Rat liver glycogen metabolism in the perinatal period

The correlation between blood glucose levels, the concentration of glycogen, the activities of glycogen sythase and phosphorylase and their respective kinases and phosphatases was examined in liver of rat fetuses between day 18 of gestation and one day after birth. Between day 18 and 21 there is a rapid increase in the concentration of glycogen and in the activity of synthase a and a much slower increase in the activity of phosphorylase a. The activity of the respective kinases increased rapidly during this period and reached maximun on day 21. The activity of synthase phosphatase and phosphorylase phosphatase increased after day 18, to reach a maximum on day 19 and 20, respectively, but decreased again towards day 21. The possibility that the changes in glycogen concentration and enzyme activities were related to an effect of glucose of AMP on the respective phosphatases was considered. It was found that the Km of phosphatase for glucose in the prenatal period was 5–7 mM, as in the adult. Since the level of blood glucose during this period was constant (2.8 mM), an effect of glucose on phosphatase activity seems unlikely. AMP concentration increased between day 18 and 21 from 6–15 nmol/g. In view of the low level of phosphorylase a activity during this period, the increase in AMP concentration is not considered to be important in the regulation of glycogen breakdown at this time.Immediately after birth blood glucose levels dropped to 5 mg/dl. This was accompanied by a rapid decrease in glycogen concentration and in the activity of glycogen synthase and a rise in phosphorylase activity. Blood glucose levels returned to the initial level within 1 h after birth, whereas the changes in glycogen concentration and enzyme activities continued for at least 3 h after birth. On day 22 all parameters examined had reached the level found in adult rat liver.It is suggested that the rapid changes observed immediately after birth are due to an effect of hypoglycemia mediated by hormones and cannot be ascribed to direct effects of metabolites on the enzyme systems involved.     

Transport and metabolism of pyridoxine in rat liver

Evidence, obtained with in situ perfused rat liver, indicated that pyridoxine is taken up from the perfusate by a non-concentrative process, followed by metabolic trapping. These conclusions were reached on the basis of the fact that at low concentrations (0.125 μM), the ³H of [³H]pyridoxine accumulated against a concentration gradient, but high concentrations (333 μM) of pyridoxine or 4-deoxypyridoxine prevented this apparent concentrative uptake. Under no conditions did the tissue water : perfusate concentration ratio of [³H]pyridoxine exceed unity.The perfused liver rapidly converted the labeled pyridoxine to pyridoxine phosphate, pyridoxal phosphate and pyridoxamine phosphate and released a substantial amount of pyridoxal and some pyridoxal phosphate into the perfusate. Since muscle and erythrocytes failed to oxidize pyridoxine phosphate to pyridoxal phosphate, it is suggested that the liver plays a major role in oxidizing dietary pyridoxine and pyridoxamine as their phosphate esters to supply pyridoxal phosphate which then reaches to other organs chiefly as circulating pyridoxal.     

Different effects of glucagon and epinephrine on the kinetic properties of liver glycogen synthase

Kinetic constants of glycogen synthase (M0.5 for glucose-6-P and S0.5 for UDP-glucose) were determined after hepatocytes isolated from starved rats were incubated with either glucagon or epinephrine. Incubation with these hormones resulted in an increase in both S0.5 and M0.5. However, the action of glucagon resulted in great modifications on S0.5 whereas epinephrine affected mainly M0.5. Therefore, glucagon and epinephrine alter the kinetic properties of glycogen synthase provoke the phosphorylation of glycogen synthase at different site(s) acting through different mechanisms.     

Glycogen synthase from human and bovine polymorphonuclear leukocyte Immunochemical characterization and comparison to glycogen synthase from rat and rabbit muscle and liver cells

Glycogen synthase from human and bovine polymorphonuclear leukocytes was purified to homogeneity. Rabbit antisera were raised against the two glycogen synthases and used for immunochemical analysis. Western blotting analysis showed that the subunit of glycogen synthase in crude homogenates of human and bovine leukocytes in both cases has an M_r of 85 000. The existence of a cross-reactivity between the two enzymes and the corresponding antisera demonstrates immunological similarities between bovine and human leukocyte glycogen synthase. In addition, both antisera recognize glycogen synthase in crude cellular extracts from rabbit and rat liver and from skeletal muscle. Leukocyte glycogen synthase, therefore, cannot be classified as either muscle (M-type) or liver (L-type) glycogen synthase and our results do not support the proposed immunochemical distinction between M- and L-type glycogen synthase.     

