THE METABOLIC SYSTEMS INVOLVED IN DISSIMILATION OF CARBOHYDRATE RESERVES IN BAKERS' YEAST

Evidence is presented showing that the dissimilation of carbohydrate reserves in two strains of bakers'' yeast, Saccharomyces cerevisiae, is a purely respiratory process. Endogenous respiration is KCN-labile. Our own experiments together with various accounts and data given in the literature show that the same "oxygen-transporting mechanism" functions in both endogenous and exogenous metabolism. However, the lack of sensitivity of the endogenous system of reactions to low concentrations of monoiodoacetic acid, the absence of anaerobic CO₂ production, and the absence of alcohol production, demonstrate that fermentation is not involved in the dissimilation of the carbohydrate reserves. Throughout the experiments the endogenous respiration behaved functionally as a unitary system of reactions. The O₂ consumption and CO₂ production were parallel at all times; i.e., the R. Q. was consistently 1. Monoiodoacetic acid and KCN in concentrations from 10^–5 to 10^–1 molar affected both O₂ uptake and CO₂ production to the same extent. The only agents known to alter the value of the R. Q. were those which disrupted the normal protoplasmic structure, viz. grinding the cells with sand, plasmolyzing them with toluol and hypertonic salt solutions, or pressing them in a hydraulic press. These agents brought about a vigorous anaerobic CO₂ production accompanied by an accumulation of alcohol in the medium. The unitary character of endogenous respiration is exhibited only when the normal structure of the cell is kept intact; apparently it depends upon the maintenance of a chambered (or compartmental) architecture of the cell.     

On the catabolic pathways of sugars in green algae

Respiratory metabolism of the cultures of algaeChlorella pyrenoidosa (82) andScenedesmus obliquus (125) was investigated. One part of algae were cultivated on a mineral nutrient solution, another two parts on the solution with glucose and on the solution with glucose and yeast decoction. Individual steps of respiratory metabolism—endogenous as well as in the presence of exogenous sugars—were estimated according to the response to the following inhibitors: monoiodacetate, NaF, NaN₃, and 2,4-DNP. In the last two cases, fructose, glucose-6-phosphate and fructose-1,6-diphosphate were applied in parallel for comparison. Na-monoiodacetate was found to inhibit the respiration of both endogenous and exogenous (with glucose) substrates, NaF (concentrations up to 2.5.10^?2 m) stimulated the O₂ uptake. The effect of sodium azide and 2,4-DNP depended in both strains on previous cultivation. On the basis of the results obtained, the presence of particular respiration pathways in the dissimilation of glucose is discussed. The following catabolic processes are to be considered: a) direct oxidation (with both autotrophically cultivated strains and with theChlorella cultivated on glucosecontaining medium), b) the process similar to glycolysis, which, however, does not necessarily involve the enolase (it is not inhibited by NaF) c) pentosephosphate cycle (Chlorella), and d) glycolysis, in which both algae can operate when sugars previously phosphorylated are applied.     

STUDIES IN THE PHYSIOLOGY OF FUSARIA. THE RESPIRATORY AND FERMENTATIVE MECHANISMS

1.Fusarium tricothecoides was selected for a study of the respiratory and fermentative activities of Fusaria. "Resting cell" suspensions were investigated by the Barcroft manometric technique. 2. The results of the investigation indicate clearly that the mechanism of endogenous metabolism (respiration) is distinct from the exogenous mechanism (fermentation). Anaerobically no significant CO₂ production is apparent without added substrate. In the presence of glucose the anaerobic CO₂ evolution is practically equal to the added CO₂ evolved aerobically in the presence of added glucose. Low concentrations of iodoacetate or fluoride selectively poison the exogenous mechanism but do not affect the endogenous mechanism. Alcohol is not produced in the course of endogenous metabolism, but is produced in the presence of added glucose. 3. A study of the metabolism of the organism throughout its entire growth phase from 1 to 7 days has been made. 4. The ability of suspensions of Fusarium sp. H., obtained by growth on a variety of common substrates, to attack a large number of carbon sources with the production of exogenous CO₂ was determined. It is found that organisms grown on glucose will attack only glucose, mannose, and fructose, but none of the common intermediary metabolites except pyruvic acid. Organisms grown on galactose attack galactose, as well as the other hexoses, indicating an adaptive mechanism. 5. An identical mechanism for the dissimilation of glucose, mannose, and galactose is indicated since no additive effects with these substrates were observed. Growths on non-hexose carbon sources attack glucose slightly under the experimental conditions with the evolution of CO₂, but do not attack any other substrate. This would indicate a residual glucose-dissimilating mechanism in all growths investigated. 6. Striking similarities between the general metabolism of resting suspensions of Fusarium sp. H. and resting suspensions of yeast cells are apparent.     

