Purification and characterization of glycogen phosphorylase A and B from the freeze-avoiding gall moth larvae Epiblema scudderiana

The active a and inactive b forms of glycogen phosphorylase from cold-hardy larvae of the gall moth, Epiblema scudderiana, were purified using DEAE⁺ ion exchange and 3-5-AMP-agarose affinity chromatography. Maximum activities for glycogen phosphorylases a and b were 6.3±0.74 and 2.7±0.87 mol glucose-1-P·min^-1·g wet weight^-1, respectively, in -4°C-acclimated larvae. Final specific activities of the purified enzymes were 396 and 82 units·mg protein^-1, respectively. Both enzymes were dimers with native molecular weights of 215000±18000 for glycogen phosphorylase a and 209000±15000 for glycogen phosphorylase b; the subunit molecular weight of both forms was 87000±2000. Both enzymes showed pH optima of 7.5 at 22°C and a break in the Arrhenius relationship with a two- to four-fold increase in activation energy below 10°C. Michaelis constant values for glycogen at 22°C were 0.12±0.004 mg·ml^-1 for glycogen phosphorylase a and 0.87±0.034 mg·ml^-1 for glycogen phosphorylase b; the Michaelis constant for inorganic phosphate was 6.5±0.07 mmol·l^-1 for glycogen phosphorylase a and 23.6 mmol·l^-1 for glycogen phosphorylase b. Glycogen phosphorylase b was activated by adenosine monophosphate with a K _a of 0.176±0.004 mmol·l^-1. Michaelis constant and K _a values decreased by two- to fivefold at 5°C compared with 22°C. Glycerol had a positive effect on the Michaelis constant for glycogen for glycogen phosphorylase a at intermediate concentrations (0.5 mol·l^-1) but was inhibitory to both enzyme forms at high concentrations (2 mol·l^-1). Glycerol production as a cryoprotectant in E. scudderiana larvae is facilitated by the low temperature-simulated glycogen phosphorylase b to glycogen phosphorylase a conversion and by positive effects of low temperature on the kinetic properties of glycogen phosphorylase a. Enzyme shut-down when polyol synthesis is complete appears to be aided by strong inhibitory effects of glycerol and KCl on glycogen phosphorylase b.Abbreviations E _a activation energy - GPa glycogen phosphorylase a - GPb glycogen phosphorylase b - h Hill coefficient - I ₅₀ concentration of inhibitor that reduces enzymes velocity by 50% - K _a concentration of activator that produces half-maximal activation of enzyme activity - K _m Michaelis-Menten substrate affinity constant - MW molecular weight - PEG polyethylene glycol - P_i morganic phosphate - SDS PAGE sodium dodecyl sulphate polyacrylamide gel electrophoresis - V _max enzyme maximal velocity     

Temporal changes in liver carbohydrate metabolism associated with seawater transfer in Oreochromis mossambicus

The metabolic aspects of ionic and osmotic regulation in fish are not well understood. The objective of this study was to examine changes in carbohydrate metabolism during seawater (SW) acclimation in the euryhaline tilapia (Oreochromis mossambicus). Hepatic activities of three key enzymes of the intermediary metabolism, phosphofructokinase, glycogen phosphorylase and glucose 6-phosphate dehydrogenase, together with glycogen content and plasma glucose concentration were measured at 0, 0.5, 1, 2, 3, 6, 12, 24, 48 and 96 h after the direct transfer of tilapia from fresh water (FW) to 70% SW. Plasma growth hormone, prolactin₁₇₇ and prolactin₁₈₈, Na⁺ and Cl⁻ concentrations were also measured. Plasma Na⁺ and Cl⁻ levels were highest at 12 h, but returned to FW levels at 24 h after transfer, suggesting the tilapia were able to osmoregulate within 24 h after transfer. Plasma glucose levels were significantly higher in 70% SW than in FW during the course of acclimation, especially in the early stages. Hepatic enzyme activities and glycogen content did not change significantly during the acclimation period. Our results suggest the possibility that glucose is an important energy source for osmoregulation during the acclimation to hyperosmotic environments in O. mossambicus.     