Glycogen accumulation in the parathyroid gland of the rat after fluoride ingestion

Summary The parathyroid glands of young male rats given 150 ppm fluoride in their drinking water for 10 weeks were examined by transmission electron microscopy. As a result of fluoride ingestion, the parathyroid chief cells of the experimental animals accumulated glycogen in excess of that seen in control animals given distilled drinking water for the same time period. In the majority of active chief cells, glycogen granules were diffusely spread throughout the cytoplasm as single granules or in small deposits. Large aggregations of glycogen granules were also seen within intercellular spaces. Accompanying the increase in glycogen was a rise in the number and development of the organelles associated with protein synthesis and secretion. The accumulation of glycogen is similar to that in hyperparathyroidism caused by chronic stimulation and prolonged secretory activity of the parathyroid gland. The results of this study suggest that increased amounts of glycogen occur in hyperactive chief cells of the parathyroid in response to the ingestion of large doses of fluoride.     

Side-chain metabolism of propranolol: involvement of monoamine oxidase and mitochondrial aldehyde dehydrogenase in the metabolism of N-desisopropylpropranolol to naphthoxylactic acid in rat liver

We examined the metabolism of N-desisopropylpropranolol (NDP), which is generated from propranolol (PL) by side-chain N-desisopropylation, to naphthoxylactic acid (NLA) in rat liver. S(-)-NDP (S-NDP) and R(+)-NDP (R-NDP) were enantioselectively metabolized to NLA in isolated rat hepatocytes and in an enzyme reaction system of rat liver mitochondria with cofactor NAD+. Furthermore, the clearance profiles of NDP enantiomers were examined in an enzyme reaction system of rat liver mitochondria without NAD+. The amounts of S-NDP remaining in the incubation medium were similar to those of R-NDP, suggesting that monoamine oxidase (MAO) catalyzes the deamination of NDP to the aldehyde intermediate, but fails to deaminate enantioselectively S-NDP or R-NDP. Cyanamide, a potent inhibitor of aldehyde dehydrogenase (ALDH), markedly decreased the formation of NLA from racemic NDP in the enzyme reaction system of rat liver mitochondria with NAD+. When rat liver cytosol and microsomes were added to this enzyme reaction system, no significant alterations were observed in the amount of NLA generated from racemic NDP. We concluded that MAO deaminates NDP to an aldehyde intermediate, and that mitochondrial ALDH subsequently catalyzes the enantioselective metabolism of the aldehyde intermediate to NLA in rat liver.     

Purification of rat liver enzymes involved in the oxidation of glyoxylate

The use of Sepharose aminohexyl oxamate for the purification of glycolate oxidase and lactate dehydrogenase is described. The kinetics of both enzymes are reported in relation to their possible roles in the production of oxalate. A model is proposed in which glycolate oxidase in the peroxisomes and lactate dehydrogenase in the cytosol cooperate in the production of oxalate.     

Effects of hemin on rat liver cyclic AMP-dependent protein kinases in cell extracts and intact hepatocytes

Cyclic AMP-dependent protein kinases I and II, partially purified from rat liver cytosol, were inhibited 50% by 40 μM hemin and 100 μM hemin, respectively. With the purified catalytic subunit of cyclic AMP-dependent protein kinase, hemin caused non-competitive inhibition with respect to the peptide substrate and mixed inhibition with respect to ATP. Hemin also inhibited purified phosphorylase b kinase, indicating that hemin concentrations above 10 μM markedly inhibit multiple protein kinases. In isolated intact hepatocytes, hemin inhibited the glucagon-dependent activation of cyclic AMP-dependent protein kinases and the activation of glycogen phosphorylase. For both effects, high heme concentrations (40–60 μM) were required for 50% inhibition. Similar high levels of exogenous hemin inhibited total hepatocyte protein synthesis. By contrast, 5 μM hemin or less was sufficient to raise intracellular heme levels, as indicated by the relative heme-saturation of tryptophan oxygenase in hepatocytes. Hemin, 5 μM, completely repressed induction of 5-aminolevulinate synthase by dexamethasone in hepatocyte primary cultures. Such repression is unlikely to be mediated by inhibition of protein kinases.     

