Effect of anaerobiosis and anhydrobiosis on the extent of glycolytic enzyme binding in Artermia embryos

The effect of anaerobiosis and anhydrobiosis on the extent of binding of glycolytic enzymes to the particulate fraction of the cell was studied in Artemia salina embryos. During control aerobic development, trehalase, phosphofructokinase and pyruvate kinase showed an increase in the percentage associated with the particulate fraction which is consistent with the carbohydrate-based metabolism of Artemia embryos. However, anaerobiosis resulted in decreased enzyme binding for six glycolytic enzymes; hexokinase, aldolase, pyruvate kinase and lactate dehydrogenase were the exceptions. Decreased enzyme binding was also observed after exposure to dehydrating conditions. The results suggest that glycolytic rate could be regulated by changes in the distribution of glycolytic enzymes between free and bound forms in Artemia embryos. This reversible interaction of glycolytic enzymes with structural proteins may account for part of the metabolic arrest observed during anaerobic dormancy and anhydrobiosis.Abbreviation pH_i intracellular concentration of H⁺ ions     

Glycolytic enzyme binding and metabolic control in anaerobiosis

Summary Metabolic rate depression is a key survival strategy used by facultative anaerobes for enduring periods of environmental anoxia. In determining the molecular mechanisms of this phenomenon the role of enzyme binding to the subcellular particulate fraction was assessed in muscle tissues (ventricle and foot) of the anoxia tolerant marine gastropod,Busycotypus canaliculatum. Using two different methodologies for preparation, soluble versus particulate fractions of muscle were separated and assayed for their contents of eight glycolytic enzymes. Preparations from anoxic animals showed decreased percentages of enzymes associated with the particulate fraction as compared to controls; this was particularly pronounced for hexokinase and aldolase. A return to aerated seawater reversed this effect, and increased enzyme binding to the particulate fraction. The absence of a Pasteur effect in animal facultative anaerobes may be due, in part, to an anoxia-induced dissociation of enzymes from the particulate fraction of the cell promoting a decrease in glycolytic rate.Abbreviations HK hexokinase - PFK phosphofructokinase - GPDH glycerol-3-phosphate dehydrogenase - PK pyruvate kinase - LDH lactate dehydrogenase - ADH alanopine dehydrogenase - ODH octopine dehydrogenase - ALD aldolase - EDTA ethylenediamine tetraacetic acid - EGTA ethyleneglycol-bis-(2-amino ethylether)-N,N-tetraacetic acid     

Role of covalent modification in the control of glycolytic enzymes in response to environmental anoxia in goldfish

Summary The effects of environmental anoxia (24 h at 7°C in N₂/CO bubbled water) on the maximal activities, selected kinetic properties, and isoelectric points of phosphofructokinase and pyruvate kinase were measured in eight tissues of the goldfish,Carassius auratus, in order to evaluate the role of possible covalent modification of enzymes in glycolytic rate control and metabolic depression during facultative anaerobiosis. Both enzymes showed modified kinetic properties as a result of anoxia in liver, kidney, brain, spleen, gill, and heart. Effects of anoxia on properties of pyruvate kinase included reducedV _max, increased S_0.5 for phosphoenolpyruvate, increasedK _a for fructose-1,6-bisphosphate, and strongly reduced I₅₀ for alanine; all these effects are consistent with an anoxia-induced phosphorylation of pyruvate kinase to produce a less active enzyme form. Anoxia-induced alterations in phosphofructokinase kinetics included tissue-specific changes in S_0.5 for fructose-6-phosphate, Hill coefficient,K _a values for fructose-2,6-bisphosphate, AMP, and NH ₄ ⁺ , and I₅₀ values for ATP and citrate, the direction of changes being generally consistent with the production of a less active enzyme form in the anoxic tissue. Enzymes from aerobic versus anoxic skeletal muscle (both red and white) did not differ in kinetic properties but anoxic enzyme forms had significantly different pI values than the corresponding aerobic forms. Enzyme phosphorylation-dephosphorylation as the basis of the anoxia-induced changes in the kinetic properties of PFK and PK was further tested in liver: treatment of the aerobic forms of both enzymes with cAMP dependent protein kinase altered enzyme kinetic properties to those typical of the anoxic enzymes while alkaline phosphatase treatment of the anoxic enzyme forms had the opposite effect. The data provide strong evidence that coordinated glycolytic rate control, as part of an overall metabolic rate depression during anoxia, is mediated via anoxia-induced covalent modification of regulatory enzymes.Abbreviations cAMP cyclic 35 adenosine monophosphate - F16P ₂ fructose-1,6-bisphosphate - F26P ₂ fructose-2,6-bisphosphate - F6P fructose-6-phosphate - PEP phosphoenolpyruvate - PFK phosphofructokinase (E.C. 2.7.1.11) - PK pyruvate kinase (E.C. 2.7.1.40) - PMSF phenylmethylsulfonyl fluoride     