Hepatic glycogen metabolism in the db/db mouse

Summary Knowledge of the metabolic changes that occur in insulin-resistant type 2 diabetes is relatively lacking compared to insulin-deficient type 1 diabetes. This paper summarizes the importance of the C57BL/KsJ-db/db mouse as a model of type 2 diabetes, and illustrates the effects that insulin-deficient and insulin-resistant states have on hepatic glycogen metabolism. A longitudinal study of db/db mice of ages 2–15 weeks revealed that significant changes in certain parameters of hepatic glycogen metabolism occur during this period. The liver glycogen levels were similar between diabetic and control mice. However, glycogen particles from db/db mice were on average smaller in mass and had shorter exterior and interior chain lengths. Total phosphorylase and phosphorylase a activities were elevated in the genetically diabetic mice. This was primarily due to an increase in the amount of enzymic protein apparently the result of a decreased rate of degradation. It was not possible to find a consistent alteration in glycogen synthase activity in the db/db mice. Glycogen synthase and phosphorylase from diabetic liver revealed some changes in kinetic properties in the form of a decrease in V_max, and altered sensitivity to inhibitors like ATP. The altered glycogen structure in db/db mice may have contributed to changes in the activities and properties of glycogen synthase and phosphorylase. The exact role played by hormones (insulin and glucagon) in these changes is not clear but further studies should reveal their contributions. The db/db mouse provides a good model for type 2 diabetes and for fluctuating insulin and glucagon ratios. Its use should clarify the regulation of hepatic glycogen metabolism and other metabolic processes known to be controlled by these hormones. The other animal models of type 2 diabetes, ob/ob mouse and fatty Zucker (fa/fa) rat, show similar impairment of hepatic glycogen metabolism. The concentrations of glycogen metabolizing enzymes are high and in vitro studies indicate enhanced rate of glycogen synthesis and breakdown. However, streptozotocin-induced diabetic animals and BB rats which resemble insulin-deficient type 1 diabetes are characterized by decreased glycogen turnover as a result of reduction in the levels of glycogen metabolizing enzymes.     

Electrochemically applied potentials induce growth and metabolic shift changes in the hyperthermophilic bacterium Thermotoga maritima MSB8

Bioelectrochemical systems are an attractive technology for regulating microbial activity. The effect of an applied potential on hydrolysis of starch in Thermotoga maritima as a model bacterium was investigated in this study. A cathodic potential (?0.6 and ?0.8 V) induced 5-h earlier growth initiation of T. maritima with starch as the polymeric substrate than that without electrochemical regulation. Moreover, metabolic patterns of starch consumption were altered by the cathodic potential. While acetate, H², and CO₂ were the major products of starch consumption in the control experiment without electrolysis, lactate accumulation was detected rather than decreased acetate and H₂ levels in the bioelectrochemical system experiments with the cathodic potential. These results indicate that the applied potential could control microbial activities related to the hydrolysis of polymeric organic substances and shift carbon and electron flux to a lactate-producing reaction in T. maritima.     

Acetate Metabolism by an Obligate Phototrophic Strain of Pandorina morum1

SYNOPSIS. Acetate metabolism was studied in 2 strains of the green alga Pandorina morum. Both strains were capable of mixotrophic growth in the light, but only one strain was capable of heterotrophic growth in the dark. ¹⁴C-2-acetate uptake by both strains was studied in the light and dark, in the presence and absence of CO₂ and 3(3,4-dichlorophenyl)-1,1-dimethylurea (10^?5M). The distribution of radioactivity incorporated into the insoluble, aqueous and chloroform soluble fractions of the cells was determined. The strain incapable of heterotrophic growth in the dark was found to incorporate very little acetate in the dark, and its ability to incorporate acetate into the insoluble fraction was severely limited under all conditions. Incorporation into the aqueous and chloroform-soluble fractions in the light was similar in both strains. The reduced incorporation into the insoluble fraction was almost totally the result of limited incorporation of acetate into polysaccharides by the obligate phototrophic strain.     

ACETATE METABOLISM BY WHOLE CELLS OF PHAEODACTYLUM TRICORNUTUM BOHLIN12

Both morphological forms of Phaeodactylum tricornutum incorporated acetate in the light and in darkness. In the dark, the majority of the acetate was oxidized, probably by the tricarboxylic acid cycle. Although some CO₂ was formed from acetate in the light, most acetate carbon was found in the cellular lipids. Acetate incorporation in the light was probably a result of both direct and indirect assimilation. The organism grew poorly on acetate in the light at a very low CO₂ tension.     

