Identification of a glycoprotein complex containing a glycogen synthase isozyme in Ascaris Suum obliquely-striated muscle

• 1.1. A glycogen/protein complex which contains the major portion of glycogen synthase activity in Ascaris suum muscle has been purified.
• 2.2. The complex contains two proteins which can be dissociated from a glycoprotein component.
• 3.3. The glycoprotein contains glycogen-like domains and is resistant to trypsin digestion.
• 4.4. The glycogen synthase activity in the purified complex catalyzes glycogen synthesis in the absence of exogenous glycogen, but demonstrates an absolute glucose 6-phosphate requirement for activity.
• 5.5. The data support the hypothesis that this isozyme of glycogen synthase is significantly different from the cyclic AMP-regulated enzyme.

     

A novel inhibitor of glycogen phosphorylase from crayfish hepatopancreas

• 1.1. A novel glycogen phosphorylase inhibitor was partially purified from crayfish hepatopancreas.
• 2.2. The inhibitor was found only in two species of crayfish examined, and not in lobster, fresh and salt water clams, mussels or cockroaches.
• 3.3. The inhibitor is a small protein (M_r = 23,000) which did not show proteolytic activity.
• 4.4. Preliminary kinetic analysis of the inhibitory mechanism indicated that it bound to both glycogen and the glycogen phosphorylase protein.
• 5.5. Inhibitor binding to glycogen resulted in a competitive inhibition pattern with respect to glycogen phosphorylase (inhibition constant of ca 10 μg/ml).
• 6.6. The inhibitor also bound glycogen phosphorylase directly with a binding coefficient of 100 μg/ml resulting in a partially non-competitive inhibition pattern with respect to phosphate.

     

Studies on glycogenolysis in carp liver: Evidence for an amylase pathway for glycogen breakdown

• 1.1. Glycogen-phosphorylase seems to be lacking in the carp liver. This enzymatic defect bears a resemblance to glycogen storage disease type VI, described in humans.
• 2.2. Carp liver homogenates exhibit an important γ-amylase (α-glucosidase, EC 3213) activity. By its pH curve and distribution in subcellular fractions of liver, this enzyme could be, to a large extent, of lysosomal origin.
• 3.3. During the strong hepatic glycogenolysis, which is induced in carp by insulin injections, the γ-amylase pathway could offer an explanation for glycogen breakdown in a tissue where glycogen phosphorylase is supposed to be absent.

     

Carbohydrate metabolism in several tissues of rainbow trout,Oncorhynchus mykiss,is modified during ovarian recrudescence

• 1.1. Several pathways of carbohydrate metabolism were evaluated in three different tissues—liver, gonad and kidney—of a hatchery-reared population of rainbow trout (Oncorhynchus mykiss) which characterised two different stages of their gonadal maturation, i.e. previtellogenesis and established exogenous vitellogenesis.
• 2.2. A fall in liver glycogen levels was observed during exogenous vitellogenesis. A decrease in activity of the enzymes involved in glycolysis and in the pentose phosphate shunt was also observed, suggesting that at the end of exogenous vitellogenesis the necessity of energy and reducing power has decreased compared to the situation at the onset of this period.
• 3.3. The main changes observed in gonad during vitellogenesis were the decreased activity of glycolysis and the pentose phosphate shunt as well as increased glycogen levels. The stored glycogen should be used later in association with the embryo development.
• 4.4. No major changes were observed in kidney metabolism throughout the vitellogenic process.
• 5.5. Exogenous vitellogenesis in rainbow trout is mainly associated with increased glycogen levels in the gonad and decreased metabolic activity in the liver.

     

The glycogen content in stressed marine bivalves: The initial absence of a decrease

• 1.1. Changes in the glycogen content, condition, stomach content and acetic acid concentration of mussels Mytilus edulis and cockles Cerastoderma edule were followed during periods of up to 14 days of exposure (to air) at temperatures of 5 and 20°C.
• 2.2. In animals with a high glycogen content the glycogen is not used during the first 3 to 7 days, at high and low temperature respectively.
• 3.3. After this latent period the glycogen concentration often decreased, coinciding with a high mortality and an increase of the concentration of acetic acid.
• 4.4. In cockles with a low glycogen content, and kept at a high temperature, glycogen can be used from the beginning of the stress period.
• 5.5. Between species no clear differences were found.
• 6.6. The stomach content decreased during exposure; however, the stomach content amounted to only 0.5 to 0.7% of the body weight, and is thought to be of minor importance as an energy source during the stress period.
• 7.7. Especially at the higher temperatures glycogen finally is transformed into acetic acid.
• 8.8. It is concluded that during exposure, the animals do not die because of a lack of energy reserves, but because of a high accumulation of acids.