Respiratory Response of Acer pseudoplatanus Cells to Pyruvate and 2,4-Dinitrophenol

The endogenous respiration rate of unstarved cultured cells of Acer pseudo-platanus L. is markedly stimulated by 2,4-dinitrophenol. Pyruvate is also stimulatory but to a lesser degree than dinitrophenol. Exogenously supplied sugars cause no short-term stimulation. Pyruvate does not enhance the elevated rate of O₂ uptake in the presence of dinitrophenol but does cause additional CO₂ evolution. The endogenous concentration of pyruvate is elevated in the presence of dinitrophenol. These observations suggest that the rate of O₂ uptake by the unstarved intact cells is limited by the rate of glycolysis and that rate of glycolysis is regulated by the intracellular concentration of adenine nucleotides or inorganic phosphate. Dinitrophenol stimulation of endogenous respiration is due in part to an indirect acceleration of glycolysis but also to a more direct facilitation of oxidation in the presence of excess mitochondrial substrate.     

The biochemical conversions of conjugated dienoic and trienoic fatty acids

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

Galactose regulation in Saccharomyces cerevisiae. The enzymes encoded by the GAL7, 10, 1 cluster are co-ordinately controlled and separately translated.

The enzymes for galactose metabolism in Saccharomyces cerevisiae are encoded by three tightly linked genes. Data presented in this paper show that, in contrast to enzymes encoded by other gene clusters in yeast, these three enzymes are translated as separate polypeptides. First, two of the enzymes encoded by the cluster, galactokinase and uridylyl transferase. purified to near homogeneity, are separate polypeptides. Second, no precursor polypeptide-containing sequences common to both these enzymes is detectable in extracts from galactose-induced yeast cells. Third, no partial or absolute polarity of expression of the enzymes is observed in strains containing nonsense mutations in any of the genes of the cluster.Expression of the three galactose metabolic enzymes is co-ordinate, both during induction and during steady-state synthesis. This is true both for wild-type yeast strains and for strains carrying the long-term galactose adaptation mutation, gal3. In GAL3⁺ strains mutations within the galactose gene cluster have no effect on this co-ordinate expression. However, in gal3^? strains, mutations in any of the genes of the cluster completely eliminate expression of the other two genes. These results suggest that the GAL3 gene product is responsible for inducer synthesis and that the actual inducer is an intermediate in galactose metabolism.     

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.     

Radiochemical investigation of the respiration of spores of Bacillus cereus

Summary The endogenous respiration of ¹⁴C-labelled spores of B. cereus was measured through the ¹⁴CO₂ produced, and the rate expressed as Q (l CO₂/hxmg). New upper limits for respiration in various conditions have been set.Dry spores had no measurable activity; Q<10^–4 at room temperature and <10^–3 at 35° C. For wet spores of different harvests, at 30°C, Q lay between 0.0013 to 0.067. Near 40° C, respiration showed a maximum. Thermal history has a great influence on Q. CO₂ production by heat-killed spores is attributed largely to infection.Water or 10^–3 m sodium phosphate buffer (pH=6.5) gave equal spore respiration, in strong NaCl it was less. Azide enhanced respiration dramatically. A temporary increase was also found with non-radioactive glucose. Exogenous respiration of spores in glucose exceeded endogenous respiration.Endogenous and exogenous respiration of vegetative forms were much larger than those of spores and were time-dependent. The ratio of minimum (endogenous, dry spores) and maximum (exogenous, wet vegetative cells) respiration was at least 3x10⁵.     