Differential survival of Venus gallina and Scapharca inaequivalvis during anoxic stress: Covalent modification of phosphofructokinase and glycogen phosphorylase during anoxia

Summary Biochemical mechanisms underlying anaerobiosis were assessed in two Mediterranean bivalve species, Scapharca inaequivalvis and Venus gallina, with widely differing tolerances for oxygen lack. These species displayed LT₅₀ values for anoxic survival at 17–18°C of 17 and 4 d, respectively. Succinate and alanine were the major products of 24 h anaerobic metabolism in both species but only S. inaequivalvis further metabolized succinate to propionate. Both species reduced metabolic rate while anoxic but metabolic arrest was more pronounced in S. inaequivalvis. Calculated ATP turnover rate (MATP) during exposure to N₂-bubbled seawater was only 4.51% of the aerobic rate in S. inaequivalvis but was 12.68% in V. gallina. To counteract a greater load of acid end products, V. gallina foot showed a significantly greater buffering capacity, 23.38±0.20 slykes, compared to 19.6±0.79 slykes in S. inaequivalvis. The two species also differed distinctly in the enzymatic regulation of anaerobiosis. In V. gallina anoxia exposure caused only a small change in PFK kinetic parameters (a decrease in K_a AMP) and had no effect on glycogen phosphorylase. By contrast, S. inaequivalvis foot showed a strong modification of enzyme properties in anoxia. The percentage of glycogen phosphorylase in the a form dropped significantly only in S. inaequivalvis. Other changes included alterations in the properties of PFK leading to a less active enzyme form in anoxia. Compared to the aerobic enzyme form, PFK from anoxic foot showed a reduced affinity for fructose-6-P (K_m increased 2.4-fold), greater inhibition by ATP (I₅₀ decreased 6.8-fold), and an increase in sensitivity to AMP activation (K_a decreased by 50%). These enzyme changes appear to be key to a glycolytic rate depression during anaerobiosis in S. inaequivalvis foot muscle.Abbreviations EDTA ethylenediaminetetraacetic acid - EGTA ethyleneglycol-bis-(2-aminoethyl)-tetraacetic acid - Fructose-2,6-P ₂ fructose-2,6-bisphosphate - Fructose-6-P fructose-6-phosphate - K _a AMP Activation constant (concentration of AMP required to increase the reaction to twice the rate it shows in the absence of AMP) - MATP ATP turnover rate - P _i inorganic phosphate - PCA Perchloric acid - PFK 6-phosphofructo-1-kinase - TCA Trichloroacetic acid     

Anoxia and freezing exposures stimulate covalent modification of enzymes of carbohydrate metabolism in Littorina littorea

