Prior PCB exposure suppresses hypoxia-induced up-regulation of glycolytic enzymes in Fundulus heteroclitus

Increased activity of the glycolytic enzymes is a conserved feature of the cellular response to hypoxia, and may represent a protective mechanism by which cells can survive short-term hypoxic exposure. Gene induction by hypoxia involves a dimer of the hypoxia inducible factor (HIF)-1 alpha and the nuclear cofactor HIF-1 beta, also called the aryl hydrocarbon receptor nuclear translocator (ARNT), which is also involved in induction of genes in response to aryl hydrocarbon exposure. To assess the possibility of interaction between these pathways, we examined changes in the activity of the glycolytic enzymes in response to hypoxia and polychlorinated biphenyl (PCB) exposure in the liver of a teleost fish, Fundulus heteroclitus. After 3 days of hypoxic exposure (dissolved oxygen levels between 1.5 and 2.0 mg/L), there were significant increases in the activity of six glycolytic enzymes (PGI, ALD, TPI, PGK, PGM and LDH). In contrast, intraperitoneal injection of 1 microg/g body weight of PCB #77 (3,3',4,4'-tetrachlorobiphenyl) caused significant decreases in glycolytic enzyme activity after 7 days of exposure. When fish were injected with PCB #77 and then (4 days later) exposed to hypoxia for 3 days as before, we observed no induction of the glycolytic enzymes. This suggests that there is an antagonistic interaction between exposure to PCBs and hypoxia in F. heteroclitus. Prior PCB exposure could make these fish less tolerant of environmental hypoxia.     

Increased phosphofructokinase content during chronic hypoxia in cultured skeletal muscle (L8) cells

Chronic hypoxia results in increased measured activity of all of the glycolytic enzymes and is associated with an increase in glycolytic capacity. Phosphofructokinase, a rate-limiting glycolytic enzyme, was measured under normoxic and hypoxic conditions to determine the relationship between increased activity and enzyme content. Monoclonal antibodies were used to isolate pure enzyme in rat skeletal muscle cells (L8) cultured hypoxically (PO2 = 14 torr) and normoxically (PO2 = 142 torr). Phosphofructokinase content per cell in cultures maintained under chronic (96 h) hypoxic conditions was twice that of cells cultured under normoxic conditions (0.0675 +/- 0.008 (S.E.) and 0.0345 +/- 0.003 micrograms enzyme protein/microgram DNA, P less than 0.01). Phosphofructokinase activity increased proportionately (hypoxia, 0.020 +/- 0.003; normoxia, 0.010 +/- 0.001 units/microgram DNA). The specific activity (units/mg enzyme protein) of phosphofructokinase in the hypoxic (296 +/- 32) versus the normoxic (290 +/- 15) cultures was not significantly different, indicating that the increased activity was accounted for by an increase in enzyme content. Glycolytic rate appears to be regulated at the level of enzyme content.     

Ultrastructure and metabolism of skeletal muscle fibres in the tench: Effects of long-term acclimation to hypoxia