Composition and Activity of Marine Alkane-Degrading Bacterial Communities in the Transition from Suboxic to Anoxic Conditions

The impact of the oxygen supply rate (OSR) on the metabolic activity and on the composition of hexadecane-degrading bacterial communities in a quasi-anoxic milieu (nominal DOT=0%) was studied in continuous cultures containing intertidal sediment. The dilution rate was kept constant at 0.035 h⁻¹. The OSR was stepwise reduced from 3.5 mmol O₂L⁻¹ h⁻¹ to 0.06 mmol O₂L⁻¹ h⁻¹. Activity was determined by analyzing the respiration quotient (RQ) and the rates of hexadecane degradation (Q_Hex), of hexadecane mineralization, and of protein production (PPR). The community composition and size were investigated by fluorescence in situ hybridization (FISH), by dilution plating (colony forming units or CFU), and by most probable number (MPN). The culture showed an aerobic hexadecane metabolism down to an OSR of 0.35 mmol O₂L⁻¹ h⁻¹. Below this OSR, anaerobic metabolism was initiated. The relationship among the RQ, PPR, Q_Hex, and the OSR can be approximated by hyperbola (Michaelis-Menten kinetics). We suggest that the metabolic adaptation of the culture to low OSRs is due to regulation of protein expression and enzyme activity. Reducing the OSR resulted in minor but significant changes in the concentration of different physiological and phylogenetic groups. This means that, in addition to protein expression and activity regulation, the adaptation of the population to low OSRs is due to changes in the community composition.     

Effect and Aftereffect of Temperature on Respiration of Intact Plants

Effects and aftereffects of typical temperatures of cultivar habitat (background temperature), heat-hardening, and cold-hardening temperatures on dark respiration of leaf segments and intact plants were investigated on plant species differing in cold tolerance—cucumber (Cucumis sativus L.), tomato (Lycopersicon esculentum Mill.), cicer milkvetch (Astragalus cicer L.), and narrow-leaved lupine (Lupinus angustifolium L.). At cold-hardening temperatures, the respiratory metabolism underwent rearrangements serving to compensate for elevated energy losses during plant adaptation. This was manifested in the increase in the respiratory coefficient (RC) and the Q ₁₀ coefficient during hardening. The preconditioning of plants at hardening temperatures enhanced O₂ uptake and elevated the ratio of growth respiration to maintenance respiration in the post-treatment period. Conversely, temperature variations within the background range had no aftereffect on RC, Q ₁₀, and O₂ uptake.     

A KINETIC ANALYSIS OF THE ENDOGENOUS RESPIRATION OF BAKERS' YEAST

The process of endogenous respiration of two strains of bakers'' yeast, Saccharomyces cerevisiae, was examined kinetically. The rate of respiration with respect to time in a non-nutrient medium was found to exhibit two phases: (a) a period of constant rate of O₂ consumption and CO₂ production (R.Q. = 1) characteristic of cells with ample concentrations of stored material; (b) a first order decline in rate of respiration with respect to time, where the rate was proportional to the concentration of some substrate, S. (R.Q. = 1 throughout second phase.) The nature of this substrate was reexamined and the evidence summarized confirms the notion that it is a carbohydrate, probably glycogen. These phases of endogenous respiration were shown to depend upon the age of the culture and the amount of substrate available.     

Simultaneous measurement of aggregation, secretion, oxygen uptake, proton production, and intracellular metabolites in the same platelet suspension.

A cuvette is described for the simultaneous measurement of hydrogen ions, calcium ions, light transmission, and pO₂ in a single gel-filtered platelet suspension stirred at 37°C. A variable volume (2.5–10 ml) and special in- and outlets permit additions and sampling during incubation. Evidence is presented that changes in these parameters reflect lactate production in resting platelets (H⁺ measurement), secretion of dense granular content (Ca²⁺ measurement), shape change and aggregation (light transmission), and arachidonate oxidation and mitochondrial respiration (pO₂ measurement). The cuvette therefore enables direct correlation between function and energy metabolism in platelets.     