The effects of anoxia (N₂ atmosphere at 5 °C) or freezing (at-8 °C) exposure in vivo on the activities of five enzymes of carbohydrate metabolism were assessed in foot muscle and hepatopancreases of the marine periwinkle Littorina littorea. Changes in glycogen phosphorylase, glycogen synthetase, pyruvate kinase and pyruvate dehydrogenase under either stress were generally consistent with covalent modification of the enzymes to decrease enzyme activity and/or convert the enzyme to a less active form. However, no evidence for a similar covalent modification of phosphofructokinase was found. The metabolic effects of freezing and anoxia were generally similar, suggesting that a primary contributor to freezing survival is the implementation of anaerobic metabolism and metabolic arrest mechanisms that also promote anoxia survival in marine molluses. However, in hepatopancreas phosphorylase was activated and pyruvate kinase remained in two enzyme forms in freezing-exposed snails, contrary to the results for anoxic animals. Ion exchange chromatography on DE-52 Sephadex revealed the presence of two forms of pyruvate kinase in both tissues of control L. littorea, eluting at 30–50 mmol·1^-1 KCl (peak I) or 90–110 mmol·1^-1 KCl (peak II). Anoxia exposure converted pyruvate kinase in both tissues to the peak I form, as did freezing for foot muscle pyruvate kinase. Kinetic analysis showed that peak I pyruvate kinase had lower affinities for substrates, phosphoenolpyruvate and ADP, and was very strongly inhibited by l-alanine compared with the peak II enzyme. Peak I pyruvate kinase had an I ₅₀ value for l-alanine of 0.38 mmol·1^-1, whereas peak II pyruvate kinase was unaffected by l-alanine evenat 40 mmol·1^-1. In vitro incubation of extracts from control foot muscle under conditions promoting phosphorylation or dephosphorylation identified the peak I and II forms as the low and high phosphate forms, respectively. This result for L. littorea pyruvate kinase was highly unusual and contrary to the typical effect of anoxia on pyruvate kinase in marine molluscs which is to stimulate the phosphorylation of pyruvate kinase and, thereby, convert the enzyme to a less active form.Abbreviations AABS p-(p-aminophenylazo)benzene sulphonic acid - F2, 6P fructose-2,6-bisphosphate - F6P fructose-6-phosphate - G6P glucose-6-phosphate - GP glycogen phosphorylase - GS glycogen synthase - I ₅₀ inhibitor concentration reducing enzyme velocity by 50% - MR metabolic rate - PDH pyruvate dehydrogenase - PEP phosphoenopyruvate - PFK phosphofructokinase - PK pyruvate kinase - SW sea water - F _a air temperature - TCA trichloroacetic acid - UDPG uridine-diphosphate glucose - WW wet weight     

The reversible binding of glycolytic enzymes in ovine skeletal muscle in response to tetanic stimulation

The extent of binding of glycolytic enzymes to the particulate fraction of homogenates was measured in sheep hind muscles after electrical stimulation. As compared to the control muscles, stimulation led to significant increases in the amount of phosphofructokinase, aldolase and glyceraldehyde-3-phosphate dehydrogenase bound to the particulate fraction. The bindng of other glycolytic enzymes was not significantly altered. A servey of different hind limb muscles at variable rates of stimulation revealed that each muscle exhibited its own characteristic response pattern in terms of the level of increased enzyme binding. Generally, an increased stimulation rate led to greater enzyme adsorption. The increase in enzyme binding was rapidly reversible for it was shown that the amount of enzyme bound quickly returned to control values when the muscles were allowed to recover in the live anaesthetised animal following cessation of stimulation. Those muscles which exhibited increased enzyme binding were characterised by a marked loss of glycogen and accumulation of lactate suggesting that accelerated glycolytic flux was a necessary condition for the observation of increased enzyme binding. In support of this, enzyme adsorption was observed to be greatest on stimulation of ischemic muscles, whereas in trained muscles, or muscles with depleted glycogen stores induced by prior adrenalin treatment, the increased enzyme binding response was greatly diminished. It is concluded that the variable binding of key glycolytic enzymes has a role to play in the regulation of glycolytic behaviour in skeletal muscle.     

Effect of electrical stimulation post mortem of bovine muscle on the binding of glycolytic enzymes. Functional and structural implications.

The extent of binding of glycolytic enzymes to the particulate fraction of homogenates was measured in bovine psoas muscle before and after electrical stimulation. In association with an accelerated glycolytic rate on stimulation, there was a significant increase in the binding of certain glycolytic enzymes, the most notable of which were phosphofructokinase, aldolase, glyceraldehyde 3-phosphate dehydrogenase and pyruvate kinase. From the known association of glycolytic enzymes with the I-band of muscle it is proposed that electrical stimulation of anaerobic muscle increases enzyme binding to actin filaments. Calculations of the extent of enzyme binding suggest that significant amounts of enzyme protein, particularly aldolase and glyceraldehyde 3-phosphate dehydrogenase, are associated with the actin filaments. The results also imply that kinetic parameters derived from considerations of the enzyme activity in the soluble state may not have direct application to the situation in the muscle fibre, particularly during accelerated glycolysis.     

