MEASUREMENTS OF THE METABOLISM OF TWO PROTOZOANS

1. The respiration of Amoeba proteus was measured. 10 c. mm. of cells were found to use about 1.6 mm.³ of oxygen per hour at 20°C. The respiratory quotient was found to be nearly unity. 2. No anaerobic metabolism was found for Amoeba. 3. The respiration of Blepharisma was found to be from 3 to 7 mm.³ oxygen per hour for 10 mm.³ cells. The respiratory quotient was about 1. 4. Blepharisma was shown to have a definite anaerobic metabolism. 80 mm.³ cells caused the evolution of 12.5 mm.³ carbon dioxide per hour at 20°C. in the presence of bicarbonate.     

THE RESPIRATORY QUOTIENT OF SEEDLINGS OF LUPINUS ALBUS DURING THE EARLY STAGES OF GERMINATION

In germinating seedlings of Lupinus albus, the initial respiratory quotient was found to be unity. After a drop to 0.76 at 9 hours, the value rose to 0.90 at 12 hours, and then fell to 0.64 at 60 hours. It is improbable that the fat oxidation system is the first to become activated.     

RELATION OF OXYGEN TENSION AND TEMPERATURE TO THE TIME OF REDUCTION OF CYTOCHROME

The time for the appearance of the cytochrome C absorption band after shaking a suspension of bakers'' yeast with various O₂-N₂ mixtures was determined at each of six temperatures. At each temperature a linear relation between this interval—called the reduction time—and O₂ tension was found. It was shown: 1. That under our experimental conditions, absorption bands of cytochrome were seen when the O₂ tension of the suspension was reduced to, or below, a certain pressure which was found to be specific for each temperature (this pressure is provisionally considered to be identical with or very near to the "critical O₂ tension" usually found in Q _OO2-O₂-tension relationships); 2. That the x-axis intercept obtained from the reduction time - O₂-tension plot gives the value of the "critical" O₂ pressure at each temperature; 3. That the O₂ tension within the suspension is reduced by the respiratory activity of the yeast cells. An equation describing these observations is given and is used in calculating rates of O₂ consumption from measurements of reduction time of cytochrome. The average difference between the calculated values and the manometric measurements of Q _OO2 was found to be 6.6 per cent. A rapid optical method of measuring rates of O₂ consumption based on the findings of these experiments is proposed for use with cytochrome-containing microorganisms.     

CRITICAL THERMAL INCREMENTS FOR RHYTHMIC RESPIRATORY MOVEMENTS OF INSECTS

The rhythm of abdominal respiratory movements in various insects, aquatic and terrestrial, is shown to possess critical increments 11,500± or 16,500± calories (Libellula, Dixippus, Anax). These are characteristic of processes involved in respiration, and definitely differ from the increment 12,200 calories which is found in a number of instances of (non-respiratory) rhythmic neuromuscular activities of insects and other arthropods. With grasshoppers (Melanoplus), normal or freshly decapitated, the critical increment is 7,900, again a value encountered in connection with some phenomena of gaseous exchange and agreeing well with the value obtained for CO₂ output in Melanoplus. It is shown that by decapitation the temperature characteristic for abdominal rhythm, in Melanoplus, is changed to 16,500, then to 11,300—depending upon the time since decapitation; intermediate values do not appear. The frequency of the respiratory movements seems to be controlled by a metabolically distinct group of neurones. The bearing of these results upon the theory of functional analysis by means of temperature characteristics is discussed, and it is pointed out that a definite standpoint becomes available from which to attempt the specific control of vital processes.     

