rate, which were suppressed by SC-19220 (a selective prostanoid EP₁ antagonist). Butaprost (a selective prostanoid EP₂ receptor agonist), misoprostol (a prostanoid EP₂ and EP₃ receptor agonist), 11-deoxy-PGE₁ (a prostanoid EP₂, EP₃ and EP₄ receptor agonist) did not alter the beating rate. Our results strongly suggest that prostanoid EP₁ receptors are involved in positive regulation of the beating rate. Prostanoid EP₁ receptor expression was confirmed by western blotting with a selective antibody. Hence, neonatal rat cardiomyocytes express both prostanoid IP and FP receptors (which negatively regulate the spontaneous beating rate) and prostanoid TP, DP₁ and EP₁ receptors (which positively regulate the spontaneous beating rate).     

Influence of environmental factors on endo-β-1,4-glucanase production by Bacillus HR68, isolated from a Zimbabwean hot spring

The production of endo-β-1,4-glucanase by a Bacillus strain isolated from a hot spring in Zimbabwe was studied in batch culture, chemostat culture, and carbon dioxide-regulated auxostat (CO₂-auxostat). The bacteria produced the enzyme in the presence of excess glucose or sucroso, but not under carbon-limited conditions in a chemostat using mineral medium. There was a specific growth rate dependent linear increase in enzyme production in glucose excess, nitrogen-limited chemostat cultures. A high specific growth rate of 2.2 h^-1 and a high rate of enzyme production of 362 nkat (mg dry mass h)^-1 were attained under nutrient rich conditions in the CO₂-auxostat. The bacteria had the highest specific growth rate and endo-β-1,4-glucanase enzyme production at 50° C. The maximum specific growth rate and the rate of enzyme production increased when yeast extract and tryptone were added in increasing amounts to the mineral medium used for cultivation in separate experiments. Increasing the glucose concentration in the CO₂-auxostat cultures increased the rate of enzyme production but did not affect the specific growth rate.     

Nitrate Uptake by Dark-grown Corn Seedlings: Some Characteristics of Apparent Induction

Five-or six-day old seedlings of corn (Zea mays L.) were exposed to 0.25 mm Ca(NO₃)₂, 1.0 mm sodium 2-[N-morpholino]-ethanesulfonate, 5 μg Mo per liter and 50 μg of chloramphenicol per ml at pH 6. Nitrate uptake was determined from depletion of the ambient solution. The pattern of nitrate uptake was characterized, after the first 20 minutes, by a low rate which increased steadily to a maximal rate by 3 to 4 hours. Transfer of nitrate to the xylem did not totally account for the increase. Development of the maximal accelerated rate did not occur at 3 C with excised roots nor with seedlings whose endosperm had been removed. Use of CaCl₂ rather than Ca(NO₃)₂ resulted in a linear rate of chloride uptake during the first 4 hours, and chloride uptake was not as restricted by endosperm removal as was nitrate uptake.     

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).     

Elevated CO2 effects on decomposition processes in a grazed grassland

The effects of elevated atmospheric CO₂ (475 μL L^?1) on in situ decomposition of plant litter and animal faecal material were studied over 2 years in a free air CO₂ enrichment (FACE) facility. The pasture was grazed by sheep and contained a mixture of C₃ and C₄ grasses, legumes and forbs. There was no effect of elevated CO₂ on decomposition within plant species but marked differences between species with faster decomposition in dicots; a group that increased in abundance at elevated CO₂. Decomposition of mixed herbage root material occurred at a similar rate to that of leaf litter suggesting that any CO₂‐induced increase in carbon allocation to roots would not reduce rates of decomposition. Sheep faeces resulting from a ‘high‐CO₂ diet’ decomposed significantly slower during summer but not during winter. The overall outcome of these experiments were explored using scenarios that took account of changes in botanical composition, allocation to roots and the presence of herbivores. In the absence of herbivores, elevated CO₂ led to a 15% increase in the rate of mass loss and an 18% increase in the rate of nitrogen (N) release. In the presence of herbivores, these effects were partially removed (11% increase in rate of mass loss and 9% decrease in N release rate) because of the recycling occurring through the animals in the form of faeces.     

