Silicon metabolism in diatoms. III. Respiration and silicon uptake in Navicula pelliculosa

1. Evidence is presented that silicon uptake in the diatom Navicula pelliculosa is linked with aerobic respiration. 2. Cyanide, fluoride, iodoacetate, arsenite, azide, and fluoroacetate, at concentrations inhibitory to respiration, were also inhibitory to silicon uptake. 3. 2,4-Dinitrophenol (1 to 2 x 10(-5)M) stimulated respiration by 100 per cent, but almost completely inhibited silicon uptake. 4. The respiratory quotient of non-Si-deficient cells decreased from 0.93 to 0.75 after 4 days of starvation in darkness. Glucose (1 per cent) raised the respiratory quotient of such starved cells to 1.05. 5. Silicate (20 mg. Si/liter) stimulated respiration of unstarved Si-deficient cells by about 40 per cent. The effect of silicate on the respiration of Si-deficient cells which had been starved in darkness for 4 days was less marked. 6. The respiratory quotient of Si-deficient cells decreased from 0.8-0.9 to 0.3 after 4 days of starvation in darkness. The addition of silicate to starved cells raised the quotient to 0.5. This represented a 25 per cent stimulation of oxygen uptake concomitant with a 90 per cent stimulation of carbon dioxide evolution. 7. Glucose (1 per cent) caused an increase of respiratory quotient in starved cells from 0.3 to 0.7-0.8. The addition of silicate had no effect on the R.Q. during the oxidation of exogenous glucose. 8. Substrates (glucose, fructose, galactose, lactate, succinate, citrate, glycerol), which caused a stimulation of respiration in starved cells, also stimulated silicon uptake by those cells. However, the stimulation of silicon uptake (50 to 100 per cent) was not proportional to the respiratory stimulation by these substrates (30 to 300 per cent).     

Lysosomal acid proteinase of rabbit liver

1. The interference mechanism of carbonyl cyanide m-chlorophenylhydrazone with the respiratory process and with phosphorylation coupled to respiration has been investigated in resting cells of Escherichia coli. 2. Preincubation of the cells with carbonyl cyanide m-chlorophenylhydrazone in the absence of substrate caused strong inhibition of succinate oxidation. The inactivation of the respiratory system proved to be time-dependent and temperature-dependent and could be arrested by adding the substrate. Inhibition of incorporation of ³²P into acid-soluble organic phosphate esters exceeded the inhibition of oxygen uptake. 3. In contrast with succinate, the rate of oxidation of glucose was increased by carbonyl cyanide m-chlorophenylhydrazone. The sensitivity of other substrates to the inhibitor was less than that of succinate. 4. Various observations are described in support of the view that respiratory inhibition induced by carbonyl cyanide m-chlorophenylhydrazone is a result of its interference with ATP synthesis. The capacity of a given substrate to increase intracellular ATP concentration appeared to be directly related to its resistance to inhibition. In cell-free extracts carbonyl cyanide m-chlorophenylhydrazone still suppressed ³²P incorporation but had no effect on respiration. 5. Carbonyl cyanide m-chlorophenylhydrazone-induced stimulation of glucose oxidation and the acceleration of succinate oxidation by ADP or AMP in cells rendered permeable to nucleotides are tentatively interpreted as an indication that a certain part of respiration in E. coli is under phosphate-acceptor-mediated control.     

The respiratory chain of Paramecium tetraurelia in wild type and the mutant Cl1. II. Cyanide-insensitive respiration. Function and regulation.

1. The cyanide-insensitive respiration in Paramecium tetraurelia was found to be located in mitochondria. 2. Sensitivity of the mitochondrial respiration to cyanide depended on growth conditions. Under standard conditions of growth, 15--20% of respiration was insensitive to 1 mM cyanide. Full resistance to 1 mM cyanide was observed by growing cells in the presence of erythromycin (100--400 microgram/ml) 0.2 mM cyanide. The mitochondrial respiration of the mutant Cl1 harvested during the exponential phase of growth was largely insensitive to cyanide (more than 80%). 3. Pyruvate was oxidized at the same rate by wild type mitochondria and mitochondria of the mutant Cl1. In contrast, succinate oxidation was 2--3 times faster in mitochondria of the mutant Cl1 than in wild type mitochondria. 4. The cyanide-insensitive respiration was inhibited by 1 mM salicylhydroxamic acid to nearly 100%. Other efficient respiratory inhibitors included amytal and heptylhydroxyquinoline. Antimycin was not inhibitory even at concentrations as high as 5 microgram/mg protein, a finding consistent with the lack of antimycin binding sites.     