Summary Tench (Tinca tinca) were acclimated to either aerated (P _{O 2} 17.6 KPa) or hypoxic (P _{O 2} 1.5 KPa) water for 6 weeks.Acclimation to hypoxia resulted in a decrease in mitochondrial volume fraction in both slow (22.9 to 15.0 %) and fast glycolytic (4.5 to 1.8 %) myotomal muscles fibres (P<0.01).Intermyofibrillar mitochondrial populations (4.4 to 1.2% slow; 0.6 to 0.04% fast fibres) were affected to a greater extent than those in the subsarcolemmal zone (18.5 to 13.8% slow; 3.9 to 1.8% fast fibres). After acclimation to hypoxia, cytochrome-oxidase activities decreased by 31 and 33 % in slow and fast fibres, respectively, but were maintained in the liver.Fibre size remained unchanged and actively differentiating fibres were observed in muscles from both groups of fish. Hypoxia resulted in a significant increase in myofibrillar volume fraction in both slow (43.1 to 56.1 %) and fast glycolytic fibres (73.1 to 82.7%) (P<0.05).Glycogen concentrations (mg/100g tissue) for liver (6616) slow muscle (1892) and fast muscle (334) were similar for fish acclimated to aerated or hypoxic water. Acclimation to hypoxia increased carnitine palmitoyl transferase activity (moles substrate utilised g·dry wt_-1 min^-1) in slow (0.42 to 1.1), fast glycolytic muscle (<0.01 to 0.15) and liver (1.1 to 3.7) indicating an enhanced capacity for fatty acid oxidation.Phosphofructokinase activities of fast glycolytic fibres were similar in fish acclimated to either aerated or hypoxic water, consistent with an unaltered capacity for anaerobic glycogenolysis. Hexokinase activities (moles substate utilised, g·dry wt^-1 min^-1) decreased in fast fibres (1.2 to 0.4) but were maintained in the slow muslce (2.1 to 2.5) and liver (4.5 to 4.8) of hypoxic fish. The activities of phosphofructokinase in slow muscle and phosphofructokinase, pyruvate kinase and lactate dehydrogenase in liver were two times higher in fish acclimated to hypoxia. An enhanced capacity for glycolysis in these tissues may reflect a reduced threshold for anaerobic metabolism during activity and/or an adaptation for acute exposure to anoxia in fish acclimated to hypoxia.Abbreviations/Glossary CO cytochrome oxidase activity - CPT carnitine palmitoyltransferase activity - HK hexokinase activity - LDH lactate dehydrogenase activity - PFK phosphofructokinase activity - PK pyruvate kinase activity - Vv volume fractions of cell components - normoxic fish acclimated to aerated water - hypoxic fish acclimated to reduced oxygen tensions - P _{O 2} partial pressure of oxygen tension A preliminary account of part of this work was presented at theXth European Meeting on Muscle and Cell Motility held at Galway, Ireland, in September 1981     

Potential role for pyruvate kinase M2 in the regulation of murine cardiac glycolytic flux during in vivo chronic hypoxia

Carbohydrate metabolism in heart failure shares similarities to that following hypoxic exposure, and is thought to maintain energy homoeostasis in the face of reduced O₂ availability. As part of these in vivo adaptations during sustained hypoxia, the heart up-regulates and maintains a high glycolytic flux, but the underlying mechanism is still elusive. We followed the cardiac glycolytic responses to a chronic hypoxic (CH) intervention using [5-³H]-glucose labelling in combination with detailed and extensive enzymatic and metabolomic approaches to provide evidence of the underlying mechanism that allows heart survivability. Following 3 weeks of in vivo hypoxia (11% oxygen), murine hearts were isolated and perfused in a retrograde mode with function measured via an intraventricular balloon and glycolytic flux quantified using [5-³H]-glucose labelling. At the end of perfusion, hearts were flash-frozen and central carbon intermediates determined via liquid chromatography tandem mass spectrometry (LC-MS/MS). The maximal activity of glycolytic enzymes considered rate-limiting was assessed enzymatically, and protein abundance was determined using Western blotting. Relative to normoxic hearts, CH increased ex vivo cardiac glycolytic flux 1.7-fold with no effect on cardiac function. CH up-regulated cardiac pyruvate kinase (PK) flux 3.1-fold and cardiac pyruvate kinase muscle isoenzyme M2 (PKM2) protein content 1.4-fold compared with normoxic hearts. CH also augmented cardiac pentose phosphate pathway (PPP) flux, reflected by higher ribose-5-phosphate (R5P) content. These findings support an increase in the covalent (protein expression) and allosteric (flux) control of PKM2 as being central to the sustained up-regulation of the glycolytic flux in the chronically hypoxic heart.     

