The effects of glucose and oxygen on the cytochromes and metabolic activity of yeast batch cultures. I. Saccharomyces spp.

Saccharomyces cerevisiae and Saccharomyces carlsbergensis were grown in batch culture with and without oxygen control. The concentrations of A-, B- and C-type cytochromes of both yeasts were dependent on the oxygen concentration during growth as well as on the initial glucose concentration of the growth medium. S. cerevisiae cytochromes were maximal after growth in low glucose and low oxygen; S. carlsbergensis cytochromes were maximal after growth in low glucose and high oxygen. Except when glucose was in very low concentration, its catabolism by S. carlsbergensis was directed predominantly towards ethanolic fermentation regardless of the oxygen concentration. Growth rate, total cell mass and yield were maximal, and anabolism was closely balanced with catabolism, when glucose and oxygen of S. carlsbergensis cultures were both high. Under these conditions neither catabolism, respiratory or ethanolic, nor glucose uptake were maximal.     

Kinetic study of hybridoma cell growth in continuous culture. I. A model for non-producing cells

The kinetic behavior of a nonproducing hybridoma clone AFP-27-NP was investigated in continuous culture under glucose-limited conditions. A total of more than 21, 000 h of cultures were operated at dilution rates ranging from 0.01 to 0.06 h(-1). The viable cell concentrations, dead cell concentrations, and cell volumes all varied with the dilution rate. A steady-state model was developed based on the biomass concentration and the glucose concentration. The specific growth rate as a function of glucose concentration is described by a model similar to the Monod model with a threshold glucose concentration and a minimum specific growth rate incorporated; the model is meaningful only at glucose concentrations and specific growth rates above these levels. A death rate is included in the model which is described by an inverted Monod-type function of glucose concentration. The yield coefficient based on glucose is constant in the lower range of specific growth rates and changes to a new constant value in the upper region of specific growth rates. No maintenance term for glucose consumption was needed; in the plot of specific glucose consumption rate vs. specific growth rate, the line intercepted the specific growth rate axis at a value close to the minimum growth rate. The values for the model parameters were determined from regression analysis of the steady-state data. The model predictions and experimental results fit very well.     

Biochemical studies with a new cytotoxic immunosuppressive agent, 3-acetyl-5-(4-fluorobenzylidene)-2,5-dihydro-4-hydroxy-2-oxothiophen (I.C.I. 47776)

1. A new cytotoxic agent, 3-acetyl-5-(4-fluorobenzylidene)-2,5-dihydro-4-hydroxy-2-oxothiophen (I.C.I. 47776), strongly inhibits protein and nucleic acid synthesis and, to a smaller extent, respiration in lymph-node cells and Landschütz ascites-tumour cells in vitro. 2. The activity of I.C.I. 47776 in vitro declines as the pH of the medium is increased and is inversely proportional to the concentration of serum in the medium. 3. The compound has no effect on the incorporation of leucine by a cell-free preparation from Landschütz ascites cells containing ATP and phosphoenolpyruvate. 4. I.C.I. 47776 stimulates glycolysis in suspensions of Landschütz ascites cells in the presence of excess of glucose but has no effect on glycolysis in suspensions of rat lymph-node cells. 5. I.C.I. 47776 markedly depresses ATP concentration in ascites cells in the absence of glucose but has no effect on the ATP concentration in the presence of glucose. The inhibition of protein synthesis by I.C.I. 47776 in ascites cells is, however, only partially reversed by the addition of glucose. 6. The ATP concentration of rat lymph-node cells incubated with I.C.I. 47776 in the absence of glucose is also markedly depressed but the addition of glucose increases the ATP concentration only slightly. Further, glucose has no effect on the inhibition of protein synthesis in lymph-node cells by I.C.I. 47776. 7. It is suggested that I.C.I. 47776 inhibits protein and nucleic acid synthesis in cell suspensions indirectly by acting as a mitochondrial poison. 8. The relevance of studies on the activity of I.C.I. 47776 in vitro to its cytotoxic and immunosuppressive action in vivo is discussed.     