Investigation of the H(2) Oxidation System in Rhizobium japonicum 122 DES Nodule Bacteroids

The H₂-oxidizing complex in Rhizobium japonicum 122 DES bacteroids failed to catalyze, at a measurable rate, ²H¹H exchange from a mixture of ²H₂ and ¹H₂ in presence of ²H₂O and ¹H₂O, providing no evidence for reversibility of the hydrogenase reaction in vivo. In the H₂ oxidation reaction, there was no significant discrimination between ²H₂ and ¹H₂, indicating that the initial H₂-activation step in the over-all H₂ oxidation reaction is not rate-limiting. By use of improved methods, an apparent K_m for H₂ of 0.05 micromolar was determined. The H₂ oxidation reaction in bacteroids was strongly inhibited by cyanide (88% at 0.05 millimolar), theonyltrifluoroacetone, and other metal-complexing agents. Carbonyl cyanide m-chlorophenylhydrazone at 0.005 millimolar and 2,4-dinitrophenol at 0.5 millimolar inhibited H₂ oxidation and stimulated O₂ uptake. This and other evidence suggest the involvement of cytochromes and nonheme iron proteins in the pathway of electron transport from H₂ to O₂. Partial pressures of H₂ at 0.03 atmosphere and below had a pronounced inhibitory effect on endogenous respiration by bacteroid suspensions. The inhibition of CO₂ evolution by low partial pressures of H₂ suggests that H₂ utilization may result in conservation of oxidizable substrates and benefits the symbiosis under physiological conditions. Succinate, acetate, and formate at concentrations of 50 millimolar inhibited rates of H₂ uptake by 8, 29, and 25%, respectively. The inhibition by succinate was noncompetitive and that by acetate and formate was uncompetitive. A concentration of 11.6 millimolar CO₂ (initial concentration) in solution inhibited H₂ uptake by bacteroid suspensions by 18%. Further research is necessary to establish the significance of the inhibition of H₂ uptake by succinate, acetate, formate, and CO₂ in the metabolism of the H₂-uptake-positive strains of Rhizobium.     

Metabolic changes during substrate shifts in continuous cultures of the yeast Candida boidinii variant 60

Summary Substrate shift experiments in chemostat cultures with either methanol or glucose as carbon source were performed with the yeast Candida boidinii variant 60. At low dilution rates of 0.064 h^–1 the culture may be easily shifted from methanol to glucose medium and back again to methanol. From these experiments it can be seen that glucose does not give rise to any catabolite inhibition of alcohol oxidase. Alcohol oxidase and formaldehyde dehydrogenase seem to be regulated by a repression-derepression mechanism, as small basal activities of both these enzymes can still be measured during growth on glucose. On the other hand, formate dehydrogenase activity is completely absent in the presence of glucose. This kind of regulation seems to favor the smooth switch from growth on glucose to methanol metabolism.With methanol or glucose, growth yields (Y_S) of 0.3 and 0.35, respectively may be obtained, and oxygen consumption (Q_{O 2}) is much higher in methanol cultures than in glucose-grown cells. Accordingly, the RQ values during growth on methanol decrease to about 0.5. Based on the yield coefficient of 0.3, it is possible to calculate that 38% of the methanol consumed must be incorporated into biomass, whereas 62% of the methanol is oxidized to CO₂. The corresponding RQ of 0.56 could not be experimentally ascertained.The activities of three mitochondrial enzymes were found to be higher in methanol-grown cells than in cells from glucose cultures. The low activites of enzymes for the phosphogluconate route in methanol-grown cells indicates that a cyclic oxidation of formaldehyde via hexose phosphate to CO₂ cannot be of great importance for methanol metabolism.List of Symbols D 1/h Dilution rate - 1/h Specific growth rate - Q_{CO 2} mmol/g·h Specific CO₂ production rate - Q_{O 2} mmol/g·h Specific O₂ comsumption rate - Q_S g/g·h Specific substrate consumption rate - RQ ./. Respiratory quotient (Q_{CO 2}/Q_{O 2}) - S_O g/l Substrate concentration in the feeding medium - $#x0073;$#x0304 g/l Substrate concentration in the fermentor - $#x0078;$#x0304 g/l Biomass in the fermentor - Y_{O 2} g/mmol O₂ Biomass yield on oxygen - Y_S g/g Biomass yield on carbon source     