Biochemical and histochemical changes in energy supply enzyme pattern of muscles of the rat during old age.

Senile muscles of the rat (28-36 months) show loss of overall activity of glycolytic and aerobic enzymes. However, there is a differential loss and shift of enzyme activity pattern in the three types of muscles. The extensor digitorum longus (EDL) and diaphragm show a decrease of ratios of glycolytic to aerobic-oxidative enzymes. This shift to a more oxidative type of metabolism is not observed in the soleus muscle. Decrease of enzyme activities is least marked in the diaphragm muscle. Biochemical analysis shows a trend to levelling out of metabolic differences between the different muscle types. This trend of 'dedifferentiation' is most marked when comparing EDL and soleus, least marked when comparing EDL and diaphragm muscle. The histochemical analysis shows a shift from the original mixed to a more uniform pattern of muscle fibres in the EDL and soleus muscle; this levelling-out of differences between enzymatic activities of different muscle fibres is not observed in the diaphragm muscle. Preferential atrophy and loss of ATPase activity in II muscle fibres in the soleus muscle and the occurrence of 'type grouping' are further characteristic features of senile muscle change. The findings show general (i.e. loss of enzyme activities) and differential trends of biochemical and histochemical enzyme changes in different types of muscles.     

Relation between growth rate and metabolic organization of white muscle,liver and digestive tract in cod,Gadus morhua

To determine whether the aerobic capacity of tissues required for growth specifically reflects growth rates, we monitored the activities of key enzymes of oxidative, glycolytic and amino acid metabolism in muscle, liver and intestine of Atlantic cod (Gadus morhua) growing at different rates. Fish were maintained individually in small tanks at 10°C and fed on rations that allowed growth rates ranging from-0.6 to 1.6% per day. The correlation between growth rate and muscle enzyme activity was pronounced for the glycolytic enzymes (LDH, PFK and PK). The activities of glycolytic enzymes were more than four times higher for fish having higher growth rates compared to those that did not grow. Mitochondrial enzyme (cytochrome c oxidase, citrate synthase and -hydroxyacyl-CoA dehydrogenase) activities remained unchanged in fish with positive growth. The liver seems to respond to requirements of growth by an increase in size. In the liver, the activities of the enzymes of amino acid metabolism expressed as units · g DNA^-1 specifically increases with growth rate. In contrast to the two other tissues, the specific activities of mitochondrial enzymes in the intestine increased with growth rate while the relative mass of the intestine remained constant. Intestinal cytochrome c oxidase activity increased from a minimum of about 2 to more than 8 units · g intestine^-1. Cytochrome c oxidase activity increased in parallel with the food conversion efficiency. This suggests that the aerobic capacity of the intestine may initially limit the rates of digestion and growth in this species.Abbreviations AA amino acid(s) - BM body mass - CCO cytochrome c oxydase - CS citrate synthase - DTNB 5,5 dithiobis-2-nitrobenzoic acid - GDH glutamate dehydrogenase - GOT glutamate oxalacetate transaminase - GPT glutamate pyruvate transaminase - GR growth rate(s) - HOAD -hydroxyacyl-CoA dehydrogenase - HSI hepatosomatic index - LDH lactate dehydrogenase - MR metabolic rate(s) - PCA perchloric acid - PFK phosphofructokinase - PK pyruvate kinase - PMSF phenylmethylsulphonyl fluoride; TRIS     

Respiration of Artemia franciscana embryos after continuous anoxia over 1-year period

Encysted embryos of the brine shrimp, Artemia franciscana, exhibit extraordinary longevity when exposed to continuous anoxia. To explore the metabolic basis of this ability, the post-anoxic respiration of embryos exposed to anoxia for periods exceeding 1 year was measured. Since anoxic metabolism might result in the accumulation of metabolic end products, an O₂ debt would be expected. Contrary to that expectation, post-anoxic embryos exhibited a marked depression in respiration rate whether embryos were hydrated under anoxic conditions or were exposed to a previous aerobic incubation and then placed under anoxia. These results, and those of previous studies, suggest that extended anoxia may bring the metabolism of these embryos to a reversible standstill.     