The preferred route of kynurenine metabolism in the rat

It has been suggested (Ueda, T., Otsuka, H. and Goda, K. (1978) J. Biochem. 84, 687–696) that direct cleavage of kynurenine, catalysed by kynureninase, followed by microsomal hydroxylation of the resultant anthranilic acid, may provide an alternative to the established pathway of kynurenine metabolism that involves direct hydroxylation followed by cleavage to 3-hydroxyanthranilic acid. To test this suggestion, anthranilic acid was administered to rats; there was no increase in either the concentration of nicotinamide nucleotides in the liver or the urinary excretion of N¹-methyl nicotinamide. However, injection of either kynurenine or 3-hydroxyanthranilic acid did increase the concentration of nicotinamide nucleotides in the liver. The kinetics of kynurenine hydroxylase (K_m = 1.8±0.6·10^?5 mol/l) and kynureninase (K_m = 2.5±0.8·10^?4 mol/l, liver steady-state kynurenine = 4.9±0.9 μmol/kg) are such that the preferred route of kynurenine metabolism is probably by way of hydroxylation rather than cleavage.     

Regulation of insulin binding and glycogenesis by insulin and dexamethasone in cultured rat hepatocytes

Regulation of insulin-binding and basal (insulin-independent) as well as insulin-stimulated glycogen synthesis from [¹⁴C]glucose, net glycogen deposition and glycogen synthase activation by insulin and dexamethasone were studied in primary cultures of adult rat hepatocytes maintained under chemically defined conditions. (1) Insulin receptor number was increased in a dose-dependent fashion by dexamethasone added to the medium between 24 and 48 h of culture and reduced by insulin, whereas ligand affinity remained unaltered. Insulin-induced down-regulation of insulin receptors was not affected by the glucocorticoid. (2) Although the changes in the sensitivity to insulin of glycogen synthesis from glucose and net glycogen deposition paralleled the modulation of the number of insulin receptors, postbinding events appear to be implicated also in the regulation of insulin-sensitivity. (3) Alterations of the responsiveness of glycogen synthesis to insulin caused by the glucocorticoid and/or insulin and by variation between individual rats were inversely related to cellular glycogen contents, suggesting that hepatocellular glycogen content participates in the regulation of insulin-responsiveness of this metabolic pathway. (4) Regulation of insulin-independent glycogenesis in response to an increase from 5 to 10 mM glucose, and of insulin-dependent glycogen synthesis were different. Since the effects of this ‘physiological’ increase in exogenous glucose were small compared to the acute action of insulin, insulin rather than portal venous glucose is considered to represent the prime stimulator of hepatic glycogen synthesis.     

Studies of ethylene-forming system in rat liver extract

Evidence of enzymatic formation of ethylene from methionine by rat liver extracts is presented. The ethylene production is closely associated with growth of the animal. The conversion of l-methionine to ethylene is oxygen dependent. Substrate analogue studies show that the ethylene-forming system is structurally specific and requires in the center of the molecule α-CH₂-CH₂- with one end attached to an unencumbered sulfur atom from a thioether moiety and the other end attached to a carboxyl group. Sylfhydryl agents are found to be very effective inhibitors of the ethylene-forming system. The finding of α-keto-4-methylthiobutyric acid to be a more efficient precursor of ethylene production suggests the possibility that α-keto-4-methylthiobutyric acid may be an intermediate in the biosynthesis of ethylene from methionine in mammalian tissues.     