Organization of the glycolytic enzymes in Escherichia coli

Differential centrifugation of osmotically lysed lysozyme-EDTA spheroplasts from Escherichia coli sedimented 50–70% of the glycolytic activities examined in a low speed pellet; the remaining activity, occurring in a high speed supernatant, contained the soluble enzymes of the cell. The distribution pattern of the enzymes could be altered by extrusion of the spheroplasts through the French Press or by lysis at different pH values. Electron micrographs of the pellet fraction revealed lysed spheroplasts mostly devoid of cellular constituents but consisting of cytoplasmic membranes surrounded by partially degraded cell wall fragments. Washing of the pellet showed that the enzymes were not all bound to the same degree to the membrane fraction. Throughput activity of the glycolytic pathway was demonstrated for the membrane fraction, but none was observed for the soluble fraction of the cell (i.e. for enzymes present in the supernatants) unless these were first concentrated by ultrafiltration. The supernatant from the lysed spheroplasts, together with a further supernatant obtained by washing the membrane pellet, was concentrated by ultrafiltration and chromatographed on a Bio-Gel column. The eluate contained glycolytic activities both in fractions corresponding to relatively high and relatively low molecular weight material The high molecular weight species, containing a proportion of all the enzymes studied, had a molecular weight of at least 1.2 × 10⁶. A multienzyme aggregate containing one each of the glycolytic enzymes would have a molecular weight of ～ 1.3 × 10⁶. The specific rate of pyruvate formation from glucose by the high molecular weight species was similar to that obtained from a preparation in which the fractions containing all the low molecular weight material enzyme activities were pooled and concentrated by ultrafiltration. Using the high molecular weight material, studies were made of the ability of added unlabelled glycolytic intermediates to compete for catalytic sites with intermediates produced endogenously from [¹⁴C₆] glucose. The relatively weak competition observed indicated a high degree of protection afforded the labelled intermediates derived from [¹⁴C₆] glucose.     

Plasmodium berghei: Glycolytic enzymes of the infected mouse erythrocyte

This paper documents the maximal activities of the glycolytic enzymes in the red blood cells of normal mice and mice infected with Plasmodium berghei. There appears to be sufficient parasite-related activity of each glycolytic enzyme to support the increased glycolytic rate, i.e., increased glucose consumption, of the parasite-infected red blood cell. The relative proportions of glycolytic enzyme activities in parasite-infected red cells are different from the proportions in either normal or reticulocyte-rich blood, indicating that the increased enzyme activities associated with infected cells are not due to contaminating host red cells or reticulocytes. A comparison of maximal enzyme activities to the rate of whole cell glucose consumption indicates that different glycolytic control mechanisms are operating in the infected RBC from those in the uninfected cells.     

Hypoxia induces oxidative stress in tissues of a goby, the rotan Perccottus glenii

The effects of hypoxia (0.4 mg O₂/L) for 2, 6 or 10 h and subsequent normoxic recovery on the levels of lipid peroxides, thiobarbituric acid reactive substances, protein carbonyls (CP), free thiols, and the activities of six antioxidant and associated enzymes were measured in the brain, liver, and skeletal muscle of the rotan Perccottus glenii. Hypoxia increased CP content in the brain (5.0–7.4-fold), liver (2.2–3.3-fold) and muscle (3.2–61-fold) relative to controls and the levels remained elevated during recovery. Lipid peroxide content rose within 2 h of hypoxia in all tissues examined with the most marked increase (8.7-fold) in the liver, but decreased again during longer hypoxic exposure except in the muscle. Levels of low-molecular mass thiols were transiently lowered after 2 h hypoxia in all tissues, but were higher compared with controls after longer hypoxic exposure and recovery. Hypoxia decreased protein thiol content in the liver and muscle that return to control levels during recovery. Experimental conditions affected enzyme activities in a different manner. Superoxide dismutase activity rose two-fold in the liver of hypoxic fish, and a similar tendency was seen in muscle glutathione-S-transferase. Activities of other enzymes were decreased or unchanged during hypoxia and elevated in some cases during normoxic recovery. Taken together, these data show that hypoxia resulted in the development of oxidative stress and a compensatory changes of antioxidant enzymes in the tissues.     