Phosphofructokinase from foot muscle of the whelk, Busycotypus canaliculatum: Evidence for covalent modification of the enzyme during anaerobiosis

Phosphofructokinase (PFK) was purified from foot muscle of aerobic and anaerobic (24 h of anoxia) whelks, Busycotypus canaliculatum. Fructose-6-P kinetics were sigmoidal at pH 7.0 with affinity constants, S_0.5, of 2.18 ± 0.10 (n_H = 2.5 ± 0.1) and 2.48 ± 0.13 mm (n_H = 2.7 ± 0.1) for the enzyme from aerobic versus anaerobic muscle. Affinity for ATP, like that for fructose-6-P, did not differ for the two enzymes (0.031 ± 0.003 for the aerobic vs 0.041 ± 0.007 mm for the anaerobic enzyme), but S_0.5 for Mg²⁺ was significantly different for the two enzymes (0.060 ± 0.006 vs 0.130 ± 0.020 mm). Whelk muscle PFK was activated by NH₄⁺, P_i, AMP, ADP, and fructose-2,6-P₂. NH₄⁺ and fructose-2,6-P₂ were less effective activators of PFK from anoxic muscle, with apparent K_a's 1.6- and 3.5-fold higher for the anaerobic vs aerobic enzyme. Activators decreased S_0.5 for fructose-6-P and reduced n_H. With the exception of fructose-2,6-P₂, the effects of activators on S_0.5 were the same for the enzyme from aerobic and anaerobic muscle; fructose-2,6-P₂ at 2.5 μm reduced S_0.5 by only 3.3-fold for the anaerobic enzyme compared to 5.5-fold for the aerobic enzyme. ATP was a strong substrate inhibitor of PFK; the enzyme from anaerobic muscle showed greater ATP inhibition, with I₅₀'s 1.5- to 2.0-fold lower than those for the aerobic enzyme. The kinetic differences between PFK from anaerobic versus aerobic foot muscle (stronger ATP inhibition and decreased sensitivity to activators for the anaerobic enzyme) were consistent with kinetic differences reported for the phosphorylated versus dephosphorylated forms, respectively, of PFK in other systems. Treatment of PFK from anaerobic muscle with alkaline phosphatase resulted in a decrease in the K_a for fructose-2,6-P₂ to a level similar to that of the aerobic enzyme. The physiological stress of anoxia may, therefore, induce a covalent modification of PFK.     

Swimming performance, metabolic rates, and their correlates in the Iceland scallop Chlamys islandica

The dramatic escape response of some scallops is modified by reproductive investment and by acclimation temperature. Despite considerable knowledge of the physiology of the escape response, functional links between escape response performance, organismal rates of oxygen uptake, and tissue metabolic capacities are little known. We measured oxygen consumption rates (standard, maximal, and aerobic scope), escape behavior (initial and repeat performance), tissue mass, condition index, protein content, and tissue metabolic capacities in the Iceland scallop Chlamys islandica to examine links between these parameters. Postexercise oxygen consumption rates were positively linked to contraction rate (repeat test) and to pyruvate kinase activity in the adductor muscle but negatively linked to digestive gland wet mass. Swimming behavior was mainly related to activity of glycolytic enzymes, and enzymatic activities were related to anatomic parameters. Scallop behavior and physiology change with size, both within our samples and on a larger scale. Small scallops showed more intense swimming activity and had higher arginine kinase activities but lower glycolytic enzyme activities in their adductor muscle than larger scallops. This corresponds to the ontogenetic change in susceptibility to predation and in habitat use observed in C. islandica.     