     

The effect of hypoxia on carbohydrate metabolism in flounder (Platichthys flesus L.)—I. Utilization of glycogen and accumulation of glycolytic end products in various tissues

• 1.1. Resting oxygen consumption at 10°C did not change from normoxia (150 mm Hg) down to an oxygen tension of 55 mm Hg for the flounder, Platichtys flesus.
• 2.2. Flounders exposed to hypoxia showed increased levels of blood glucose and lactate, dependent on the degree of hypoxia.
• 3.3. Due to hypoxia glycogen was depleted in the liver and swimming muscle but in the heart there was no significant change.
• 4.4. Liver glucose increased after 7 hr of hypoxia. Heart and muscle glucose did not change but the absolute glucose concentration in the heart was five times higher than in the muscle.
• 5.5. There is a transient accumulation of lactate in heart, liver and kidney after 7 hr of hypoxia while lactate accumulation in the swimming muscle is significant only after 21 hr of hypoxia.
• 6.6. Succinate only accumulated in the liver while alanine accumulated in muscle, heart and liver.

     

NAD(P)H dehydrogenase from rabbit and rat liver: Purification and some properties

• 1.1. NAD(P)H dehydrogenase from rabbit liver was purified to electrophoretic homogeneity using a procedure also found applicable for the rat liver enzyme.
• 2.2. Rabbit and rat liver enzymes showed different behaviour in isoelectric focusing and different K_m values and turnover numbers.
• 3.3. Both enzymes were inhibited to similar extents by warfarin.
• 4.4. The rabbit enzyme is composed of two subunits of mol. wt 27,000 and contained 1 FAD group per subunit.
• 5.5. Some absorption and circular dichroism properties of the rat enzyme are shown.

     

IDentification of a microsomal retinoic acid synthase as a microsomal cytochrome P-450-linked monooxygenase system

• 1.1. To characterize an enzyme which metabolizes retinal in liver microsomes, several properties of the enzymatic reaction from retinal to retinoic acid were investigated using rabbit liver microsomes.
• 2.2. The maximum pH of the reaction in the liver microsomes was 7.6.
• 3.3. The K_m and V_max values for all-trans, 9-cis and 13-cis-retinals were determined.
• 4.4. The reaction proceeded in the presence of NADPH and molecular oxygen.
• 5.5. The incorporation of one atom of molecular oxygen into retinal was confirmed by using oxygen-18, showing that the reaction comprised monooxygenation, not dehydrogenation.
• 6.6. The monooxygenase activity was inhibited by carbon monoxide, phenylisocyanide and antiNADPH-cytochrome P-450 reductase IgG, but not by anti-cytochrome b₅ IgG.
• 7.7. The enzymatic activity inhibited by carbon monoxide was photoreversibly restored by light of a wavelength of around 450 nm.
• 8.8. The retinal-induced spectra of liver microsomes with three isomeric retinals were type I spectra.
• 9.9. The microsomal monooxygenase activity induced by phenobarbital or ethanol were more effective than that by 3-methylcholanthrene, clotrimazole or β-naphthoflavone.
• 10.10. These results showed that the monooxygenase reaction from retinal to retinoic acid in liver microsomes is catalyzed by a cytochrome P-450-linked monooxygenase system.

     

Seasonal effects of prolactin on aspects of carbohydrate and lipid metabolism in the goldfish,Carassius auratus

• 1.1. Diurnal and seasonal variations of certain aspects of carbohydrate and lipid metabolism to ovine prolactin (PRL) treatment in the goldfish, Carassius auratus, were examined.
• 2.2. PRL treatment late in the light phase of a long photoperiod during spring depletes liver glycogen stores. During fall liver glycogen levels are not affected by PRL treatment in fishes acclimated to long or short photoperiods. PRL is hypoglycaemic in fall and spring.
• 3.3. PRL administered late in the light phase of a long photoperiod during spring increases plasma and liver total lipids and plasma cholesterol, while decreasing plasma triglycerides. In fall PRL may increase or decrease plasma organic-bound P levels dependent upon injection time.

     

Human GMP synthetase

• 1.1. The specific activity of GMP synthetase was measured in several human tissues and found to be highest in cultured skin fibroblasts, followed by bone marrow, leukocytes, erythrocytes. placenta, and liver.
• 2.2. The enzyme from fibroblasts was purified approximately 50-fold by ammonium sulfate fractionation and gel filtration.
• 3.3. The K_m values were determined to be 4.9μM for XMP, 270μM for ATP. and 340 μM for glutamine.
• 4.4. Ammonium sulfate could replace glutamine as the amino donor but was much less efficient.
• 5.5. The enzyme was specific for ATP as the energy source.
• 6.6. Unlike the calf thymus enzyme, the human enzyme has no requirement for a reduced sulfhydryl compound.
• 7.7. Human GMP synthetase is inhibited by ATP, dATP, azaserine, and hydroxylamine.