Transport protein synthesis in non-growing yeast cells

Addition of a metabolizable substrate (glucose, ethanol and, to a degree, trehalose) to non-growing baker's yeast cells causes a boost of protein synthesis, reaching maximum rate 20 min after addition of glucose and 40–50 min after ethanol or trehalose addition. The synthesis involves that of transport proteins for various solutes which appear in the following sequence: H⁺, l-proline, sulfate, l-leucine, phosphate, α-methyl-d-glucoside, 2-aminoisobutyrate. With the exception of the phosphate transport system, the K_t of the synthesized systems is the same as before stimulation. Glucose is usually the best stimulant, but ethanol matches it in the case of sulfate and exceeds it in the case of proline. This may be connected with ethanol's stimulating the synthesis of transport proteins both in mitochondria and in the cytosol while glucose acts on cytosolic synthesis alone. The stimulation is often repressed by ammonium ions (leucine, proline, sulfate, H⁺), by antimycin (proline, trehalose, sulfate, H⁺), by iodoacetamide (all systems tested), and by anaerobic preincubation (leucine, proline, trehalose, sulfate). It is practically absent in a respiration-deficient petite mutant, only little depressed in the op₁ mutant lacking ADP/ATP exchange in mitochondria, but totally suppressed (with the exception of transport of phosphate) in a low-phosphorus strain. The addition of glucose causes a drop in intracellular inorganic monophosphate by 30%, diphosphate by 45%, ATP by 70%, in total amino acids by nearly 50%, in transmembrane potential (absolute value) by about 50%, an increase of high-molecular-weight polyphosphate by 65%, of total cAMP by more than 100%, in the endogenous respiration rate by more than 100%, and a change of intracellular pH from 6.80 to 7.05. Ethanol caused practically no change in ATP, total amino acids, endogenous respiration, intracellular pH or transmembrane potential; a slight decrease in inorganic monophosphate and diphosphate and a sizeable increase in high-molecular-weight polyphosphate. The synthesis of the various transport proteins thus appears to draw its energy from different sources and with different susceptibility to inhibitors. It is much more stimulated in facultatively aerobic species (Saccharomyces cerevisiae, Endomyces magnusii) than in strictly aerobic ones (Rhodotorula glutinis, Candida parapsilosis) where an inhibition of transport activity is often observed after preincubation with metabolizable substrates.     

On the ability of galactose to influence hexose and amino acid uptake by isolated rat brain capillaries

The uptake of glucose, 2-deoxyglucose, proline, methionine, and alpha-methylamino isobutyric acid was studied in brain capillaries preincubated with 50 mM galactose either in vitro or isolated from galactose-fed rats. The uptake was not decreased in both cases. The linear rate of glucose oxidation by capillaries was also not altered by preincubation with galactose.     

Effects of Cyanide and Ethylene on the Respiration of Cyanide-sensitive and Cyanide-resistant Plant Tissues

The effects of cyanide and ethylene, respectively, were studied on the respiration of a fully cyanide-sensitive tissue-the fresh pea, a slightly cyanide-sensitive tissue-the germinating pea seedling, and a cyanide-insensitive tissue-the cherimoya fruit. Cyanide inhibition of both fresh pea and pea seedling respiration was attended by a conventional Pasteur effect where fermentation was enhanced with an accumulation of lactate and ethanol and a change in the level of glycolytic intermediates indicative of the activation of phosphofructokinase and pyruvate kinase accompanied by a sharp decline in ATP level. In these tissues, ethylene had little or no effect on the respiration rate, or on the level of glycolytic intermediates or ATP. By contrast, ethylene as well as cyanide enhanced both respiration and aerobic glycolysis in cherimoya fruits with no buildup of lactate and ethanol and with an increase in the level of ATP. The data support the proposition that for ethylene to stimulate respiration the capacity for cyanide-resistant respiration must be present.     