Experimental determination of control of glycolysis in Lactococcus lactis

The understanding of control of metabolic processes requires quantitative studies of the importance of the different enzymatic steps for the magnitude of metabolic fluxes and metabolite concentrations. An important element in such studies is the modulation of enzyme activities in small steps above and below the wild-type level. We review a genetic approach that is well suited for both Metabolic Optimization and Metabolic Control Analysis and studies on the importance of a number of glycolytic enzymes for metabolic fluxes in Lactococcus lactis. The glycolytic enzymes phosphofructokinase (PFK), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), pyruvate kinase (PYK) and lactate dehydrogenase (LDH) are shown to have no significant control on the glycolytic flux in exponentially growing cells of L. lactis MG1363. Introduction of an uncoupled ATPase activity results in uncoupling of glycolysis from biomass production. With MG1363 growing in defined medium supplemented with glucose, the ATP demanding processes do not have a significant control on the glycolytic flux; it appears that glycolysis is running at maximal rate. It is likely that the flux control is distributed over many enzymes in L. lactis, but it cannot yet be excluded that one of the remaining glycolytic steps is a rate-limiting step for the glycolytic flux.     

Effects of hibernation on mitochondrial regulation and metabolic capacities in myocardium of painted turtle (Chrysemys picta)

Painted turtles hibernating during winter may endure long-term exposure to low temperature and anoxia. These two conditions may affect the aerobic capacity of a tissue and might be of particular importance to the cardiac muscle normally highly reliant on aerobic energy production. The present study addressed how hibernation affects respiratory characteristics of mitochondria in situ and the metabolic pattern of turtle myocardium. Painted turtles were acclimated to control (25 degrees C), cold (5 degrees C) normoxic and cold anoxic conditions. In saponin-skinned myocardial fibres, cold acclimation increased mitochondrial respiratory capacity and decreased apparent ADP-affinity. Concomitant anoxia did not affect this. Creatine increased the apparent ADP-affinity to similar values in the three acclimation groups, suggesting a functional coupling of creatine kinase to mitochondrial respiration. As to the metabolic pattern, cold acclimation decreased glycolytic capacity in terms of pyruvate kinase activity and increased lactate dehydrogenase (LHD) activity. Concomitant anoxia counteracted the cold-induced decrease in pyruvate kinase activity and increased creatine kinase activity. In conclusion, cold acclimation seems to increase aerobic and decrease anaerobic energy production capacity in painted turtle myocardium. Importantly, anoxia does not affect the mitochondrial functional integrity but seems to increase the capacity for anaerobic energy production and energy buffering.     

Sugar and fructan accumulation during metabolic adjustment between respiration and fermentation under low oxygen conditions in wheat roots

In terms of gene expression and carbohydrate metabolism, the response of wheat seedlings to hypoxia is dramatically different from the anoxic response. Total carbohydrate content of roots increased 4-fold during 6 days of hypoxia, with a 17-fold increase in fructans. In contrast, anoxically treated roots depleted all soluble carbohydrates and died within 72 h. Gas exchange measurements (CO₂ release vs. O₂ uptake) demonstrate that hypoxia establishes a new balance between fermentation and aerobic respiration in the roots without altering the flux of carbon through glycolysis. Furthermore, the respiratory component of this new balance is 55% higher in roots that have been hypoxically pretreated compared to non-hypoxically pretreated roots. The establishment of this new homeostasis under hypoxia involves the induction of glycolytic (aldolase and enolase) and fermentative enzymes (pyruvate decarboxylase, alcohol dehydrogenase, and lactate dehydrogenase). Enzyme induction is generally complete within 24 h with mRNA induction occurring primarily during Period I (0–6 h of hypoxia), and maximal enzymes activities attained during Period II (6–24 h of hypoxia). Accumulation rates of Suc, hexoses, and fructans also change during Periods I and II. By the start of Period III (24–144 h of hypoxia), the metabolic adjustments are complete and fructans are the major carbohydrate accumulated. In anoxia, the pattern of enzyme induction was dramatically different: aldolase was not induced and declined throughout the treatment. Alcohol dehydrogenase, pyruvate decarboxylase, and lactate dehydrogenase were induced as in hypoxia, but rapidly declined within 72 h of anoxia. Only enolase exhibited a similar expression pattern in both anoxia and hypoxia.