Ionic control of renal gluconeogenesis IV. Effect of extracellular phosphate concentration

Isolated rat renal tubules from glucose from pyruvate, malate, glycerol and α-ketoglutarate. The rate of glucose formation from all but glycerol is enhanced by an increase in Ca²⁺ concentration. Because changes in inorganic phosphate concentrations influence the uptake and retention of calcium by isolated cells, the effect of changes in phosphate concentration upon renal gluconeogenesis was examined. It was found that changing phosphate concentration altered the metabolism of isolated rat renal tubules in three ways which dependend upon the Ca²⁺ concentration. In the absence of Ca²⁺, increasing phosphate concentration from 0.07 to 1.2 mM led to a stimulation of the decarboxylation of [U-¹⁴C]malate, [1-14C]pyruvate, [2-¹⁴C]-pyruvate, α-keto[5-¹⁴C]glutarate and [1,3-¹⁴C₂]glycerol, and to an increase in ATP concentration but had no effect upon the rate of glucose formation from malate, pyruvate, α-ketoglutarate but a slight stimulation of glucose production from glycerol. A further increase in phosphate above 1.2 mM had no effect on any of these parameters. In the presence of either low (0.2 mM) or high (2.0 mM) Ca²⁺, changing phosphate concentration had no effect upon the decarboxylation of any of these substrates except glycerol whose decarboxylation was stimulated by increasing medium phosphate concentration. In the presence of calcium, increasing phosphate concentration led to an inhibition of glucose formation from malate, pyruvate and α-ketoglutarate but not from glycerol. Also in the presence of calcium both parathyroid hormone and cyclic AMP stimulated glucose formation, and under these conditions increasing phosphate concentration led to an inhibition of glucose formation. In tubules treated with parathyroid hormone an increase in phosphate concentration from 0.07 to 6.0 mM led to a significant increase in cyclic AMP concentration even though the rate of glucose formation decreased.Analysis of metabolite concentrations and rates of substrates decarboxylations, under a variety of conditions, revealed that P_i altered renal gluconeogenesis at a site different from those controlled by changes in Ca²⁺ concentration. The P_i-control site was tentatively identified as the glyceraldehyde phosphate dehydrogenase-glycerate kinase reaction sequence. However, the effect of changing P_i concentration upon parathyroid hormone-induced alterations in cyclic AMP concentration could not be explained by this action of P_i, and was probably due to an effect of P_i upon cellular calcium distribution. Thus, changes in P_i concentration appear to have two cellular effects, only one of which is related to a change in cellular calcium metabolism.     

Combination of microdialysis and glucosensor permits continuous (on line) SC glucose monitoring in a patient operated device. II. Evaluation in animals.

The microdialysis technique was used for following the glucose content of the extracellular subcutaneous (SC) fluid under varying blood glucose levels in rats. The glucose content in the microdialysis perfusion fluid was continuously analyzed by means of the measuring flow chamber of an ex vivo glucose monitor. In six ChBB rats blood glucose levels were varied between 40 mg/dl and 575 mg/dl by intravenous (IV) infusion of glucose and by SC injections of insulin, respectively. After a running-in period of about half an hour, the glucose content in the perfusion fluid was closely related to the blood glucose concentration (r > 0.92) up to a time period of 6 hrs. The "relative recovery" rate of glucose by the microdialysis probe in the SC tissue varied within the 6 experimental sessions. The relative recovery rate could be shown to be not dependent on the absolute blood glucose levels in the individual rat within the glucose concentration range tested.     