     

Effects of the nonsteroidal anti-inflammatory drug piroxicam on energy metabolism in the perfused rat liver

• 1.1. The actions of piroxicam, a nonsteroidal and noncarboxylic anti-inflammatory drug, on the metabolism of the isolated perfused rat liver were investigated. The main purpose was to verify if piroxicam is also active on glycogenolysis and energy metabolism, as demonstrated for several carboxylic nonsteroidal anti-inflammatories.
• 2.2. Piroxicam increased oxygen consumption in livers from both fed and fasted rats.
• 3.3. Piroxicam increased glucose release and glycolysis from endogenous glycogen (glycogenolysis).
• 4.4. Gluconeogenesis from lactate plus pyruvate was inhibited.
• 5.5. The action of piroxicam on oxygen consumption was blocked by antimycin A, but not by atractyloside.
• 6.6. The action of piroxicam in the perfused rat liver metabolism seems to be a consequence of its action on mitochondria.
• 7.7. It can be concluded that inhibition of energy metabolism and stimulation of glycogenolysis are not specific properties of carboxylic nonsteroidal anti-inflammatory drugs.

     

Prenatal induction of tyrosine aminotransferase in rat liver

• 1.1. Hepatic tyrosine aminotransferase activity from adult rat can be resolved into four components on hydroxylapatite column.
• 2.2. A similar profile of enzyme distribution can be obtained from late foetal liver.
• 3.3. Insulin administration to pregnant rats result in induction of two isoenzymes of tyrosine aminotransferase in foetal rat liver. Similarly Cyclic AMP injection to foetal rats in utero results in the induction of the same two forms of the enzyme.
• 4.4. Triaminolone injection to foetal rats in utero leads to the induction of three of the isoenzymes of tyrosine aminotransferase.

     

Studies on tryptophan pyrrolase of Schistocerca gregaria försk. (Orthoptera)

• 1.The trytophan pyrrolase activity of central fat bodies of S. gregoria hoppera was studied.
• 2.The enzyme system appears to be similar to that of mammalian liver.
• 3.The enzyme was localized only in central fat bodies.
• 4.Extracts of other body parts can mimic an enzyme activity because of a degradation of ommochromes in the enzyme test.

     

Influence of handling and/or anaesthesia on stress response in rainbow trout. Effects on liver primary metabolism

• 1.1. The overall effect of handling, anaesthesia and sham injection on some blood metabolites, liver glycogen and several key enzymes involved in liver carbohydrates and nitrogen metabolism was studied in rainbow trout. In addition, the possible role of anaesthesia (MS222) itself as a stress-inductor or suppressor was also studied.
• 2.2. Stress resulted in hyperglycaemia and initially in liver glycogen depletion, as well as increasing plasma amino acid levels.
• 3.3. Glycogen stores subsequently recovered while amino acid concentration fell.
• 4.4. These changes seemed to correlate with the increased activity of liver fructose 1,6-bisphosphatase, glucose 6-phosphate dehydrogenase, alanine aminotransferase and glutamate dehydrogenase, thus supporting the hypothesis that gluconeogenic flux from amino acids increases in stressed trouts.
• 5.5. Anaesthesia, under the same experimental conditions, did not seem to mediate in stress production, but rather resulted in stress suppression.

     

Liver glycogen mobilization by Trypanosoma brucei sonicates

• 1.1. The African trypanosome, T. brucei, appears to possess a hormone-like substance capable of stimulating the production of glucose from glycogen.
• 2.2. The effect of this substance is primarily on the liver as demonstrated in vitro.
• 3.3. The effect is consistent and independent of host conditions provoking an immune response.
• 4.4. The data are discussed with respect to the endocrinological aspects of the host and its corresponding involvement.

     

DNase-I-like enzyme from the carp liver—Inhibition by muscle and endogenous actin

• 1.1. DNase-I-like activity occurs in the carp (Cyprinus carpio) liver cytosol (supernatant 105,000g).
• 2.2. The enzyme resembles DNase I from bovine pancreas in respect to the molecular mass (~31 kDa), pH (7.4) and ion requirements (Mg²⁺, Ca²⁺) and the ability to degrade native as well as denatured DNA.
• 3.3. As judged by comparison of DNase zymograms obtained after native- and SDS-PAGE, the enzyme occurs in the three molecular forms of similar molecular weight and different charges.
• 4.4. All these forms are inhibited by rabbit skeletal muscle actin as well as by endogenous actin isolated from the carp liver cytosol.
• 5.5. DNase from the carp liver cytosol does not interact with the antibodies directed against DNase I from bovine pancreas and against DNase I from the rat and bovine parotid glands.