Kinetics of polyglucose breakdown in Chlorobium

Washed cells of Chlorobium limicola f. thiosulfatophilum photoassimilate CO₂ and acetate into polyglucose, which is laid down within the cells as rosette-like granules. When the cells are incubated in the dark, the polyglucose is broken down. Experiments using electron microscopy and labelling with ¹⁴C-acetate have revealed that degradation of polyglucose occurs in such a way that all the granules are subject to degradation simultaneously and the polyglucose which has been formed most recently in the light, becomes metabolized in the dark first.     

Carbonic anhydrase is induced prior to arylsulfatase under the simultaneous deprivation of inorganic carbon and sulfate in Chlamydomonas reinhardtii (Volvocales, Chlorophyta)

The activity of periplasmic arylsulfatase (Ars), which catalyzes the cleavage of sulfate from aromatic sulfur compounds, was detected in cells acclimated to the sulfate-deficient conditions in a unicellular green alga Chlamydomonas reinhardtii Dangeard, but not in Chlorella, Scenedesmus, Dunaliella and Porphyridium. Upon the transfer of cells to sulfate-deficient autotrophic media under high-CO₂ conditions, the induction of Ars was observed only in the light, but not in the light with dichlorophenyldimethylurea (DCMU) nor in the dark. However, Ars was induced in the light with DCMU or in the dark when acetate was present as an organic carbon source, but not citrate. Under similar high-CO₂ conditions, high-CO₂ requiring mutants of cia-3 and cia-5, whose photosynthetic activities are greatly limited under low CO₂, showed much lower level of Ars activities than wild type cells. Under Iow-CO₂ conditions the induction of Ars was greatly suppressed even in wild type and no induction was observed in both mutants. These results suggest that the stimulation of photosynthetic or respiratory carbon metabolism are necessary for the induction of Ars. In contrast, the induction of periplasmic carbonic anhydrase (CA) which was synthesized de novo specifically under CO₂-limited conditions was strongly suppressed by the addition of organic carbon sources, such as acetate and citrate. When cells are subjected to CO₂-limitation and sulfate-deficiency simultaneously, the induction of CA was initiated immediately, while that of Ars was initiated following the completion of CA induction with an about 4-h lag. When the concentration of CO₂ was suddenly lowered during the induction of Ars, the induction of Ars ceased quickly, and the induction of CA was initiated instead. From these results the induction of CA was suggested to have priority over that of Ars under the dual stress of CO₂, and sulfate-deprivation.     

Involvement of NAD(P)+-glutamate dehydrogenase isoenzymes in carbon and nitrogen metabolism in Chlamydomonas reinhardtü

The involvement of three NAD(P)₊-L-glutamate dehydrogenase (GDH; EC 1.4.1.3) isoenzymes, named GDH₁, GDH₂ and GDH₃, in the carbon and nitrogen metabolism of the green alga Chlamydomonas reinhardtü 6145c has been investigated under different environmental and stress conditions. GDH₁ activity decreased, but GDH₂ and GDH₃ activities increased with the age of cultures. When the extracellular ammonium concentration was high, only GDH₁ activity increased with growth whereas GDH₂ and GDH₃ remained unchanged. In the presence of L-methionine-D,L-sulfoximine (MSX), an inhibitor of L-glutamine synthetase (GS), a significant increase of GDH₁ and a slight decrease in GDH₃ activity was observed, whereas GDH₂ did not change. A significant increase in the intracellular 2-oxoglutarate was also found upon addition of azaserine, an inhibitor of L-glutamate synthase (GOGAT) activity. However, no significant changes in GDH isoenzyme activities were observed after addition of azaserine or azaserine plus MSX, except an induction of GDH₃ in the latter case. Moreover, in the presence of ethoxyzolamide (ETZ), an inhibitor of carbonic anhydrase activity, an induction of total GDH activity, mainly due to an increase in GDH₁ and to a minor extent in GDH₂, was observed in cells under low CO₂ (0.03%). In the dark, cells showed an increase in GDH₁ activity, but when acetate was present GDH₁ activity was repressed. All these results taken together suggest a relationship between GDH₁ and nitrogen assimilation, whereas GDH₂ and GDH₃ seem to be involved in the production of 2-oxoglutarate to fuel the tricarboxylic acid (TCA) cycle.     