Kinetic study of hybridoma cell growth in continuous culture: II. Behavior of producers and comparison to nonproducers

A hybridoma cell line, AFP-27-P, was cultivated in continuous culture under glucose-limited conditions. The viable cell concentration, dead-cell concentration, and cell volume all varied with the dilution rate. A model previously developed for a nonproducing clone of the same cell line, AFP-27-NP, was extended to describe the behavior of the cells. The relationship between the specific growth rate and glucose concentration is described by a function similar to the Monod model. A threshold glucose concentration and a minimum specific growth rate are incorporated; the model is meaningful only at glucose concentration and a minimum specific growth rate are incorporated; the model is meaningful only at glucose concentrations and specific growth rates above these levels. The relationship between the death rate and the glucose concentration is described by an inverted Monod-type function. Furthermore, the yield coefficient based on glucose is constant in the lower range of specific growth rates and changes to a new constant value in the upper range of specific growth rates. No maintenance term for glucose consumption is used; in the plot of specific glucose consumption rate vs. specific growth rate, the line intercepts the specific growth rate at a value close to the minimum growth rate. The productivity of antibody as a function of the specific growth rate is described by a mixed type model with a noon-growth-associated term and a negative-growth-associated term. The values for the model parameters were determined from regression analysis of the steady state data.     

The stimulus-secretion coupling of glucose-induced insulin release. Metabolic effects of menadione in isolated islets.

Pancreatic islets contain an enzyme system which catalyzes the donation of hydrogen from NAD(P)H to menadione (2-methyl-1,4-naphthoquinone). In high concentrations (20 to 50 micrometer), menadione, in addition to lowering the concentration of reduced pyridine nucleotides in the islets, also impairs glycolysis and glucose oxidation, decreases ATP concentration, and inhibits proinsulin biosynthesis. However, at a 10 micrometer concentration, menadione fails to affect the concentration of adenine nucleotides, the utilization of glucose, the production of lactate and pyruvate, the oxidation of [6-14C]glucose and the synthesis of proinsulin; whereas the metabolism of glucose through the pentose shunt is markedly increased. The sole inhibitory effect of menadione 10 micrometer upon metabolic parameters is to reduce the concentration of both NADH and NADPH, such an effect being noticed in islets exposed to glucose 11.1 mM but not in those incubated at a higher glucose level (27.8 mM). Since, in the presence of glucose 11.1 mM, menadione 10 micrometer also severely decreases glucose-stimulated45 calcium net uptake and subsequent insulin release, it is concluded that the availability of reduced pyridine nucleotides may play an essential role in the secretory sequence by coupling metabolic to cationic events. Thus, when insulinotropic nutrients are oxidized in the B-cell, the increased availability of reduced pyridine nucleotides could modify the affinity for cations of native ionophoretic systems, eventually leading to the accumulation of calcium up to a level sufficient to trigger insulin release.     

The effects of glucose and oxygen on the cytochromes and metabolic activity of yeast batch cultures. II. Candida utilis

Candida utilis was grown in batch culture with and without oxygen control. The concentrations of A-, B-, and C-type cytochromes were found to vary with the initial glucose concentration, with the dissolved oxygen concentration, and with time. A-type was the most sensitive. After glucose was essentially exhausted, the yeast catabolized ethanol, if it had been growing in a relatively low initial glucose concentration, or non-glucose carbohydrate, including some of that previously accumulated within the cell, if it had been growing in a high initial glucose concentration. This difference in metabolic pattern could explain why cytochrome derepression was initiated soon after glucose uptake ceased only if initial glucose had been relatively low. The effects of glucose and dissolved oxygen concentrations on yeast cytochromes and respiratory activity are discussed.     

Kinetic analysis of the cerebral creatine kinase reaction under hypoxic and hypoglycaemic conditions in vitro. A 31P-n.m.r. study.