     

Involvement of lysine residue in the nucleotide binding of pigeon liver malic enzyme: modification with affinity label periodate-oxidized nadp

• 1.1. Periodate-oxidized NADP, a competitive inhibitor of malic enzyme with respect to NADP. inactivate the enzyme in mild conditions.
• 2.2. The inactivation is due to the modification of an essential lysine residue.
• 3.3. Two molecules of reagent were found to be incorporated into the enzyme tetramer after extensive modification.
• 4.4. Complete protection of malic enzyme from the oxidized NADP inactivation was afforded by NADP and its analogues.
• 5.5. The modified enzyme showed increased apparent Michaelis constant for the nucleotide coenzymes but the maximum velocity was decreased.
• 6.6. The binding between the modified enzyme and NADPH was impaired.

     

Gender-related differences of mouse liver d-aspartate oxidase in the activity and response to administration of d-aspartate and peroxisome proliferators

• 1.1. The hepatic d-aspartate oxidase activity was found to be higher in female ddY and ICR mice than in their male counterparts. On the contrary, the free d-aspartate content in the liver was lower in female mice than in male mice, suggesting that d-aspartate is actually metabolized by d-aspartate oxidase in vivo.
• 2.2. Oral administration of d-aspartate to the animals increased the hepatic d-aspartate oxidase activity 2–3 fold in both genders without any significant difference in the rate of the increase between the genders.
• 3.3. Several peroxisomal enzyme activities other than d-aspartate oxidase examined were not affected by this treatment.
• 4.4. Experiments in vitro suggested that the increase in the d-aspartate activity might be explained in part by stabilization of the enzyme by d-aspartate.
• 5.5. The administration of clofibrate, a peroxisome proliferator, to male mice, increased the hepatic d-aspartate oxidase activity with a significant simultaneous decrease of d-aspartate content in the liver, in agreement with a possible role of the enzyme n vivo.
• 6.6. On the other hand, the administration of clofibrate or dehydroepiandrosterone to female mice decreased the d-aspartate oxidase activity.
• 7.7. The peroxisome proliferators were suggested to act to eliminate the gender difference of hepatic d-aspartate oxidase activity in mice.

     

The influence of environmental and incubation temperature on fatty acid synthetase from flounder (Platichthys flesus L.) liver

• 1.1. Fatty acid synthetase from liver of cold and warm adapted flounder and rabbit was purified to homogenity and compared.
• 2.2. The mol. wt of the cold and warm flounder enzyme was estimated to be about 457,000.
• 3.3. The kinetic properties were found to be similar for warm and cold adapted flounder liver enzyme and not different from the rabbit liver enzyme when measured at 5, 10, 15, 20 and 37°C.
• 4.4. Palmitic acid was the main product of both the flounder and rabbit enzyme, but significant amounts of butyric acid were also synthesized. The product composition did not change for any of the enzymes tested when the incubation temperature was changed.
• 5.5. It was concluded that fatty acid synthetase from flounder liver is similar to mammalian fatty acid synthetase with regard to molecular weight and kinetic properties.

     

A study of glycerolphosphate acyltransferase in rat liver mitochondria-submitochondrial localization and some properties of the solubilized enzyme

• 1.1. Glycerolphosphate acyltransferase (GPAT) was solubilized from the rat liver mitochondrial membranes using sodium cholate. Dithiothreitol was necessary to stabilize the solubilized enzyme on storage.
• 2.2. Unlike the enzyme in situ in mitochondrial membranes, the solubilized mitochondrial GPAT was susceptible to inhibition by N-ethylmaleimide; a property more characteristic of the distinct microsomal form of GPAT.
• 3.3. Solubilized mitochondrial GPAT retained its very high preference for saturated acyl-CoA substrate (palmitoyl-CoA) and had no activity whatever with any tested concentration of the unsaturated substrate oleoyl-CoA.
• 4.4. Solubilization increased the affinity of mitochondrial GPAT for palmitoyl-CoA whilst decreasing the K_m for glycerol phosphate.
• 5.5. After separation of liver mitochondrial outer and inner membranes and estimation of cross-contamination by appropriate markers it was concluded that the mitochondrial inner membrane contains significant GPAT activity. This was established with preparations from fed, 48 hr-starved and streptozotocin-diabetic rats.