Glucose catabolism during aging and differentiation in hypocotyls ofPhaseolus mungo seedlings

Changes in activities of the glycolytic and pentose phosphate (PP) pathways in glucose catabolism in various parts of the hypocotyls obtained from 4-day-old etiolatedPhaseolus mungo seedlings were investigated by measuring the inhibition rates of respiration by iodoacetate and malonate, and the release of¹⁴CO₂ from [1-¹⁴C]- and [6-¹⁴C]glucose. The relative activity of the PP pathway in glucose catabolism was higher in the immature part (Part I) and the aged part (Part V) of the hypocotyls than in the intermediary one (Part III), while the activity of the glycolytic pathway decreased with aging. On a fresh weight basis, the enzyme activities of the glycolytic and PP pathways were higher in Part I than in Parts III and V. On a protein content basis, however, activities of the enzymes of the PP pathway increased with aging and differentiation of the hypocotyls whereas those of the glycolytic pathway decreased. Levels of nicotinamide adenine nucleotides were found to be in the following order: Part I>Part III> Part V for NAD⁺+NADH; Part I>Part V>Part III for NADP⁺+NADPH. The stimulative effect of methylene blue on decreasing the C₆/C₁ ratio was greater in Part III than in Part I, and No effect was observed in Part V. These data suggest that a decrease in the activity of the glycolytic pathway with aging and differentiation may be due to the decreasing glycolytic enzyme activities and NAD(H) content. The higher activity of the PP pathway in the immature part is attributable to larger amounts of NADP(H) and enzymes of the PP pathway. The greater contribution of the PP pathway to glucose catabolism in the aged part than in the intermediary part seems to results from a more active turnover of NADP and the relatively higher activity of the enzymes of the PP pathway than those of the glycolytic pathway.     

Energy metabolism transition in multi-cellular human tumor spheroids

It is thought that glycolysis is the predominant energy pathway in cancer, particularly in solid and poorly vascularized tumors where hypoxic regions develop. To evaluate whether glycolysis does effectively predominate for ATP supply and to identify the underlying biochemical mechanisms, the glycolytic and oxidative phosphorylation (OxPhos) fluxes, ATP/ADP ratio, phosphorylation potential, and expression and activity of relevant energy metabolism enzymes were determined in multi-cellular tumor spheroids, as a model of human solid tumors. In HeLa and Hek293 young-spheroids, the OxPhos flux and cytochrome c oxidase protein content and activity were similar to those observed in monolayer cultured cells, whereas the glycolytic flux increased two- to fourfold; the contribution of OxPhos to ATP supply was 60%. In contrast, in old-spheroids, OxPhos, ATP content, ATP/ADP ratio, and phosphorylation potential diminished 50-70%, as well as the activity (88%) and content (3 times) of cytochrome c oxidase. Glycolysis and hexokinase increased significantly (both, 4 times); consequently glycolysis was the predominant pathway for ATP supply (80%). These changes were associated with an increase (3.3 times) in the HIF-1alpha content. After chronic exposure, both oxidative and glycolytic inhibitors blocked spheroid growth, although the glycolytic inhibitors, 2-deoxyglucose and gossypol (IC(50) of 15-17 nM), were more potent than the mitochondrial inhibitors, casiopeina II-gly, laherradurin, and rhodamine 123 (IC(50) > 100 nM). These results suggest that glycolysis and OxPhos might be considered as metabolic targets to diminish cellular proliferation in poorly vascularized, hypoxic solid tumors.     