1. The tissue concentration of phosphocreatine (PCr) and the pseudo-first-order rate constant of creatine kinase (kf) were monitored in superfused guinea-pig brain slices in vitro by using 31P-n.m.r. techniques. 2. Superfusion of slices in low oxygen partial pressure (pO2 approx. 16 kPa) decreased tissue PCr concentrations by 48% but ATP concentrations were unchanged. Regression analysis revealed a significant negative correlation between the PCr concentration in hypoxic tissue and the increase in the rate constant, kf. Nevertheless the forward flux through the enzyme (Jf = kf.[PCr]) declined under these conditions. 3. Lowering the glucose concentration to 0.2 or 0.1 mM decreased PCr concentrations by 29% and 48% respectively; here ATP concentrations as well as PCr concentrations also decreased. Only in the presence of the lower glucose concentration (0.1 mM) was kf increased. However, unlike the situation in hypoxic tissue, Jf was maintained at control rates. 4. In spectra obtained in the presence of low oxygen or low glucose concentrations, a resonance attributable to tissue inorganic phosphate became dectectable. This observation is discussed in terms of known changes in tissue phosphate concentrations and possible alterations in cytoplasmic pH.     

Substrate regulation of the glucose transport system in rat skeletal muscle. Characterization and kinetic analysis in isolated soleus muscle and skeletal muscle cells in culture

A self-regulatory mechanism of the glucose transport in rat skeletal muscle cells is described. In isolated rat soleus muscles and rat skeletal myocytes and myotubes in culture, pre-exposure to varying glucose concentrations modulated the rate of 2-deoxyglucose uptake. Maximal uptake was observed at glucose concentrations below 3 mM. Between 2.5 and 4.0 mM glucose it was reduced by 25-35%; further elevation of the glucose concentration resulted in a gradual decrease of the transport rate by approximately 2% for each millimolar glucose. The effect of glucose was time-dependent and fully reversible. Insulin rapidly increased the 2-deoxyglucose uptake in the soleus muscle; however, the insulin effect depended on the glucose concentration of the preincubation. Insulin was totally ineffective in muscles pre-exposed to 1.0-3.0 mM glucose, whereas its stimulatory action increased with increasing glucose concentrations above 4 mM. The effect of low glucose and insulin were not additive, and the maximal 2-deoxyglucose uptake rates induced by both conditions were of identical magnitude. It is postulated that glucose may "up- and down-regulate" its transport by affecting the number of active glucose transporters in the plasma membrane, and that insulin exerts its stimulatory effect only when the extracellular glucose reaches a threshold concentration.     

In Vitro Sugar Transport in Zea mays L. Kernels : II. Characteristics of Sugar Absorption and Metabolism by Isolated Developing Embryos

In vitro sugar transport into developing isolated maize embryos was studied. Embryo fresh and dry weight increased concomitantly with endogenous sucrose concentration and glucose uptake throughout development. However, endogenous glucose and fructose concentration and sucrose uptake remained constant. The uptake kinetics of radiolabeled sucrose, glucose, and fructose showed a biphasic dependence on exogenous substrate concentration. Hexose uptake was four to six times greater than sucrose uptake throughout development. Carbonylcyanide-m-chlorophenylhydrazone and dinitrophenol inhibited sucrose and glucose uptake significantly, but 3-O-methyl glucose uptake was less affected. The uptake of 1 millimolar sucrose was strongly pH dependent while glucose was not. Glucose and fructose were readily converted to sucrose and insoluble products soon after absorption into the embryo. Thus, sucrose accumulated, while glucose pools remained low. Based on the findings of this and other studies a model for sugar transport in the developing maize kernel is presented.     

Arginine catabolism in Lactobacillus sake isolated from meat.

Lactobacillus sake isolated from meat can hydrolyze arginine via the arginine deiminase pathway. Two enzymes, arginine deiminase and ornithine transcarbamylase, have been revealed by detection of their reaction products, citrulline and ornithine, respectively. The production of citrulline depends on the concentration of glucose in a synthetic medium; it does not occur when the concentration of glucose is 27.5 mM or higher.     

High levels of polysaccharides in Aplysia hepatopancreas and penis: differential effects of nutrition and development.