Does the γ subunit move to an abortive position for ATP hydrolysis when the F1·ADP·Mg complex isomerizes to the inactive F1*·ADP·Mg complex?

F₁-ATPases transiently entrap inhibitory MgADP in a catalytic site during turnover when noncatalytic sites are not saturated with ATP. An initial burst of ATP hydrolysis rapidly decelerates to a slow intermediate rate that gradually accelerates to a final steady-state rate. Transition from the intermediate to the final rate is caused by slow binding of ATP to noncatalytic sites which promotes dissociation of inhibitory MgADP from the affected catalytic site. Evidence from several laboratories suggests that the γ subunit rotates with respect to α/β subunit pairs of F₁-ATPases during ATP hydrolysis. The α₃β₃ and α₃β₃δ subcomplexes of the TF₁-ATPase do not entrap inhibitory MgADP in a catalytic site during turnover, suggesting involvement of the γ subunit in the entrapment process. From these observations, it is proposed that the γ subunit moves into an abortive position for ATP hydrolysis when inhibitory MgADP is entrapped in a catalytic site during ATP hydrolysis.     

Prostaglandins and pacemaker activity in isolated guinea pig SA node

Prostaglandins PGE₂, PGE₁, PGF_2α, and PGA₁ substantially increase automaticity in SA-nodal, right atrial preparations excised from guinea pigs. This natural pacemaker tissue is sensitive to nanomolar doses of PG with, for example, 10⁻⁸ M PGE₂, increasing SA rate by about 20%. If these preparations are pretreated with 2 μM indomethacin, a blocker of endogenous prostaglandin synthesis, then spontaneous rate drops and subsequent rate increases due to PGE₂ administration can be more easily demonstrated. Guinea pig pacemaker tissue differs from similar rabbit tissue not only in that it is directly responsive to PGE₂, but also in that PGE₂ does not depress the absolute response to transmural stimulation (adrenergically mediated rate increase). The positive chronotropic responses to PGE₂ also occur when the guinea pig tissue is pretreated in 0.6 μM propranolol, which causes blockade of beta-adrenergic receptors.The pacemaker myocardium in the guinea pigs thus appears to be directly stimulated by exogenous PGE₂ at very low doses. The observation that 2 μM indomethacin reduces SA-nodal rate suggests the presence of a very sensitive, functionally important, PGE-like system which modulates heart rate in this mammalian species.     

Studies on acidification of media by Avena stem segments in the presence and absence of gibberellic Acid

The rate of acidification of media by Avena stem segments was studied with a titrimeter. GA₃ increased this rate by an average of 17% if supplied to the segments 90 min prior to measurement. GA₃ inhibited the rate by 15% if supplied 10 min prior to measurement. After 90 min incubation, stimulation of elongation had started; at 10 min, GA₃ had not yet started to stimulate elongation in the segments.     

Effect of oxygen tension on stability and expression of a killer toxin chimeric plasmid in a chemostat culture of Saccharomyces cerevisiae

Summary The effects of oxygen tension and dilution rate on expression and stability of killer toxin chimeric plasmid (pADH-10A) in transformants of wine yeast (Montrachet 522) were investigated using a glucose-limited chemostat culture. Killer toxin activity increased as a function of dilution rate when transformants were grown in N₂ or air, but not in 100% O₂. Killer transformants grown in the presence of N₂ had 2–4 fold and 10–15 fold higher toxin expression than that in the presence of air and 100% O₂, respectively. Plasmid stability increased as a function of dilution rate, regardless of the oxygen tension used. However, transformants grown in air gave the highest plasmid stability.Paper Number 10918 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC 27695. The use of trade names in this publication does not imply endorsement by the North Carolina Agricultural Research Service of the products named. nor criticism of similar ones not mentioned.     