The influence of organic substrates and inhibitors on the induction of a respiratory oscillation in the cyanobacterium Anacystis nidulans

The rate of respiratory oxygen uptake of the cyanobacterium (blue-green alga) Anacystis nidulans oscillated under certain physiological conditions after light pulses or after addition of sodium acetate. The oscillation started either by the photosynthetic inhibition of respiration or by the stimulation of oxygen uptake caused by sodium acetate. The photosynthetic inhibition of respiration decreased the rate of oxygen uptake to about 20% of the rate in the dark.Starved cells (48 h dark) had lost the inducibility of the oscillation. In starved as well as in non-starved cells oscillations were inducible in the presence of fructose or glucose. Well developed oscillations were not promoted further. All other substances tested as substrates did not restore the inducibility of the oscillation in starved cells. The induction of the oscillation was inhibited by iodoacetamide (0.1 mM), p-hydroxymercuribenzoate (0.1 mM) and sodium fluoride (100 mM). It is suggested that a flow from glyceraldehyde-3-phosphate to the incomplete tricarboxylic acid cycle is a prerequisite for the oscillation.     

Control of respiration and oxidative phosphorylation in isolated rat liver cells

NAD(P)H fluorescence, mitochondrial membrane potential and respiration rate were measured and manipulated in isolated liver cells from fed and starved rats in order to characterize control of mitochondrial respiration and phosphorylation. Increased mitochondrial NADH supply stimulated respiration and this accounted for most of the stimulation of respiration by vasopressin and extracellular ATP. From the response of respiration to NADH it was estimated that the control coefficient over respiration of the processes that supply mitochondrial NADH was about 0.15-0.3 in cells from fed rats. Inhibition of the ATP synthase with oligomycin increased the mitochondrial membrane potential and decreased respiration in cells from fed rats, while the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone had the opposite effect. There was a unique relationship between respiration and membrane potential irrespective of the ATP content of the cells indicating that phosphorylation potential controls respiration solely via phosphorylation (rather than by controlling NADH supply). From the response of respiration to the mitochondrial membrane potential (delta psi M) it was estimated that the control coefficients over respiration rate in cells from fed rats were: 0.29 by the processes that generate delta psi M, 0.49 by the process of ATP synthesis, transport and consumption, and 0.22 by the processes that cycle protons across the inner mitochondrial membrane other than via ATP synthesis (e.g. the passive proton leak). Control coefficients over the rate of mitochondrial ATP synthesis were 0.23, 0.84 and -0.07, respectively, by the same processes. The control distribution in cells from starved rats was similar.     

Phosphoenolpyruvate and 2-phosphoglycerate: endogenous energy source(s) for sugar accumulation by starved cells of Streptococcus lactis.

In the absence of an exogenous energy source, galactose-grown cells of Streptococcus lactis ML3 rapidly accumulated thiomethyl-beta-D-galactopyranoside (TMG) and 2-deoxyglucose to intracellular concentrations of 40 to 50 mM. Starved cells maintained the capacity for TMG uptake for many hours, and accumulation of the beta-galactoside was insensitive to proton-conducting ionophores (tetrachlorosalicylanilide and carbonylcyanide-m-chlorophenyl hydrazone) and sulfydryl group reagents including iodoacetate and N-ethylmaleimide. Fluorimetric analysis of glycolytic intermediates in extracts prepared from starved cells revealed (a) high intracellular levels of phosphoenolpyruvate (13 mM; PEP) and 2-phosphoglycerate (approximately 39 mM; 2-PG), but an absence of other metabolites including glucose 6-phosphate, fructose 6-phosphate, fructose 1,6-diphosphate, and triosephosphates. The following criteria showed PEP (and 2-PG) to be the endogenous energy source for TMG accumulation by the phosphotransferase system: the intracellular concentrations of PEP and 2-PG decreased with concomitant uptake of TMG, and a close correlation was observed between maximum accumulation of the beta-galactoside and the total available concentration of the two intermediates; TMG accumulated as an anionic derivative, which after extraction and incubation with alkaline phosphatase (EC 3.1.3.1) formed the original analogue; fluoride inhibition of 2-phospho-D-glycerate hydrolyase (EC 4.2.1.11) prevented the conversion of 2-PG to PEP, and uptake of TMG by the starved cells was reduced by 80%; and the stoichiometric ratio [TMG] accumulated/[PEP] consumed was almost unity (0.93). In cells metabolizing glucose, all intermediates listed in (a) and (b) were found. Upon exhaustion of glucose from the medium, the metabolites in (b) were not longer detectable, while the intracellular concentrations of PEP and 2-PG increased to the levels previously observed in starved cells. The glycolytic intermediates in (b) are all in vitro heterotropic effectors of pyruvate kinase (adenosine 5'-triphosphate:pyruvate 2-O-phosphotransferase, EC 2.7.1.40) from S. lactis ML3. It is suggested that the capacity of starved cells to maintain high intracellular concentrations of PEP and 2-PG is a consequence of decreased in vivo activity of this key regulatory enzyme of glycolysis.     