1. Carbohydrate levels in tissues of Aplysia californica were measured. In animals maintained in the laboratory without feeding for 1-2 weeks, the penis contained the highest concentration of glycogen. 2. Blood glucose ranged between 2.5 and 4.8 mg/dl and averaged 3.2 +/- 0.2 mg/dl. 3. Fed animals had significantly greater tissue glycogen levels than starved animals. The penis exhibited the smallest per cent increase in glycogen concentration in response to feeding. 4. In contrast, the hepatopancreas exhibited a large increase, attaining glycogen concentrations near that of the penis. 5. Most of the increase in total tissue glycogen in fed animals occurred in the hepatopancreas. 6. Starved and fed animals did not differ significantly in blood glucose concentration, thus indicating that blood glucose is regulated and excess glucose is stored. 7. The hepatopancreas is the major mobile glucose store. 8. The high concentrations of glycogen found in the penis were not affected by mating activity. 9. However, penis glycogen concentration increased greatly with reproductive maturation of Aplysia; in contrast, hepatopancreas glycogen concentration was relatively unaffected by development. 10. A structural role by carbohydrates in the penis is suggested.     

Glucose diffusion in pancreatic islets of Langerhans.

We investigate the time required for glucose to diffuse through an isolated pancreatic islet of Langerhans and reach an equilibrium. This question is relevant in the context of in vitro electrophysiological studies of the response of an islet to step changes in the bath glucose concentration. Islet cells are electrically coupled by gap junctions, so nonuniformities in islet glucose concentration may be reflected in the activity of cells on the islet periphery, where electrical recordings are made. Using a mathematical model of hindered glucose diffusion, we investigate the effects of the islet porosity and the permeability of a surrounding layer of acinar cells. A major factor in the determination of the equilibrium time is the transport of glucose into islet beta-cells, which removes glucose from the interstitial spaces where diffusion occurs. This transport is incorporated by using a model of the GLUT-2 glucose transporter. We find that several minutes are required for the islet to equilibrate to a 10 mM change in bath glucose, a typical protocol in islet experiments. It is therefore likely that in electrophysiological islet experiments the glucose distribution is nonuniform for several minutes after a step change in bath glucose. The delay in glucose penetration to the inner portions of the islet may be a major contributing factor to the 1-2-min delay in islet electrical activity typically observed after bath application of a stimulatory concentration of glucose.     

Insulin and the way the brain handles glucose.

—In living rats the concentration of insulin in the circulating blood was raised and independently of this the glucose concentration in the blood plasma was varied from hyperglycaemic to hypoglycaemic levels. Hyperglycaemia increased the influx of glucose into the brain and it also, for a limited period, increased the glucose gain by the brain. Insulin, on the other hand, did not affect influx but significantly increased the gain of glucose by the brain. It is suggested that although both hyperglycaemia and insulin can increase glucose gain by the brain they do so in entirely different ways.     

Glucose Utilization by Euglena gracilis var. bacillaris: Short-Term Metabolic Studies*

SYNOPSIS. In tryptone media, optimal growth of nonphotosynthetic Euglena gracilis var. bacillaris on glucose occurred with 1% (w/v) glucose at pH 3.5, and required a previous adaptive period in glucose medium. In short term metabolic experiments, glucose uptake was greatly stimulated by small concentrations of tryptone or succinate; effects of shaking suggested that CO₂ has a similar stimulatory effect. Glucose utilization was highly dependent on glucose concentration, with an apparent threshold at about 2 mM and increasing steeply with glucose concentration above this value. In tracer experiments, about 90% of the glucose carbon consumed was assimilated, and about 10% released as CO₂. Glucose did not stimulate respiration even during rapid glucose utilization. Tracer studies indicated oxidation of endogenous substrates was depressed by an amount which just compensated for the respiration due to glucose. The conditions which allowed rapid glucose utilization by “resting”E. gracilis var. bacillaris were the same as those known previously to be required for growth on glucose. It was therefore concluded that these factors act directly on the main pathways of glucose metabolism.     

Hyperglycemia-induced hyponatremia: metabolic considerations in calculation of serum sodium depression.