Capacity of Azospirillum thiophilum for lithotrophic growth coupled to oxidation of reduced sulfur compounds

Capacity for lithotrophic growth coupled to oxidation of reduced sulfur compounds was revealed in an Azospirillum strain, A. thiophilum BV-S ^T . Oxygen concentration in the medium was the major factor determining the type of energy metabolism (organotrophic or lithotrophic) in the presence of thiosulfate. Under aerobic conditions, metabolism of A. thiophilum BV-S^T was organoheterotrophic, with thiosulfate oxidation to tetrathionate resulting from the interaction with reactive oxygen species, mostly H₂O₂, which was formed in the electron transport chain in the course of oxidation of organic electron donors. Under microaerobic conditions (2 mg/L O₂ in liquid medium), A. thiophilum BV-S^T carried out lithoheterotrophic (mixotrophic) metabolism; enzymes of the dissimilatory type of sulfur metabolism were responsible for thiosulfate oxidation to tetrathionate and sulfate. Two enzyme systems were found in the cells: thiosulfate dehydrogenase, which catalyzes incomplete oxidation of thiosulfate to tetrathionate and the thiosulfate-oxidizing Sox enzyme complex, which is involved in complete oxidation of thiosulfate to sulfate. The genetic determinant of a Sox complex component in A. thiophilum BV-S^T was revealed. The soxB gene was found, and its expression under microaerobic conditions was observed to increase 32-fold compared to aerobic cultivation.     

Oxyleghemoglobin-mediated Hydrogen Oxidation by Rhizobium japonicum USDA 122 DES Bacteroids

Oxyleghemoglobin was used to supply low concentrations of O₂ to H₂-oxidizing bacteroids from Rhizobium japonicum USDA 122 DES. The H₂ oxidation system of these bacteroids was capable of effectively utilizing O₂ at the low concentrations of O₂ expected to be found in soybean nodules. Apparent K_m values of approximately 10 nanomolar O₂ have been calculated for the oxyhydrogen reaction. These values include the K_m values for both H₂ oxidation and endogenous substrate oxidation. Even in the presence of oxyleghemoglobin, H₂ additions stimulated C₂H₂ reduction, reduced the rate of endogenous respiration and maintained the ATP contents of bacteroids. In our reconstituted oxyleghemoglobin and bacteriod system, we estimate that the H₂ oxidation system is capable of recycling all of the H₂ evolved during the N₂ fixation process.     