温度对意大利蝗呼吸代谢的影响

【目的】意大利蝗Calliptamus italicus L.是新疆荒漠、半荒漠草原的主要危害种类,前期研究表明其发生与新疆气候变暖显著相关,本研究进一步探讨气候变暖条件下意大利蝗的呼吸代谢适应机制。【方法】应用多通道昆虫呼吸仪测定了15, 20, 25, 30和35℃不同温度条件下意大利蝗成虫的呼吸率、代谢率、CO₂释放率、Q₁₀(每升高10℃呼吸率的变化幅度)及呼吸商并分析其变化特征。【结果】15℃时意大利蝗成虫的呼吸率、代谢率、CO₂释放率均显著低于其他温度（P<0.01）, 35℃时3项指标值显著高于其他温度（P<0.01）,表明低于15℃和高于35℃的温度条件都对意大利蝗的呼吸代谢产生明显影响;在20~30℃之间,意大利蝗的呼吸率、代谢率及CO2释放率变化幅度小且平稳,差异均不显著（P>0.01）,表明该温度范围是意大利蝗生长发育的适宜温度条件。不同温度下意大利蝗呼吸率的Q₁₀值显示, 20~30℃温度范围内的 Q₁₀值最小,为1.03, 15~25℃的Q10值为1.43, 25~35℃的Q10值最大,为2.42,说明意大利蝗的呼吸代谢活动对温度变化敏感,并表明20~30℃是意大利蝗生长发育的适宜范围。各温度条件下意大利蝗呼吸商的差异不显著（P>0.01）,平均为0.9450,判断意大利蝗呼吸代谢消耗的底物主要为糖类物质。【结论】意大利蝗生长发育的适宜温度范围是20~30℃,预示着在气候持续变暖背景下,意大利蝗仍将是新疆草原最重要的生物灾害之一。     

TEMPERATURE CHARACTERISTICS FOR THE PRODUCTION OF CO2 BY GERMINATING SEEDS OF LUPINUS ALBUS AND ZEA MAYS

The rates of production of CO₂ by germinating seeds of Lupinus albus and Zea mays were studied between temperatures 12.5° and 25°C. with the HCl-Ba(OH)₂ titration method. The temperature characteristics found are different from those previously obtained for the oxygen consumption of the same seeds germinated in the same manner. For Lupinus, the temperature characteristics above and below the critical temperature of 20° are 16,100 ± and 24,000 ± calories respectively. For Zea, no evidence of a critical temperature was found in this region, and the temperature characteristic is 20,750 ± calories throughout the range of temperature tested. The possible interpretations of the difference in the values of temperature characteristics for oxygen consumption and for production of CO₂ are noted.     

Novel Indirect Calorimetry Technology to Analyze Metabolism in Individual Neonatal Rodent Pups

Background

The ability to characterize the development of metabolic function in neonatal rodents has been limited due to technological constraints. Low respiratory volumes and flows at rest pose unique problems, making it difficult to reliably measure O₂ consumption, CO₂ production, respiratory quotient (RQ), and energy expenditure (EE). Our aim was to develop and validate a commercial-grade indirect calorimetry system capable of characterizing the metabolic phenotype of individual neonatal rodents.

Methodology/Principal Findings

To address this research need, we developed a novel, highly sensitive open-circuit indirect calorimetry system capable of analyzing respiratory gas exchange in a single neonatal rodent pup. Additionally, we derived an equation from known metabolic relationships to estimate inlet flow rates, improving the efficiency of data collection. To validate the neonatal rodent indirect calorimetry system and evaluate the applicability of the derived equation for predicting appropriate flow rates, we conducted a series of experiments evaluating the impact of sex, litter size, time of day (during the light phase), and ambient temperature on neonatal rat metabolic parameters. Data revealed that the only metabolic parameter influenced by litter size is a neonatal rat''s RQ, with rat pups reared in a small litter (5 pups) having lower RQ''s than rat pups reared in either medium (8 pups) or large (11 pups) litters. Furthermore, data showed that ambient temperature affected all metabolic parameters measured, with colder temperatures being associated with higher CO₂ production, higher O₂ consumption, and higher energy expenditure.

Conclusion/Significance

The results of this study demonstrate that the modified Panlab Oxylet system reliably assesses early postnatal metabolism in individual neonatal rodents. This system will be of paramount importance to further our understanding of processes associated with the developmental origins of adult metabolic disease.     

THE RATE OF OXYGEN UTILIZATION BY YEAST AS RELATED TO TEMPERATURE

Suspensions of the yeast Saccharomyces cerevisiae gave reproducible rates of O₂ uptake over a period of 6 months. The relation of rate of consumption of O₂ to temperature was tested over a wide range of temperatures, and the constant in the formulation of the relationship is found to be reproducible. The values of this constant (µ) have been obtained for five separate series of experiments by three methods of estimation. The variability of µ has the following magnitudes: the average deviation of a single determination expressed as per cent of the mean is ±2 per cent in the range 30–15°, and ±0.8 per cent in the range 15–3°C. This constancy of metabolic activity measured as a function of temperature can then be utilized for more precise investigations of processes controlling the velocity of oxidations of substrates, and of respiratory systems controlled by intracellular respiratory pigments. The data plotted according to the Arrhemus equation give average values of the constant µ as follows: for the range 35–30°, µ = 8,290; 30–15°, µ = 12,440 ±290; 15–3°, µ = 19,530 ±154. The critical temperatures are at 29.0° and 15.7°C. A close similarity exists between these temperature characteristics (µ) and values in the series usually obtained for respiratory activities in other organisms. This fact supports the view that a common system of processes controls the velocities of physiological activities in yeast and in other organisms.     