Hyperglycemia is associated with a decrease in serum sodium concentration. Previous methods of estimating the degree of decrease have not considered the fact that glucose will enter certain cells despite relative insulin deficiency; thus, glucose will not contribute directly to the osmotic gradient responsible for water shifts into or out of these tissues. The expected decrease in serum sodium concentration is 1.35 meg/l for every 100mg/dl increase in blood glucose concentration - the metabolic correction factor. Although the numerical difference between this factor and that calculated by others is small, the metabolic implications could be critical. In the hyperglycemic state the water content of tissues not requiring insulin for glucose transport could increase, and where tissue swelling is physically restricted (for example, in the brain) this expansion could seriously affect organ function.     

Increased erythritol production in fed-batch cultures of Torula sp. by controlling glucose concentration

The effect of glucose concentration on erythritol production by Torula sp. was investigated. The maximum volumetric productivity of erythritol was obtained at an initial glucose concentration of 300 g l⁻¹ in batch culture. The volumetric productivity was maximal at a controlled glucose concentration of 225 g l⁻¹, reducing the lag time of the erythritol production. A fed-batch culture was established with an initial glucose concentration of 300 g l⁻¹ and with a controlled glucose concentration of 225 g l⁻¹ in medium containing phytic acid as a phosphate source. In this fed-batch culture, a final erythritol production of 192 g l⁻¹ was obtained from 400 g l⁻¹ glucose in 88 h. This corresponded to a volumetric productivity of 2.26 g l⁻¹ h⁻¹ and a 48% yield. Journal of Industrial Microbiology & Biotechnology (2001) 26, 248–252. Received 26 September 2000/ Accepted in revised form 16 January 2001     

Carbohydrate metabolism in pregnancy. Part I. Diurnal plasma glucose profile in normal and diabetic women.

Diurnal plasma glucose profiles and oral glucose tolerance during pregnancy were studied in normal women, chemical diabetics, and insulin-requiring diabetics. In normal women the mean diurnal plasma glucose rose by only 0.22 mmol/1 (4 mg/100 m1) during pregnancy. Mild chemical diabetes resulted in an increase in both the mean diurnal glucose concentration and the fluctuation of plasma glucose levels during the day. Fluctuation in glucose concentration in insulin-dependent diabetics was about three times that found in non-diabetic women of similar gestation, with relative hyperglycaemia during the day and hypoglycaemia at night. In non-diabetic women and those with chemical diabetes the mean dirunal glucose correlated closely with the total area under the three-hour oral glucose tolerance curve and significantly, but less closely, with the two-hour glucose tolerance test value.     

Brain glucose-sensing mechanisms: ubiquitous silencing by aglycemia vs. hypothalamic neuroendocrine responses

Interest in brain glucose-sensing mechanisms is motivated by two distinct neuronal responses to changes in glucose concentrations. One mechanism is global and ubiquitous in response to profound hypoglycemia, whereas the other mechanism is largely confined to specific hypothalamic neurons that respond to changes in glucose concentrations in the physiological range. Although both mechanisms use intracellular metabolism as an indicator of extracellular glucose concentration, the two mechanisms differ in key respects. Global hyperpolarization (inhibition) in response to 0 mM glucose can be reversed by pyruvate, implying that the reduction in ATP levels acting through ATP-dependent potassium (K-ATP) channels is the key metabolic signal for the global silencing in response to 0 mM glucose. In contrast, neuroendocrine hypothalamic responses in glucoresponsive and glucose-sensitive neurons (either excitation or inhibition, respectively) to physiological changes in glucose concentration appear to depend on glucokinase; neuroendocrine responses also depend on K-ATP channels, although the role of ATP itself is less clear. Lactate can substitute for glucose to produce these neuroendocrine effects, but pyruvate cannot, implying that NADH (possibly leading to anaplerotic production of malonyl-CoA) is a key metabolic signal for effects of glucose on glucoresponsive and glucose-sensitive hypothalamic neurons.