Stress and interpopulation variation in glycolytic enzyme activity and expression in a teleost fish Fundulus heteroclitus

Northern populations of Fundulus heteroclitus have twofold greater activity of lactate dehydrogenase-B (LDH-B) than southern populations, but exposure to stress increases LDH-B in southern populations, abolishing this difference. To test whether differences in the activity of other hepatic glycolytic enzymes between populations are sensitive to stress, we injected fish with a pharmacological dose of cortisol in coconut oil (400 microg g(-1)) or exposed them to handling stress and measured the activities of all the glycolytic enzymes. At rest, liver phosphofructokinase (PFK) and aldolase (ALD) activities were greater in southern fish, whereas LDH-B activity was greater in northern fish. No other glycolytic enzymes differed in activity between populations in control fish. Cortisol injection and handling stress decreased PFK and ALD and increased LDH activities in the southern but not the northern population, such that the populations no longer differed in the activity of any enzyme following treatment. Unlike Ldh-B mRNA, Pfk and Ald mRNA levels did not parallel enzyme activity, suggesting complex kinetics or regulation at multiple levels. Plasma cortisol did not differ between populations at rest but was significantly different between populations in treated fish. These data suggest that differences in liver enzyme activity may be related to differences in stress hormone physiology between populations.     

Glycolytic adjustments in tissues of frog Rana ridibunda and land snail Helix lucorum during seasonal hibernation

The present work aimed to contribute to the understanding of the adaptation of the glycolytic pathway in tissues of frog Rana ridibunda and land snail species Helix lucorum during seasonal hibernation. Moreover responses of glycolytic enzymes from cold acclimated R. ridibunda and H. lucorum were studied as well. The drop in Po₂ in the blood of hibernated frogs and land snails indicated lower oxygen consumption and a decrease in their metabolic rate. The activities of glycolytic enzymes indicated that hibernation had a differential effect on the glycolyis in the two species studied and also in the tissues of the same species. The activity of l-LDH decreased significantly in the skeletal muscle and heart of hibernated R. ridibunda indicating a low glycolytic potential. Similar biochemical responses were observed in the same tissues during cold acclimation. The continuous increase in the activities of glycolytic enzymes studied, except for HK, might indicate a compensation for the impacts of low temperature on the enzymatic activities. In contrast to R. ridibunda, the activities of the enzymes increased and remained at higher levels than those of the prehibernation controls indicating maintenance of glycolytic potential in the tissues of hibernating land snails.     

Decrease in phosphofructokinase activity during blood preservation and the effect of intracellular ATP

The activities of 15 enzymes, including all the glycolytic enzymes, were observed during the preservation of human red cells at 4°C. After 8 weeks, phosphofructokinase (PFK) activity had decreased most. The decrease was prevented by the addition of adenine and inosine to the preservation medium, but not at all by inosine alone and only slightly by adenine alone. This decrease paralleled that of the decrease of intracellular ATP. PFK in the hemolysate was inactivated rapidly, but the inactivation was effectively prevented by ATP. The decrease in glycolytic activity during preservation was concluded to be a result of the loss of PFK activity, and this in turn was due to the decrease of ATP.     

Chronic hypoxia in development selectively alters the activities of key enzymes of glucose oxidative metabolism in brain regions

The immature brain is more resistant to hypoxia/ischemia than the mature brain. Although chronic hypoxia can induce adaptive-changes on the developing brain, the mechanisms underlying such adaptive changes are poorly understood. To further elucidate some of the adaptive changes during postnatal hypoxia, we determined the activities of four enzymes of glucose oxidative metabolism in eight brain regions of hypoxic and normoxic rats. Litters of Sprague-Dawley rats were put into the hypoxic chamber (oxygen level maintained at 9.5%) with their dams starting on day 3 postnatal (P3). Age-matched normoxic rats were use as control animals. In P10 hypoxic rats, lactate dehydrogenase (LDH) activity in cerebral cortex, striatum, olfactory bulb, hippocampus, hypothalamus, pons and medulla, and cerebellum was significantly increased (by 100%–370%) compared to those in P10 normoxic rats. In P10 hypoxic rats, hexokinase (HK) activity in hypothalamus, hippocampus, olfactory bulb, midbrain, and cerebral cortex was significantly decreased (by 15%–30%). Neither -ketoglutarate dehydrogenase complex (KGDHC, which is believed to have an important role in the regulation of the tricarboxylic acid [TCA] cycle flux) nor citrate synthase (CS) activity was significantly decreased in the eight regions of P10 hypoxic rats compared to those in P10 normoxic rats. In P30 hypoxic rats, LDH activity was only increased in striatum (by 19%), whereas HK activity was only significantly decreased (by 30%) in this region. However, KGDHC activity was significantly decreased in olfactory bulb, hippocampus, hypothalamus, cerebral cortex, and cerebellum (by 20%–40%) in P30 hypoxic rats compared to those in P30 normoxic rats. Similarly, CS activity was decreased, but only in olfactory bulb, hypothalamus, and midbrain (by 9%–21%) in P30 hypoxic rats. Our results suggest that at least some of the mechanisms underlying the hypoxia-induced changes in activities of glycolytic enzymes implicate the upregulation of HIF-1. Moreover, our observation that chronic postnatal hypoxia induces differential effects on brain glycolytic and TCA cycle enzymes may have pathophysiological implications (e.g., decreased in energy metabolism) in childhood diseases (e.g., sudden infant death syndrome) in which hypoxia plays a role.     