On the mechanism of the glucose-induced ATP catabolism in ascites tumour cells and its reversal by pyruvate.

Addition of glucose to Ehrlich-Landschütz ascites tumour cells preincubated for 30-60 min in phosphate-buffered Krebs-Ringer salt solution ("starved cells") resulted within 1-2 min in an approx. 90% decline of their ATP content and a massive accumulation of fructose 1,6-bisphosphate. These alterations, which took place under both aerobic and anaerobic conditions, were followed by a gradual spontaneous recovery with restoration of normal ATP and fructose 1,6-bisphosphate values. The transient derangement of the energy metabolism after glucose addition to starved ascites tumour cells by preventable by simultaneous addition of pyruvate or 2-oxobutyrate, or by preincubating the cells in the presence of glucose. The protective effect of pyruvate was duplicated by addition of phenazine methosulphate or NAD+ to the incubation medium. The data seem to warrant the conclusion that the glucose-induced ATP depletion is determined by a blockade of glycolysis at the stage of glyceraldehyde phosphate dehydrogenase caused by the failure of the cells to oxidize the NADH produced in the same reaction. The continued unrestrained action of 6-phosphofructokinase results in accumulation of fructose 1,6-bisphosphate, which constitutes a trap for the high-energy phosphate bonds of ATP. The primary metabolic disturbance appears to consist of a transient inhibition of pyruvate kinase with the resultant inability of the cells to maintain an unimpaired supply of pyruvate, as required for the lactate dehydrogenase-mediated oxidation of NADH. The regulatory mechanism underlying this phenomenon is discussed.     

Differences in coupling of energy to glycine and phenylalanine transport in aerobically grown Escherichia coli.

Differences exist in the coupling of energy to transport of glycine and phenylalanine in aerobically grown cells of Escherichia coli. Energy derived from respiration, although involved in both uptake systems, is not employed identically as shown by kinetic effects of cyanide and anoxia and by temperature dependencies. Additional evidence for aerobic differences was provided by the effects of azide which greatly decreased initial rates of uptake of glycine but not phenylalanine. The effect on glycine uptake was not due to uncoupling of oxidative phosphorylation or to a decrease in respiration rate. Evidence for anaerobic differences was provided by the addition of either glucose or ferricyanide to cell suspensions containing glycerol, thereby maintaining anoxic uptake of phenylalanine, but not glycine, at the aerobic level. Ferricyanide stimulation required a functional Ca, Mg-adenosine 5'-triphosphatase and involved cell metabolism. Ferricyanide was also found to produce differential stimulation of other amino acid transport systems; tyrosine, tryptophan and leucine uptakes were stimulated whereas those for alanine, proline, threonine, and glutamine were relatively unaffected.     

Metabolism under Microaerobic Conditions of Mitochondria from Cowpea Nodules

A method is described for isolating mitochondria from nodules of cowpea (Vigna unguiculata [L.] Walp.) under completely anaerobic conditions. The mitochondria were immediately active when incubated aerobically with substrates, and their respiration rates were higher than mitochondria prepared in air. The mitochondria lacked fumarate reductase and were not inhibited by 5% CO₂. When incubated under microaerobic conditions, their respiration could be measured by leghemoglobin spectroscopy. Microaerobic respiration was inhibited approximately 50% by 1 millimolar malonate, and was completely inhibited by cyanide. O₂ uptake and the ATP/O ratio declined under microaerobic conditions, and therefore ATP production may be low in the environment of infected nodule cells.     