Effect of AMP and related compounds on glycogen content of Tetrahymena

Addition of AMP to cultures of Tetrahymena pyriformis caused an increase in glycogen content of the cells and a small inhibition of growth. Adenine, adenosine, ADP, and ATP also increased glycogen content. Inosine and GMP were less effective; cytidine and uridine were ineffective. The increase in glycogen content was also observed in cultures supplemented with ribose, fructose, or glycerol, and when glyconeogenesis was increased by partial anaerobiosis. Adenine itself did not serve as a glycogen precursor, nor could the lipids of the cell have been the source of the carbon for the increased glycogen. The specific activity of glycogen from cultures supplemented with labelled amino acids was lower in AMP-treated cells than in controls. AMP-treatment had little effect on ¹⁴CO₂ production from labelled glucose, acetate, or pyruvate, but baused a marked inhibition of the oxidation of labelled glyoxylate. It was suggested that AMP increases the rate of glyconeogenesis from precursors other than amino acids and interferes with malate synthase activity or malate transfer from peroxisomes to mitochondria.     

The incorporation of nitrogen into products of recent photosynthesis in Anabaena cylindrica Lemm.

In vivo tracer studies with ¹⁴C have been performed to help determine pathways of incorporation of newly assimilated nitrogen into N₂-fixing cells of Anabaena cylindrica. After photosynthesis in Ar:O₂:¹⁴CO₂ for 30 min, the addition of N₂ or NH ₄ ⁺ resulted in increased rates of ¹⁴CO₂-incorporation both in the light and dark, and in increased incorporation of ¹⁴C into amino acids at the expense of sucrose and sugar phosphates. Evidence of enhanced sucrose catabolism and increased pyruvate kinase activity was obtained on adding nitrogen, and, of the ¹⁴C-labelling entering the tricarboxylic acid cycle, more appeared in citrate and 2-oxoglutarate than in malate and oxaloacetate. The kinetics of ¹⁴C-incorporation into various amino acids suggest that in the light and dark the most important route of primary ammonia assimilation involves glutamine synthetase and that glutamate, aspartate, glycine and probably alanine are formed secondarily from glutamine.     

Explant culture of rat colon: A model system for studying metabolism of chemical carcinogens

Summary An explant culture system has been developed for the long-term maintenance of colonic tissue from the rat. Explants of 1 cm² in size were placed in tissue-culture dishes to which was added 2 ml of CMRL-1066 medium supplemented with glucose, hydrocortisone, β-retinyl acetate, and either 2.5% bovine albumin or 5% fetal bovine serum. The dishes were placed in a controlied-atmosphere chamber which was gassed with 95% O₂ and 5% CO₂. The chamber then was placed on a rocker platform which rocked at 10 cycles per min causing the medium to flow intermittently over the epithelial surface. The explants were incubated at 30°C. The viability of the tissue was measured both by incorporation of specific precursors into cellular macromolecules and by monitoring of tissue morphology with light and electron microscopy. Cultured rat colon was able to metabolize benzo[a]pyrene, 7,12-dimethylbenz[a]anthracene, aflatoxin B₁, dimethylnitrosamine, 1,2-dimethylhydrazine, and methylazoxymethanol acetate into chemical species that bind to cellular DNA and protein.     

Acetate formation from CO and CO2 by cell extracts of Peptostreptococcus productus (strain Marburg)

Cell extracts of Peptostreptococcus productus (strain Marburg) obtained from CO grown cells mediated the synthesis of acetate from CO plus CO₂ at rates of 50 nmol/min × mg of cell protein. ¹⁴CO was specifically incorporated into C₁ of acetate. No label exchange occurred between ¹⁴C₁ of acetyl-CoA and CO, indicating that ¹⁴CO incorporation into acetate was by net synthesis rather than by an exchange reaction. In acetate synthesis from CO plus CO₂ the latter substrate could be replaced to some extent by formate or methyl tetrahydrofolate as the methyl donor. The methyl group of methyl cobalamin was incorporated into acetate ony at very low activities. The cell extracts contained high levels of enzyme activities involved in acetate or cell carbon synthesis from CO₂. The following enzymic activities were detected: CO: methyl viologen oxidoreductase, formate dehydrogenase, formyl tetrahydrofolate synthetase, methenyl tetrahydrofolate cyclohydrolase, methylene tetrahydrofolate dehydrogenase, methylene tetrahydrofolate reductase, phosphate acetyltransferase, acetate kinase, hydrogenase, NADPH: benzyl viologen oxidoreductase, and pyruvate synthase. Some kinetic and other properties were studied.     