Evaluation of early embryonic mortality in donor insemination by a mathematical model,globally and depending on semen quality

Stating the probability of pregnancy per cycle as P_oP_FP_v, the product of the probabilities of ovulation, fertilization, and egg viability, the model allows an estimate of P_F and P_oP_v for a series of cycles with known insemination timing. Such results obtained from a series of donor insemination (AID) compared with those generally admitted in natural reproduction suggest that the lower pregnancy rate in AID (all the lower when the postthaw motility is low) is owing to a lower egg viability. Since the abortion rate does not seem higher, there might be a sizable rate of very early embryonic deaths in AID perhaps even as early as nondeveloping eggs.     

Indirekte Regelmechanismen der Stoffwechselgröße von Fischen

Metabolic rate does not strictly follow changes of influencing parameters. O₂-consumption by fish is ordinarily said to be independent from O₂-pressure throughout a wide range. This constancy is probably the result of a regulation. The metabolic rate itself or an auxiliary mechanism “before” or “after” metabolism may be regulated. On the basis of vanDam's paper (1938) and our own experiments, the problem whether or not O₂-pressure in blood serves as a regulated auxiliary mechanism in order to maintain a certain metabolic constancy is discussed. The disadvantage of such a regulation would be the energy demand of increased ventilation and circulation as compensating mechanisms. In accordance with this assumption we have found a rise in O₂-consumption at a somewhat reduced O₂-pressure. Locomotory behaviour supports the constancy of metabolic rate; thus a contrary shift of the temperature preferendum after application of substances which influence metabolism has been found.     

Effects of CO(2) Enrichment and Carbohydrate Content on the Dark Respiration of Soybeans

During the period of most active leaf expansion, the foliar dark respiration rate of soybeans (Glycine max cv Williams), grown for 2 weeks in 1000 microliters CO₂ per liter air, was 1.45 milligrams CO₂ evolved per hour leaf density thickness, and this was twice the rate displayed by leaves of control plants (350 microliters CO₂ per liter air). There was a higher foliar nonstructural carbohydrate level (e.g. sucrose and starch) in the CO₂ enriched compared with CO₂ normal plants. For example, leaves of enriched plants displayed levels of nonstructural carbohydrate equivalent to 174 milligrams glucose per gram dry weight compared to the 84 milligrams glucose per gram dry weight found in control plant leaves. As the leaves of CO₂ enriched plants approached full expansion, both the foliar respiration rate and carbohydrate content of the CO₂ enriched leaves decreased until they were equivalent with those same parameters in the leaves of control plants. A strong positive correlation between respiration rate and carbohydrate content was seen in high CO₂ adapted plants, but not in the control plants.

Mitochondria, isolated simultaneously from the leaves of CO₂ enriched and control plants, showed no difference in NADH or malate-glutamate dependent O₂ uptake, and there were no observed differences in the specific activities of NAD⁺ linked isocitrate dehydrogenase and cytochrome c oxidase. Since the mitochondrial O₂ uptake and total enzyme activities were not greater in young enriched leaves, the increase in leaf respiration rate was not caused by metabolic adaptations in the leaf mitochondria as a response to long term CO₂ enrichment. It was concluded, that the higher respiration rate in the enriched plant's foliage was attributable, in part, to a higher carbohydrate status.

     

THE PRODUCTION OF CARBON DIOXIDE BY NERVE

1. A modified Osterhout respiratory apparatus for the detection of CO₂ from nerve is described. 2. The lateral-line nerve from the dogfish discharges CO₂ at first with a gush for half an hour or so and then steadily at a lower rate for several hours. 3. Simple handling of the nerve does not increase the output of CO₂; cutting it revives gush. 4. The CO₂ produced by nerve is not escaping simply from a reservoir but is a true nervous metabolite. 5. The rate of discharge of CO₂ from a quiescent nerve varied from 0.0071 to 0.0128 mg. per gram of nerve per minute and averaged 0.0095 mg. 6. Stimulated nerve showed an increased rate of CO₂ production of 15.8 percent over that of quiescent nerve. 7. The results of these studies indicate that chemical change is a factor in nerve transmission.     