TEMPERATURE CHARACTERISTICS FOR THE METABOLISM OF CHLORELLA : II. THE RATE OF RESPIRATION OF CULTURES OF CHLORELLA PYRENOIDOSA AS A FUNCTION OF TIME AND OF TEMPERATURE

The respiration of the green alga Chlorella pyrenoidosa, suspended in Knop''s solution, has been studied in the dark as a function of time and of temperature. The rates of oxygen consumption and of carbon dioxide production (at constant temperature) decline for about 25 hours to a low, constant level. From an analysis of the curves it is suggested that two substances, A and B, are utilized, whose respiratory quotients are 1 and 0.65 respectively. The values of the temperature characteristics were found to be: for oxidation of A, 19,500 (0.6 to 11.5°C.) and 3,500 (11.5 to 28°C.); for oxidation of B, 5,600 (23.4 to 0.6°C.).     

Energy Metabolism of Rumex Leaf Tissue in the Presence of Senescence-regulating Hormones and Sucrose

Hormones which inhibit senescence of Rumex leaf tissue in the dark include gibberellin A₃, and the cytokinins 6-benzylamino purine and zeatin. These hormones inhibit respiratory metabolism in this tissue, but do not change the pattern or total amount of oxygen consumption during senescence. Abscisic acid, a senescence accelerator, correspondingly stimulates oxygen consumption. This correlation of senescence rate and respiration rate holds with regard to the hormone concentrations effective and the continued activity of the hormones when added after the lag phase of chlorophyll breakdown. Transfer experiments show that the respiratory inhibition due to gibberellin A₃ and the promotion due to abscisic acid become established within 3 hours of hormone addition. When gibberellin A₃ and zeatin were rapidly added to narrow strips of tissue, no inhibitions of oxygen uptake were observed in the first 12 minutes. Senescence-inhibiting concentrations of sucrose strongly stimulate respiratory meabolism, raise the respiratory quotient, and cause inhibition of chlorophyll and protein breakdown which is distinct from the effect of gibberellins or cytokinins.     

Respiration during Postharvest Development of Soursop Fruit, Annona muricata L

Fruit of soursop, Annona muricata L., showed increased CO₂ production 2 days after harvest, preceding the respiratory increase that coincided with autocatalytic ethylene evolution and other ripening phenomena. Experiments to alter gas exchange patterns of postharvest fruit parts and tissue cylinders had little success.

The respiratory quotient of tissue discs was near unity throughout development. 2,4-Dinitrophenol uncoupled respiration more effectively than carbonylcyanide m-chlorophenylhydrazone; 0.4 millimolar KCN stimulated, 4 millimolar salicylhydroxamic acid slightly inhibited, and their combination strongly inhibited respiration, as did 10 millimolar NaN₃. Tricarboxylic acid cycle members and ascorbate were more effective substrates than sugars, but acetate and glutarate strongly inhibited.

Disc respiration showed the same early peak as whole fruit respiration; this peak is thus an inherent characteristic of postharvest development and cannot be ascribed to differences between ovaries of the aggregatetype fruit. The capacity of the respiratory apparatus did not change during this preclimacteric peak, but the contents of rate-limiting malate and citrate increased after harvest.

It is concluded that the preclimacteric rise in CO₂ evolution reflects increased mitochondrial respiration because of enhanced supply of carboxylates as a substrate, probably induced by detachment from the tree. The second rise corresponds with the respiration during ripening of other climacteric fruits.

     

THE GROWTH AND RESPIRATION OF THE AVENA COLEOPTILE

1. Transport of the plant growth hormone into the Avena coleoptile as well as the action of the hormone on cell elongation in the coleoptile are shown to depend upon aerobic metabolism. 2. Crystalline auxine, in contrast with impure preparations, affects neither the magnitude nor the respiratory quotient of coleoptile respiration. 3. Increasing age of the coleoptile cell decreases its rate of elongation much more than its rate of respiration. HCN or phenylurethane on the other hand decrease the two processes to the same extent, in spite of the fact that only a small portion of the energy liberated by respiration can be used in the mechanical process of growth. 4. From 2 and 3 it is concluded that processes of a respiratory nature but of relatively small magnitude form one or more integral steps in the chain of reactions by which the plant growth hormone brings about cell elongation.     