Carbon Metabolism Transitions during the Development of Marine Macroalga Gracilaria verrucosa

The changes in the rate of photosynthetic and dark CO₂ assimilation and the activity of key enzymes of carboxylation were studied during the main developmental stages (shoots, juvenile plants, and mature plants) of red macroalga Gracilaria verrucosa (Huds.) Papenf. Changes in the direction of primary carbon metabolism were also investigated. It was estimated that the transition of metabolism related to the shift in the pathways of carboxylation did not occur during development of G. verrucosa. During all developmental stages, the level of dark CO₂ assimilation was by at least one order of magnitude lower than that of photosynthetic assimilation The predominant pathway of CO₂ assimilation was ribulosobisphosphate carboxylation. At the same time, the transition of metabolism related to the changes in the type of phosphoglyceric acid utilization was found. At the early developmental stages, a substantial part of phosphoglyceric acid was directed into the amino acid metabolism via the anaplerotic pathway of photosynthesis similar to that in higher plants.     

Investigation of the dark metabolism of acetate in photoheterotrophically grown cells ofRhodospirillum rubrum

The mechanism of the aerobic dark assimilation of acetate in the photoheterotrophically grown purple nonsulfur bacteriumRhodospirillum rubrum was studied. Both in the light and in the dark, acetate assimilation inRsp. rubrum cells, which lack the glyoxylate pathway, was accompanied by the excretion of glyoxylate into the growth medium. The assimilation of propionate was accompanied by the excretion of pyruvate. Acetate assimilation was found to be stimulated by bicarbonate, pyruvate, the C₄-dicarboxylic acids of the Krebs cycle, and glyoxylate, but not by propionate. These data implied that the citramalate (CM) cycle inRsp. rubrum cells can function as an anaplerotic pathway under aerobic dark conditions. This supposition was confirmed by respiration measurements. The respiration of cells oxidizing acetate depended on the presence of CO₂ in the medium. The fact that the intermediates of the CM cycle (citramalate and mesaconate) markedly inhibited acetate assimilation but had almost no effect on cell respiration indicated that citramalate and mesaconate were intermediates of the acetate assimilation pathway. The inhibition of acetate assimilation and cell respiration by itaconate was due to its inhibitory effect on propionyl-CoA carboxylase, an enzyme of the CM cycle. The addition of 5 mM itaconate to extracts ofRsp. rubrum cells inhibited the activity of this enzyme by 85%. The data obtained suggest that the CM cycle continues to function inRsp. rubrum cells that have been grown anaerobically in the light and then transferred to the dark and incubated aerobically.     

The effects of insulin on myocardial metabolism and acidosis in normoxia and ischaemia: A 31P-NMR study

1. The effect of insulin on the perfused rat heart during normoxia and total ischaemia was studied by ³¹P-NMR. 2. During normoxic perfusion, insulin increased the phosphocreatine to ATP ratio at the expense of P_i, when glucose was the substrate. No change was observed when acetate was used as the sole substrate. The intracellular pH (as measured from the position of the 2-deoxyglucose 6-phosphate resonance peak) was unaffected by insulin treatment. 3. Infusion of insulin prior to ischaemia caused an increase in the rate and extent of acidosis during the period of no flow while the rate of ATP depletion was decreased. 4. Freezeclamped studies showed an increase in glycogen levels upon insulin treatment of the glucose perfused rat heart. During ischaemia, a decrease in glycogen content concomitant with an increase in lactate was observed. The accessibility of glycogen to phosphorylase during ischaemia is increased as a result of insulin treatment. The control of glycolysis during ischaemia is discussed with respect to the content and structure of glycogen in heart tissue.     