Decreased glycolytic metabolism contributes to but is not the inducer of apoptosis following IL-3-starvation

IL-3 regulates the glycolytic pathway. In Baf-3 cells IL-3 starvation leads to a decrease in glucose uptake and in lactate production. To determine if there is a link between the decreased metabolism induced by growth factor-starvation and the induction of cell death, we have compared the cell death characteristics and the metabolic modifications induced by IL-3-deprivation or glucose-deprivation in Baf-3 cells. We show that in both conditions cells die by an apoptotic process which involves the activation of similar Caspases. Different metabolic parameters (i.e. intracellular ATP levels and lactate accumulation in the culture medium) were measured. We show that IL-3 deprivation leads to a partial decrease in lactate production in contrast to glucose deprivation that completely inhibits lactate production. Similarly following IL-3-starvation a significant drop in the intracellular ATP levels in live cells is observed only after 16 h when a large fraction, more than 50 per cent of cells, is already apoptotic. On the contrary, glucose deprivation is followed by an abrupt decrease in ATP levels in the first 2 h of treatment. However, in the presence of IL-3, cells are able to survive for an extended time in these conditions since 70% of cells survived with low ATP levels for up to 16 h. This was not due to partial inhibition of the apoptotic process by the low level of ATP as glucose-deprivation in the absence of IL-3 led to faster death kinetics of Baf-3 cells compared with IL-3 starvation only. These results indicate that the drop in ATP levels and the triggering of apoptosis can be dissociated in time and that when the glycolytic pathway is strongly inhibited, cells are able to survive with relatively low ATP levels if IL-3 is present. Finally we show that induction of bcl-x by IL-3 protects cells from glucose-deprivation induced cell death.     

Isolation and characterization of mutants defective in the cyanide-insensitive respiratory pathway of Pseudomonas aeruginosa.

The branched respiratory chain of Pseudomonas aeruginosa contains at least two terminal oxidases which are active under normal physiological conditions. One of these, cytochrome co, is a cytochrome c oxidase which is completely inhibited by concentrations of the respiratory inhibitor potassium cyanide as low as 100 microM. The second oxidase, the cyanide-insensitive oxidase, is resistant to cyanide concentrations in excess of 1 mM as well as to sodium azide. In this work, we describe the isolation and characterization of a mutant of P. aeruginosa defective in cyanide-insensitive respiration. This insertion mutant was isolated with mini-D171 (a replication-defective derivative of the P. aeruginosa phage D3112) as a mutagen and by screening the resulting tetracycline-resistant transductants for the loss of ability to grow in the presence of 1 mM sodium azide. Polarographic studies on the NADH-mediated respiration rate of the mutant indicated an approximate 50% loss of activity, and titration of this activity against increasing cyanide concentrations gave a monophasic curve clearly showing the complete loss of cyanide-insensitive respiration. The mutated gene for a mutant affected in the cyanide-insensitive, oxidase-terminated respiratory pathway has been designated cio. We have complemented the azide-sensitive phenotype of this mutant with a wild-type copy of the gene by in vivo cloning with another mini-D element, mini-D386, carried on plasmid pADD386. The complemented cio mutant regained the ability to grow on medium containing 1 mM azide, titration of its NADH oxidase activity with cyanide gave a biphasic curve similar to that of the wild-type organism, and the respiration rate returned to normal levels. Spectral analysis of the cytochrome contents of the membranes of the wild type, the cio mutant, and the complemented mutant suggests that the cio mutant is not defective in any membrane-bound cytochromes and that the complementing gene does not encode a heme protein.     

Induction by ethylene of cyanide-resistant respiration

Ethylene and cyanide induce an increase in respiration in a variety of plant tissues, whereas ethylene has no effect on tissues whose respiration is strongly inhibited by cyanide. It is suggested that the existence of a cyanide-insensitive electron transport path is a prerequisite for stimulation of respiration by ethylene.     

Proline and valine transport in Agrobacterium tumefaciens C-58

Abstract The transport of proline and valine by Agrobacterium tumefaciens was investigated. Proline uptake by starved cells was found to be higher in the presence of glucose than in its absence. Valine uptake, on the other hand, was lowered in the presence of glucose. Proline uptake was found to be insensitive to the action of dicyclohexyl carbodiimide (DCCD), a membrane ATPase inhibitor, whereas valine uptake appeared to show some sensitivity to this agent. The results obtained seem to suggest that the two transport systems make use of different energy stores.     