Induction by Oxygen of Respiration and Phosphorylation of Anaerobically Grown Escherichia coli

The changes occurring in the respiratory enzymes of anaerobically grown Escherichia coli strain B and E. coli 15 T⁻A⁻U⁻bar during exposure to oxygen were studied. Reduced nicotinamide adenine dinucleotide (NADH) oxidase activity reached its peak soon after O₂ exposure; cytochrome content and succinate oxidase activity increased more slowly, and these increases paralleled each other. The activities of isocitrate and malate dehydrogenases also increased, but the increase was less than that of the succinate and NADH oxidases; exposure to O₂ had no effect on the succinate and NADH dehydrogenase activities. On the other hand, the glycolytic activity decreased slowly after O₂ exposure. The incorporation of ³²P into acid-soluble organic phosphate esters paralleled the respiratory rate during the first 60 min after O₂ exposure, but continued to increase after the respiration reached a plateau. The sensitivity of ³²P incorporation to the uncoupler carbonyl cyanide m-chlorophenylhydrazone also increased with time. The observed relationship between the development of the respiratory chain and the energy-conserving mechanism during O₂ exposure is discussed. Synthesis of the respiratory enzymes upon exposure to oxygen was dependent on concomitant protein and ribonucleic acid synthesis but not on deoxyribonucleic acid synthesis.     

Glycolytic enzymes and intermediates in carbon catabolite repression mutants of Saccharomyces cerevisiae

Summary Glycolytic parameters were determined in recessive yeast mutants with partial defects in carbon catabolite repression. Specific activities of pyruvate kinase and pyruvate decarboxylase in glucose grown cells of all mutant and wild type stains were 4–5 times higher than in ethanol grown cells. Mutants of gene HEX1 had a reduced hexose phosphorylating activity on allmedia wheras those of gene HEX2 had elevated levels but only in glucose grown cells. Mutants of gene CAT80 were normal in this respect. All other glycolytic enzymes were normal in all mutants. This was also true for glycolytic intermediates. Only hexlmutants showed a reduced fermentation of repressing sugars. The three genes appear to be involved in catabolite repression of several but not of all repressible enzymes. Even though all three types of mutants show a limited overlap in their effects on certain enzymes, they still are distinctly different in their action spectra. Carbon catabolite repression apparently does not depend on the sole accumulation of glycolytic intermediales. The activity of the products of the three genes HEX1, HEX2 and CAT80 are required directly or indirectly for triggering carbon catabolite repression. Even a small segment of carbon catabolite repression is controlled by several genes with regulatory functions indicating that the entire regulatory circuit is highly complex.     