Body temperature and metabolic rate during natural hypothermia in endotherms

During daily torpor and hibernation metabolic rate is reduced to a fraction of the euthermic metabolic rate. This reduction is commonly explained by temperature effects on biochemical reactions, as described by Q ₁₀ effects or Arrhenius plots. This study shows that the degree of metabolic suppression during hypothermia can alternatively be explained by active downregulation of metabolic rate and thermoregulatory control of heat production. Heat regulation is fully adequate to predict changes in metabolic rate, and Q ₁₀ effects are not required to explain the reduction of energy requirements during hibernation and torpor.Abbreviations BMR basal metabolic rate - BW body weight - C thermal conductance - C_HL thermal conductance as derived from HL - C_HP thermal conductance as derived from HP - HL heat loss - HP heat production - MR metabolic rate - RQ respiratory quotient - T_a ambient temperature - T_b body temperature     

Effect of ambient temperature on thermal sensitivity of POAH area in the rabbit

The POAH area of five conscious, male rabbits was heated with an electric thermode. The hypothalamic temperature threshold (ΔT_hy) for thermoregulatory reactions was determined at ambient temperatures of 12, 16, 20 and 24°C. The ΔT_hy for cutaneous vasolidation decreased with increasing ambient temperature. By contrast, the ΔT_hy for respiratory reaction was not dependent on ambient but only on hypothalamic temperature. After the start of hypothalamic heating, thermoregulatory reactions developed in the following characteristic order: vasodilation in the nose area, ear vasodilation and respiratory reaction. It is concluded that in order to increase heat loss rabbits first utilize cutaneous vasodilation. When this becomes insufficient, as indicated by an increase in hypothalamic temperature.     

Radiorespirometer for continuous monitoring of chick embryo development.

A radiorespirometer is described that is capable of continuous monitoring of O₂ utilization, CO₂ and/or ¹⁴CO₂ production per minute, heart rate, and body activity of an embryonated egg while it develops for several days in a closed chamber with near normal pO₂ or other desired pO₂. Oxygen is supplied to the embryo by an electrolytic cell, and CO₂ is removed by a KOH solution flowing through a diffusion cell separated from the embryo chamber by a CO₂ permeable rubber membrane. The instrument permits selecting embryos for viability and developmental stage, according to their O₂ utilization per minute and respiratory quotient, without breaking the eggshell. Inoculation of the embryonated egg with ¹⁴C-labeled substrates, drugs, or toxins can occur without interfering with continuous recording of metabolic activity.     

Higher Thermal Acclimation Potential of Respiration but Not Photosynthesis in Two Alpine Picea Taxa in Contrast to Two Lowland Congeners

The members of the genus Picea form a dominant component in many alpine and boreal forests which are the major sink for atmospheric CO₂. However, little is known about the growth response and acclimation of CO₂ exchange characteristics to high temperature stress in Picea taxa from different altitudes. Gas exchange parameters and growth characteristics were recorded from four year old seedlings of two alpine (Picea likiangensis vars. rubescens and linzhiensis) and two lowland (P. koraiensis and P. meyeri) taxa. Seedlings were grown at moderate (25°C/15°C) and high (35°C/25°C) day/night temperatures, for four months. The approximated biomass increment (ΔD²H) for all taxa decreased under high temperature stress, associated with decreased photosynthesis and increased respiration. However, the two alpine taxa exhibited lower photosynthetic acclimation and higher respiratory acclimation than either lowland taxon. Moreover, higher leaf dry mass per unit area (LMA) and leaf nitrogen content per unit area (N_area), and a smaller change in the nitrogen use efficiency of photosynthesis (PNUE) for lowland taxa indicated that these maintained higher homeostasis of photosynthesis than alpine taxa. The higher respiration rates produced more energy for repair and maintenance biomass, especially for higher photosynthetic activity for lowland taxa, which causes lower respiratory acclimation. Thus, the changes of ΔD²H for alpine spruces were larger than that for lowland spruces. These results indicate that long term heat stress negatively impact on the growth of Picea seedlings, and alpine taxa are more affected than low altitude ones by high temperature stress. Hence the altitude ranges of Picea taxa should be taken into account when predicting changes to carbon fluxes in warmer conditions.     