The effect of carbon dioxide concentration on respiration of growing and mature soybean leaves

Soybean plants were grown continuously at 350 and 700cm³m^?3 CO₂ at constant temperature. Respiration rates of third trifoliolate leaves were measured at the growth CO₂ concentration for the whole dark period from 5d before through to 5d after full area expansion. The short-term response of respiration rate to the measurement CO₂ concentration was also determined at each age. Respiration rates per unit of dry mass declined with age and were significantly less at a given age or RGR in leaves grown and measured at the elevated CO₂. The difference in respiration rate was largest in mature leaves and resulted from the different measurement CO₂ concentrations. The respiratory costs of the tissue synthesis, estimated from the elemental composition of the tissue, did not differ substantially between CO₂ treatments. The response of respiration rate to carbon dioxide concentration was not strongly affected by the form of nitrogen supplied. Maintenance respiration calculated by subtracting growth respiration from total respiration was negative in rapidly growing leaves for both CO₂ treatments. This indicates that CO₂ efflux in the dark does not accurately reflect the average 24 h rate of energy expenditure on growth and maintenance for soybean leaves.     

Interferon Treatment of Ehrlich Ascites Tumor Cells: Effects on Exogenous mRNA Translation and tRNA Inactivation in the Cell Extract

We reported earlier that in cell extracts that were prepared from interferon-treated Ehrlich ascites tumor cells and preincubated and passed through Sephadex G-25 (S30_INT), the translation of exogenous mRNA (viral and host) was impaired and the impairment could be overcome to a large extent by adding a crude tRNA preparation from Ehrlich ascites tumor cells but not from Escherichia coli. We find now that the rate of inactivation of some tRNA's (especially those specific for leucine, lysine, and serine) but not those of many others is faster in S30_INT than in corresponding extracts from control cells. This increased rate of tRNA inactivation may perhaps account for the need for added RNA to overcome at least partially the impairment of translation in S30_INT. The relationship of the increased rate of tRNA inactivation to the antiviral effect of interferon is unclear. So far no significant difference has been detected in the amount of tRNA needed to overcome the impairment of encephalomyocarditis virus RNA translation in S30_INT between tRNA from interferon-treated cells and tRNA from control cells. Furthermore, no difference was found in the rate of inactivation in S30_INT between leucine-specific tRNA's from interferon-treated and from control cells. tRNA's specific for leucine and lysine were not inactivated (unless very slowly) during incubation under our conditions in an extract from interferon-treated (or from control) cells unless the extract had been passed through Sephadex G-25 or dialyzed. The translation of exogenous mRNA was, however, impaired in an extract from interferon-treated cells that had not been passed through Sephadex G-25. This impairment was apparently not overcome by added tRNA.     

Inhibition of photosynthetic carbon dioxide fixation in isolated spinach chloroplasts exposed to reduced osmotic potentials

Reduced osmotic potentials inhibited the rate of CO₂ fixation by isolated intact spinach (Spinacia oleracea) chloroplasts. This inhibition was observed immediately after transfer of chloroplasts from a solution containing 0.33 m sorbitol to higher sorbitol concentrations, and the depressed rate remained constant. The inhibited CO₂ fixation could not be attributed to a decreased rate of photosynthetic electron transport, since NADP reduction was unaffected by subjecting the chloroplasts to low potentials. It could also not result from restricted permeability to CO₂, as CO₂ concentrations had no effect on the relative inhibition induced by the lowered potential.     