Entamoeba histolytica. I. Aerobic metabolism

The respiration of intact trophozoites harvested from axenic cultures of Entamoeba histolytica was studied with the polarographic technique utilizing the Clark oxygen electrode. A typical Q_o2 value for the freshly harvested amebae was 1 μatom oxygen/mg protein/hr.It was conclusively demonstrated that this parasite, a putative anaerobe, not only consumes oxygen when provided, but has a high affinity for the gas.Added glucose, galactose, and ethanol increased the respiratory rates, whereas other carbohydrates were without effect on the endogenous respiration. Intermediates of the tricarboxylic acid cycle, amino and fatty acids did not stimulate the respiration of E. histolytica.Inhibitors of the mammalian respiratory chain (cyanide, antimycin) as well as agents that inhibit enzymes catalyzing the tricarboxylic acid cycle (malonate, fluoropyruvate, fluoroacetate, fluorocitrate) had little effect on the endogenous or glucose-supported respiration. Alkylating agents (iodoacetamide, iodoacetate), cinnamate, and N-ethylymaleimide strongly inhibited the oxygen consumption of E. histolytica. The chemotherapeutic agents, Paromomycin, Emetine and Metronidazole, at concentrations that inhibit growth in vitro, did not restrict the respiration.Storage of the trophozoites at 4 C led to progressive deterioraion of the parasites and loss of endogenous and glucose-supported respiration. The deterioration was paralled by loss of SH-materials from the amebae. Likewise, sonication or lysis with detergents abolished both the endogenous respiration and response to glucose.Exogenous NADH or NADPH evoked only marginal increases in oxygen consumption of the freshly harvested amebae, but were effective respiratory substrates with stored or sonicated organisms. Addition of vitamin K₃ greatly enhanced the endogenous and glucose-supported respiration of the intact amebae, as well as enhancing the response of stored or sonicated amebae to reduced pyridine nucleotides.     

New Type of Oxygenase Involved in the Metabolism of Propane and Isobutane

Nocardia paraffinicum (Rhodococcus rhodochrous), a hydrocarbon-degrading microorganism, was used in a study of propane and isobutane metabolism. The bacterium was able to utilize propane or isobutane as a sole source of carbon, and oxygen was found to be essential for its metabolism. Gas chromatographic analysis showed that n-propanol was the major compound recovered from the metabolism of propane by resting cells, although trace amounts of isopropanol and acetone were detected. When a mixture of propane and isobutane was used, drastic inhibition (72 to 88%) of hydrocarbon utilization by resting cells occurred. The ratio of hydrocarbon to oxygen consumed was found to be approximately 2:1 during the metabolism of propane or isobutane by resting cells when these substrates were provided individually to the organism. Gas chromatographic-mass spectrometric analysis of products formed from ¹⁸O₂ confirmed that the initial oxidative step in the metabolism of these substrates involved molecular oxygen. The proportion of the alcohol containing ¹⁸O was the same as that of ¹⁸O₂ in the gas mixture. Only a negligible amount of ¹⁸O was detected in the alcohol when H₂¹⁸O was incorporated into the system. The observed 2:1 ratio of hydrocarbon to oxygen consumption suggests that the oxygenase in N. paraffinicum, unlike the conventional mono- or dioxygenases, requires two hydrocarbon-binding sites for each of the oxygen-binding sites and is therefore an intermolecular dioxygenase. The newly described oxygenase, which catalyzes the reaction of two molecules of propane with one molecule of oxygen to yield two molecules of a C₃ alcohol, is proposed as the initial oxidation step of the hydrocarbon substrate.     

Robust metabolic responses to varied carbon sources in natural and laboratory strains of Saccharomyces cerevisiae

Understanding factors that regulate the metabolism and growth of an organism is of fundamental biologic interest. This study compared the influence of two different carbon substrates, dextrose and galactose, on the metabolic and growth rates of the yeast Saccharomyces cerevisiae. Yeast metabolic and growth rates varied widely depending on the metabolic substrate supplied. The metabolic and growth rates of a yeast strain maintained under long-term laboratory conditions was compared to strain isolated from natural condition when grown on different substrates. Previous studies had determined that there are numerous genetic differences between these two strains. However, the overall metabolic and growth rates of a wild isolate of yeast was very similar to that of a strain that had been maintained under laboratory conditions for many decades. This indicates that, at in least this case, metabolism and growth appear to be well buffered against genetic differences. Metabolic rate and cell number did not co-vary in a simple linear manner. When grown in either dextrose or galactose, both strains showed a growth pattern in which the number of cells continued to increase well after the metabolic rate began a sharp decline. Previous studied have reported that O₂ consumption in S. cerevisiae grown in reduced dextrose levels were elevated compared to higher levels. Low dextrose levels have been proposed to induce caloric restriction and increase life span in yeast. However, there was no evidence that reduced levels of dextrose increased metabolic rates, measured by either O₂ consumption or CO₂ production, in the strains used in this study.