Formation of glycine and aminoacetone from l-threonine by rat liver mitochondria

Threonine is a precursor of glycine in the rat, but the metabolic pathway involved is unclear. To elucidate this pathway, the biosynthesis of glycine, and of aminoacetone, from l-threonine were studied in rat liver mitochondrial preparations of differing integrities. In the absence of added cofactors, intact mitochondria formed glycine and aminoacetone in approximately equal amounts from 20 mM l-threonine, but exogenous NAD⁺ decreased and CoA increased the ratio of glycine to aminoacetone formed. In intact and freeze-thawed mitochondria, the ratio of glycine to aminoacetone formed was markedly sensitive to the concentration of l-threonine, glycine being the major product at low l-threonine concentrations. Disruption of mitochondrial integrity by sonication (1 min) decreased the ratio of glycine to aminoacetone formed, and in 20 000 × g supernatant fractions from sonicated (3 min) mitochondria, aminoacetone was the major product. The main non-nitogenous tow-carbon compound detected when intact mitochondria catabolized l-threonine to glycine was acetate, which was probably derived from deacylation of acetyl-CoA. These results suggest that glycine formation from l-threonine in rat liver mitochondria occured primarily by the coupled activities of threonine dehydrogenase and 2-amino-3-oxobutyrate CoA-ligase, the extent of coupling between the enzymes being dependent upon a close physical relationship and upon the flux through the dehydrogenase reaction. In vivo glycine synthesis would predominate, and aminoacetone would be a minor product.     

Response of rat connective tissues to streptozotocin-diabetes. Tissue-specific effects on collagen metabolism

We assessed the effect of streptozotocin-diabetes on in vivo collagen metabolism in skin, aorta and intestine by injecting [³H]proline into rats, 20 days after administering the diabetogen, streptozotocin. One day after [³H]proline injection, diabetic and control animals were killed, their tissues analyzed for both ³H-labeled and unlabeled hydroxyproline and results expressed per entire tissue. Thereby, the effect of diabetes on net collagen synthesis and tissue collagen mass, respectively, was evaluated.Diabetes resulted in a lower content of [³H]collagen in skin and aorta, suggesting decreased net collagen synthesis. This decrease in net synthesis was accompanied by a decrease of collagen mass in skin, whereas aortic collagen mass was unaffected. Consequently, an acceleration of collagen degradation in skin is postulated to have accompanied the expected depression of collagen synthesis; alterations of the physiochemical properties of skin from diabetic rats support this interpretation. For intestine, both net collagen synthesis and mass increased in diabetic rats, reflecting increased collagen synthesis—possibly associated with polyphagy.In conclusion, with regard to collagen metabolism, representative connective tissues respond differently to experimental diabetes, and we suggest that this insight will be useful in future studies aimed at understanding the pathophysiology of connective tissues affected by diabetes.     

Purification and some properties of ornithine decarboxylase from rat liver

Ornithine decarboxylase (EC 4.1.1.17) was purified to near homogeniety from livers of thioacetamide- and dl-α-hydrazino-δ-aminovaleric acid-treated rats by using three types of affinity chromatography with pyridoxamine phosphate-Sepharose, pyridoxamine phosphate-dipropylenetriamine-Sepharose and heparin-Sepharose. This procedure gave a purification of about 3.5·10⁵-fold with an 8% yield; the specific activity of the final enzyme preparation was 1,1·10⁶ nmol CO₂/h per mg protein. The purified enzyme gave a single band of protein which coincided with activity peak on polyacrylamide gel electrophoresis and also gave a single major band on SDS-polyacrylamide gel electrophoresis. A single precipitin line was formed between the purified enzyme and an antiserum raised against a partially purified enzyme, on Ouchterlony immunodiffusion. The molecular weight of the enzyme was estimated to be 105 000 by polyacrylamide gel electrophoresis at several different gel concentrations; the dissociated subunits had molecular weights of 50 000 on SDS-polyacrylmide gels. The isoelectric point of the enzyme was pH 4.1.     

Mössbauer spectroscopy of iron metabolism and iron intracellular distribution in liver of rats