Cellular physiology controls photoautotrophic production of 1,2-propanediol from pools of CO2 and glycogen

Synechocystis sp. PCC 6803 PG is a cyanobacterial strain capable of synthesizing 1,2-propanediol from carbon dioxide (CO₂) via a heterologous three-step pathway and a methylglyoxal synthase (MGS) originating from Escherichia coli as an initial enzyme. The production window is restricted to the late growth and stationary phase and is apparently coupled to glycogen turnover. To understand the underlying principle of the carbon partitioning between the Calvin-Benson-Bassham (CBB) cycle and glycogen in the context of 1,2-propanediol production, experiments utilizing ¹³C labeled CO₂ have been conducted. Carbon fluxes and partitioning between biomass, storage compounds, and product have been monitored under permanent illumination as well as under dark conditions. About one-quarter of the carbon incorporated into 1,2-propanediol originated from glycogen, while the rest was derived from CO₂ fixed in the CBB cycle during product formation. Furthermore, 1,2-propanediol synthesis was depending on the availability of photosynthetic active radiation and glycogen catabolism. We postulate that the regulation of the MGS from E. coli conflicts with the heterologous reactions leading to 1,2-propanediol in Synechocystis sp. PCC 6803 PG. Additionally, homology comparison of the genomic sequence to genes encoding for the methylglyoxal bypass in E. coli suggested the existence of such a pathway also in Synechocystis sp. PCC 6803. These findings are critical for all heterologous pathways coupled to the CBB cycle intermediate dihydroxyacetone phosphate via a MGS and reveal possible engineering targets for rational strain optimization.     

Respiration accumulates Calvin cycle intermediates for the rapid start of photosynthesis in Synechocystis sp. PCC 6803

We tested the hypothesis that inducing photosynthesis in cyanobacteria requires respiration. A mutant deficient in glycogen phosphorylase (?GlgP) was prepared in Synechocystis sp. PCC 6803 to suppress respiration. The accumulated glycogen in ΔGlgP was 250–450% of that accumulated in wild type (WT). The rate of dark respiration in ΔGlgP was 25% of that in WT. In the dark, P700⁺ reduction was suppressed in ΔGlgP, and the rate corresponded to that in (2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone)-treated WT, supporting a lower respiration rate in ?GlgP. Photosynthetic O₂-evolution rate reached a steady-state value much slower in ?GlgP than in WT. This retardation was solved by addition of d-glucose. Furthermore, we found that the contents of Calvin cycle intermediates in ?GlgP were lower than those in WT under dark conditions. These observations indicated that respiration provided the carbon source for regeneration of ribulose 1,5-bisphosphate in order to drive the rapid start of photosynthesis.     

Pod photosynthesis and seed dark CO2 fixation support oil synthesis in developingBrassica seeds

Rate of photosynthesis and activities of photosynthetic carbon reduction cycle enzymes were determined in pods (siliqua), whereas rate of dark CO₂ fixation, oil content and activities of enzymes involved in dark CO₂ metabolism were measured in seeds ofBrassica campestris L. cv. Toria at different stages of pod/seed development. The period between 14 and 35 days after anthesis corresponded to active phase of seed development during which period, seed dry weight and oil content increased sharply. Rate of pod photosynthesis and activities of photosynthetic carbon reduction cycle enzymes were maximum in younger pods but sufficiently high levels were retained up to 40 days after anthesis. The rate of dark¹⁴CO₂ fixation in seeds increased up to 21 days after anthesis and declined thereafter but maintaining sufficiently high rates till 35 days after anthesis. Similarly various enzymes viz., phosphoenolpyruvate carboxylase, NAD⁺-malate dehydrogenase and NADP⁺-malic enzyme, involved in dark CO₂ metabolism retained sufficient activities during the above period. These enzyme activities were more than adequate to maintain the desired supply of malate which mainly arises from dark CO₂ fixation in seeds and further translocated to leucoplasts for onward synthesis of fatty acids. Enzyme localization experiments revealed phosphoenolpyruvate carboxylase and enzymes of sucrose metabolism to be present only in cytosol, whereas enzymes of glycolysis were present both in cytosolic and leucoplastic fractions. These results indicated that oil synthesis in developingBrassica seeds is supported by pod photosynthesis and dark CO₂ fixation in seeds as the former serves as the source of sucrose and the latter as a source of malate