In vitro liver clearance of tritiated estradiol-17β in the female rat after retrochiasmatic transection and ovariectomy

It was reported in a previous study that serum estradiol-17β (E₂) was elevated in rats after retrochiasmatic transection (FC). Serum E₂ was also higher in estradiol cypionate treated, ovariectomized (ovx) rats that had been subjected to FC than in those that had not. This suggested that increased secretion of E₂ was not the only factor responsible for elevated serum E₂ after FC. To ascertain the contribution of decreased metabolism of E₂ to this response, liver tissue slices were incubated with 3H-estradiol-17β, and the rates of ³h uptake and conversion to water-soluble conjugates were measured.The rate of uptake of ³H by the tissue was not indicative of the rate of conjugate formation. Livers of rats with high serum E₂ exhibited lower rates of ³h uptake than those of rats with low serum E₂. Even so, the formation of ³H conjugates was greater in liver of rats with high serum E₂. As hypothesized, livers of rats with FC formed conjugates at a significantly lower rate than those of similarly treated rats without FC. Thus, FC of an intact rat leads to an increase in serum E₂ by increasing the secretion of E₂, and apparently also by decreasing the rate of E₂ metabolism by the liver.     

Isoprene emission from aspen leaves : influence of environment and relation to photosynthesis and photorespiration

Isoprene emission rates from quaking aspen (Populus tremuloides Michx.) leaves were measured simultaneously with photosynthesis rate, stomatal conductance, and intercellular CO₂ partial pressure. Isoprene emission required the presence of CO₂ or O₂, but not both. The light response of isoprene emission rate paralleled that of photosynthesis. Isoprene emission was inhibited by decreasing ambient O₂ from 21% to 2%, only when there was oxygen insensitive photosynthesis. Mannose (10 millimolar) fed through cut stems resulted in strong inhibition of isoprene emission rate and is interpreted as evidence that isoprene biosynthesis requires either the export of triose phosphates from the chloroplast, or the continued synthesis of ATP. Light response experiments suggest that photosynthetically generated reductant or ATP is required for isoprene biosynthesis. Isoprene biosynthesis and emission are not directly linked to glycolate production through photorespiration, contrary to previous reports. Isoprene emission rate was inhibited by above-ambient CO₂ partial pressures (640 microbar outside and 425 microbar inside the leaf). The inhibition was not due to stomatal closure. This was established by varying ambient humidity at normal and elevated CO₂ partial pressures to measure isoprene emission rates over a range of stomatal conductances. Isoprene emission rates were inhibited at elevated CO₂ despite no change in stomatal conductance. Addition of abscisic acid to the transpiration stream dramatically inhibited stomatal conductance and photosynthesis rate, with a slight increase in isoprene emission rate. Thus, isoprene emission is independent of stomatal conductance, and may occur through the cuticle. Temperature had an influence on isoprene emission rate, with the Q₁₀ being 1.8 to 2.4 between 35 and 45°C. At these high temperatures the amount of carbon lost through isoprene emission was between 2.5 and 8% of that assimilated through photosynthesis. This represents a significant carbon cost that should be taken into account in determining midsummer carbon budgets for plants that are isoprene emitters.     

Interactions between Glucose and Inorganic Carbon Metabolism in Chlorella vulgaris Strain UAM 101

Chlorella vulgaris strain UAM 101 has been isolated from the effluent of a sugar refinery. This alga requires glucose to achieve maximal growth rate even under light saturating conditions. The growth rate of cultures grown on light + CO₂ + glucose (3.16 per day) reaches the sum of those grown on light + CO₂ (1.95 per day) and on dark + glucose (1.20 per day). Unlike other Chlorella strains, uptake of glucose (about 2 micromoles per milligram dry weight per hour) was induced to the same extent in the light and dark and was not photosensitive. The rate of dark respiration was not affected by light and was strongly stimulated by the presence of glucose (up to about 40% in 4 hours). The rate of photosynthetic O₂ evolution was measured as a function of the CO₂ concentration. These experiments were conducted with cells which experienced different concentrations of CO₂ or glucose during growth. The maximal photosynthetic rate was inhibited severely by growing the cells in the presence of glucose. A rather small difference in the apparent photosynthetic affinity for extracellular inorganic carbon (from 10-30 micromolar) was found between cells grown under low and high CO₂. Growth with glucose induced a reduction in the apparent affinity (45 micromolar) even though cells had not been provided with CO₂. Experiments performed at different pH values indicate CO₂ as the major carbon species taken from the medium by Chlorella vulgaris UAM 101.