Respiration, cyanide-insensitive oxygen uptake and oxidative phosphorylation in cyanobacteria

Cyanide-insensitive oxygen uptake in the dark of 9 species of cyanobacteria was 6–20% of the total oxygen uptake of intact cells. In Phormidium , no cyanideinsensitive oxygen uptake was observed. In intact cells, the I₅₀ value for cyanide was significantly lower in cyanobacteria of the taxonomic sections I to III (1–9 μ M ) than in those from section IV and V (10–60 μ M ). Cyanide-insensitive oxygen uptake in the cell-free system of Anabaena variabilis was not affected by typical inhibitors of the alternative pathway of plants. Cell-free oxidation of cytochrome c was completely inhibited by cyanide with an I₅₀ value of 0.5–1 μ M . Electron transport of intact cells without cyanide present yielded P/O ratios of 0.7–3.0. The data on oxidative phosphorylation using intact cells and the cell-free system, indicate that cyanide-insensitive oxygen uptake is not coupled to ATP formation.     

Uptake of glycine betaine and its analogues by bacteroids of Rhizobium meliloti

Bacteroids isolated from alfalfa nodules induced by Rhizobium meliloti 102F34 transported glycine betaine at a constant rate for up to 30 min. Addition of sodium salts greatly increased the uptake activity, whereas other salts or non-electrolytes had less effect. The apparent Km for glycine betaine uptake was 8.3 microM and V was about 0.84 nmol min-1 (mg protein)-1 in the presence of 200 mM-NaCl which gave maximum stimulation of the transport. Supplementing bacteroid suspensions with various energy-yielding substrates, or ATP, did not increase glycine betaine uptake rates. The uncoupler carbonyl cyanide m-chlorophenylhydrazone (CCCP), and the respiratory inhibitor potassium cyanide strongly inhibited glycine betaine uptake, but arsenate was totally inactive. Glycine betaine transport showed considerable structural specificity: choline, proline betaine, gamma-butyrobetaine and trigonelline did not competitively inhibit the system, although choline and proline betaine were transported by bacteroids. Both a high-affinity activity and a low-affinity activity were found for choline uptake. These osmoprotective compounds might have a significant role in the maintenance of nitrogenase activity in bacteroids subjected to salt stress.     

The control by respiration of the uptake of α-methyl glucoside in Escherichia coli K12

The uptake of methyl α-d-glucopyranoside (α-MG) by Escherichia coli K12 was decreased by the addition of substrates which stimulated the rate of oxygen consumption by the cells. The inhibition, which occurred only at non-saturating concentrations of α-MG, was not the result of a stimulation of the rate of exit of intracellular α-MG, and was abolished by the presence of carbonyl cyanide m-chlorophenylhydrazone or sodium azide. Since those drugs inhibit energy conservation at the respiratory chain and did not alter significantly the rate of oxygen consumption under the conditions for the assay of α-MG uptake, it appears that the inhibition of the transport system by respirable substrates is mediated by some form of energy derived from respiration.     

A 31P NMR study on uptake and metabolism of hexose monophosphates in rat diaphragm muscle

Phosphorus nuclear magnetic resonance spectroscopy was used to study uptake and metabolic conversion of glycolytic intermediates in rat diaphragm muscles. The resonances of several phosphorus-containing metabolites were identified in the intact tissues and in their ethanolic extracts. Experiments on muscles preincubated with glucose 6-phosphate or glucose 1-phosphate indicated that: 1) both substrates penetrate into the tissue and actively participate in glycolytic reactions; 2) glucose 1-phosphate is completely converted into other metabolites, including glucose 6-phosphate and its products; 3) preincubation with either hexose monophosphate in the presence or in the absence of insulin produced the same set of phosphorylated metabolites. Addition of insulin to preincubation media induced a conspicuous spread of chemical shifts in the band arising from phosphorylated sugars in tissues incubated with glucose 1-phosphate but not in those treated with glucose 6-phosphate. The different responses to insulin exhibited by the 31P n.m.r. spectral profiles of tissues incubated with the two substrates substantiate the hypothesis that glucose 6-phosphate and its products may undergo their metabolic conversions in the tissue along distinct intracellular enzymatic pathways, on which insulin would exert different regulatory effects. This study indicates that 31P n.m.r. may provide a useful approach to the elucidation of metabolic processes involving sugar phosphates in intact tissues.