Metabolic responses of sand fiddler crabs, Uca pugilator, in northwest Florida to seasonal temperature change

Metabolic responses of sand fiddler crab, Uca pugilator, populations in northwest Florida are greatly influenced by seasonal temperature fluctuations. Crabs acclimated at 20 °C and immediately transferred to either 14 or 26 °C produced an acute metabolic response with respective temperature quotient (Q₁₀) values of 3.46 and 3.91. Crabs acclimated at 10 and 20 °C exhibited a Q₁₀ of 2.62 indicating a partial compensation response. A brumation (reverse) response (Q₁₀ value of 20.11) was observed for acclimated crabs between 5 and 10 °C. Brumation is advantageous during winter when food supplies are scarce and crabs must survive extensive periods of inactivity.     

OBSERVATIONS ON THE RESPIRATION OF TRYPANOSOMA CRUZI IN CULTURE

1. The oxygen consumption of cultural forms of Trypanosoma cruzi decreases in intensity with increasing age of the cultures; no correlation with any other factor studied could be established. 2. The respiratory quotient was high for the first 10 days, i.e. as long as the population increased; with the onset of a decline in numbers, the R.Q. began to drop. It is believed that the flagellates consume in the beginning predominantly sugar and later predominantly protein. Observations on the pH of the cultures bear out this view. 3. The oxygen consumption was independent of the oxygen tension over a wide range of tensions. 4. The oxygen consumption increased in the temperature range 13° to 40°C., while a temperature of 44°C. proved to be lethal. Upon application of Arrhenius'' equation, two straight lines, intersecting at about 28°C., resulted. The µ values were 23,980 and 5275 for the lower and higher temperature range respectively. 5. Of the oxidase inhibitors tested, strong inhibition of the oxygen consumption was achieved with azide, cyanide, and hydrogen sulfide. Pyrophosphate had no influence at all. There is some probability that cytochrome oxidase is the chief oxidase present. 6. The strongest inhibitory influence due to dehydrogenase inhibitors was observed with propyl carbamate and high concentrations of ethyl carbamate. 7. A small fraction of the oxygen consumption, about 10 per cent, may be due to substances with sulfhydryl groups, as indicated by a slight but distinct inhibition due to dilute iodoacetate and to arsenite.     

Use of glucose and carbon isotope fractionation by microbial cells immobilized on solid-phase surface

By the example of glucose uptake by the soil bacteria Pseudomonas aureofaciens BS1393(pBS216) and Rhodococcus sp. 3–30 immobilized on a solid-phase surface (quartz sand), their growth parameters were determined: growth rate (doubling time), total CO₂ production, CO₂ production per cell, lag period with respect to substrate uptake, respiratory quotient. The growth of P. aureofaciens and Rhodococcus sp. on glucose revealed (1) differences of the lag period with respect to substrate (lag time of ～4 h for P. aureofaciens and ～26 h for Rhodococcus sp.); (2) differences between the maximal rates of CO₂ production (～50 μg C-CO₂ g^?1 sand h^?1 for P. aureofaciens and ～8.5 μg C-CO₂ g^?1 sand h^?1 for Rhodococcus sp.); (3) differences in CO₂ production per cell (～1.94 × 10^?9 μM CO₂/CFU for P. aureofaciens and more than ～3.4 × 10^?9 μM CO₂/CFU for Rhodococcus sp.). The kinetics of the metabolic CO₂ isotopic composition was shown to be determined by the difference in the carbon isotopic characteristics of products in the cell. Upon introduction of glucose into the medium (the preparatory stage of the metabolism), the uptake of intracellular ¹³C-depleted products (lipids) is noted; at the stage of the maximal cell growth rate, introduced glucose is mainly metabolized; and at the final stage, upon exhaustion of substrate, the “stored” products—the lipid fraction—get involved in the metabolism. At the maximal rate of glucose uptake, the CO₂ carbon isotopic fractionation coefficient relative to organic products of microbial biosynthesis was determined to be α = 1.009 ± 0.002.     

THE EFFECTS OF RADIATIONS ON BIOLOGICAL SYSTEMS : II. IMMEDIATE AND SUBSEQUENT EFFECTS OF X-RAY IRRADIATION UPON RESPIRATION OF DROSOPHILA LARVAE

By means of measurement of CO₂ respiratory rates it has been possible to observe immediate and latent effects of x-ray irradiations upon Drosophila larvae. The observations were extended over a period of several days, the duration of the prepupal period being observed also. In every instance a significant decrease in the rate of CO₂ respiration was observed immediately after irradiation. This decrease was univariant with the period of irradiation within the experimental limits.