Investigation of glucose catabolism in hypoxic Mcf 7 breast cancer culture

Hypoxia plays an important role in tumor phenotype and progression and alters glycolysis, with changes in signaling pathways that develop in response to hypoxia. In this study, the effects of oxygen (normoxia/hypoxia) and of glucose levels on the glucose metabolism was investigated in MCF-7 cancer cells. Under either normoxia or hypoxia conditions, the cells were exposed to glucose at different concentrations (0, 5.5, 15 or 55 mM) for either 3, 6, 12, 24 or 48 h. In all groups, cell viability, levels of key enzymes reflecting glycolytic metabolism in cell lysates, glucose consumed in the medium and extracellular lactate levels and wound closure percentages were determined. In hypoxic cells, intracellular consumption of glucose, and extracellular lactate levels due to increased glucose concentration were observed to be higher (compared to normoxia) and as a result of prolonged exposure to hypoxia, cells were observed to develop resistance to the prolonged exposure to hypoxia. The number of glycolytic enzymes obtained at different levels proved that cells had different potential capacities and changing mechanisms for the metabolic needs of the cell depending on the glucose amount in the medium and time in adapting to the oxygen tension. This study showed that there was an important interaction between hypoxia and glucose metabolism in general, and it was concluded that metabolic processes activated by hypoxia could offer new therapeutic targets.     

The role of phosphofructokinase in glycolytic control in the facultative anaerobe Sipunculus nudus

Summary The involvement of phosphofructokinase (PFK) in glycolytic control was investigated in the marine peanut worm Sipunculus nudus. Different glycolytic rates prevailed at rest and during functional and environmental anaerobiosis: in active animals glycogen depletion was enhanced by a factor of 120; during hypoxic exposure the glycolytic flux increased only slightly. Determination of the mass action ratio (MAR) revealed PFK as a non-equilibrium enzyme in all three physiological situations. Duirng muscular activity the PFK reaction was shifted towards equilibrium; this might account for the observed increase in glycolytic rate under these conditions. PFK was purified from the body wall muscle of S. nudus. The enzyme was inhibited by physiological ATP concentrations and an acidic pH; adenosine monophosphate (AMP), inorganic phosphate (P_i), and fructose-2,6-bisphosphate (F-2,6-P₂) served as activators. PFK activity, determined under simulated cellular conditions of rest and muscular work, agreed well with the glycolytic flux in the respective situations. However, under hypoxia PFK activity surpassed the glycolytic rate, indicating that PFK may not be rate-limiting under these conditions. The results suggest that glycolytic rate in S. nudus is mainly regulated by PFK during rest and activity. Under hypoxic conditions the regulatory function of PFK is less pronounced.Abbreviations ATP, ADP, AMP adenosine tri-, di-, monophosphate - DTT dithiothreitol - EDTA ethylene diaminetetra-acetic acid - F-6-P fructose-6-phosphate - F-1,6-P₂ fructose-1,6-bisphosphate - F-2,6-P₂ fructose-2,6-bisphosphate; bwm, body wall muscle; fresh mass, total body weight - G-6-P glucose-6-phosphate - H enthalpy change - K _a activation constant - K _eq equilibrium constant - K _i inhibition constant - K _m Michaelis constant - MAR mass action ratio - NMR nuclear magnetic resonance - PFK phosphofructokinase - P_i inorganic phosphate - PLA phospho-l-arginine - SD standard deviation - TRIS, TRIS (hydroxymethyl) aminomethane - TRA triethanolamine hydrochloride - V _max maximal velocity     

Hypoxic incubation leads to concerted changes of carbonic anhydrase activity and 2.3 DPG concentration of chick embryo red cells

Red cell carbonic anhydrase activity, 2.3 DPG concentration, and activities of three key enzymes controlling DPG metabolism (PK, PFK and DPGM) were measured in normoxic and hypoxic (incubation in 13.5% O₂) chick embroys. In normoxia 2.3 DPG concentration and carbonic anhydrase activity begin to increase by the third week of incubation. Hypoxia induces a rise of 2.3 DPG concentration and carbonic anhydrase activity by Day 8 of development, i.e., 1 week earlier. Since during normal development chick embryos become hypoxic in the third week of incubation, the results suggest that PO₂ has a controlling influence on the timing of differentiation events of definitive embryonic red cells.