Mössbauer spectroscopy was used to investigate the distribution of iron in rat organs and its localisation in liver subcellular fractions. A ⁵⁷Fe-sucrose complex solution was injected by 0.5 ml doses into tail veins of anmals every day, during a 6-day period. Mössbauer spectra were measured in spleen, blood, liver and liver subcellular fractions. The Mössbauer spectrum of a spleen sample has two symmetrical doublets, one with δ=0.6 mm/s and Δ=0.7 mm/s, and the other with δ=1.0 mm/s and Δ=2.35 mm/s. The Mössbauer spectrum of blood has parameters which are close to those for carboxyhemoglobin and oxyhemoglobin complexes. After the addition of sodium citrate, the proportion of the carboxyhemoglobin complexes increases. The Mössbauer spectrum of liver has a two-component pattern with two symmetrical doublets, the first with δ=0.6 mm/s and Δ=0.63 mm/s and the second with δ=1.4 mm/s and Δ=3.45 mm/s. The first component, which was identified as ferritin, is present in all subcellular fractions (800 × g_av sediment fraction, mitochondrial/lysosomal, microsomal and supernatant fractions), with its content in microsomal fraction. After the addition of NaBH₄ to mitochondrial/lysosomal fraction, about 20 % of the iron contained in ferritin was reduced. In the Mössbauer spectrum this is reflected by an appearance of a doublet with δ=0.85 mm/s and Δ=3.7 mm/s.     

Antiestrogen binding sites in rat liver nuclei

Isolated, intact rat liver nuclei have high-affiity (K_d=10⁻⁹ M) binding sites that are highly specific for nonsteroidal antiestrogens, especially for compounds of the triphenylethylene series. Nuclear [³H]tamoxifen binding capacity is thermolabile, being most stable at 4°C and rapidly lost at 37°C. More [³H]tamoxifen, however, is specifically bound at incubation temperatures of 25°C and 37°C than at 4°C although prewarming nuclei has no effect, suggesting exchange of [³H]tamoxifen for an unidentified endogenous ligand. Nuclear antiestrogen binding sites are destroyed by trypsin but not by deoxyribonuclease I or ribonuclease A. The nuclear antiestrogen binding protein is not solubilized by 0.6 M potassium chloride, 2 M sodium chloride, 0.6 M sodium thiocyanate, 3 M urea, 20 mM pyridoxal phosphate, 1% (w/v) digitonin or 2% (w/v) sodium cholate but is extractable by sonication, indicating that it is tightly bound within the nucleus. Rat liver nuclear matrix contains high-affinity (K_d=10⁻⁹ M) [³H]tamoxifen binding sites present in 5-fold higher concentrations (4.18 pmol/mg DNA) than in intact nuclei (0.78±0.10 (S.D.) pmol/mg DNA). Low-speed rat liver cytosol (20 000×g, 30 min) contains high-capacity (955±405 (S.D.) fmol/mg protein), low-affinity (K_d=10.9±4.5 (S.D.) nM) antiestrogen binding sites. In contrast, high-speed cytosol (100 000×g, 60 min) contains low-capacity (46±15 (S.D.) fmol/mg protein), high-affinity (K_d=0.61± 0.20 (S.D.) nM) binding sites. Low-affinity cytosolic sites constitute more than 90% of total liver binding sites, high-affinity cytosolic sites 0.3%–3.2%, and nuclear sites less than 0.5% of total sites.     

Glycogen metabolism in resting and growing cells of Saccharomyces carlsbergensis

Saccharomyces carlsbergensis cells, growing under carbohydrate or nitrogen limitation, initially deplete their glycogen, which is resynthesized only during the late exponential phase. Cells, harvested in the carly exponential phase, are even unable to synthesize glycogen in glucose-containing phosphate buffer. This is in contrast to cells from the stationary phase which rapidly synthesize glycogen under the same conditions. Lack of O₂ slows down glycogen synthesis.Contrary to cells suspended in complete medium, addition of ammonia alone to nitrogen free-media induced neither breakdown of glycogen, nor complete cessation of glycogen synthesis. Ammonia slowed down glycogen synthesis (both aerobic and anaerobic), only, in cells grown either under carbohydrate or under nitrogen limitation.Glycogen synthesis was observed 1 min after addition of glucose to a starved cell suspension in phosphate buffer. Removal of the sugar from the buffer resulted in an instantanous decrease of the glycogen level in the cells. The results indicate that glycogen-metabolism is regulated by a variety of endogenous and environmental factors.     

Binding of [H]methyltrienolone to androgen receptor in rat liver

The synthetic androgen methyltrienolone is superior to testosterone and androstenedione for the measurement of androgen receptor in tissues where the native ligands are metabolized into inactive derivatives. [³H]Methyltrienolone binds with a high affinity to androgen receptor in cytosol prepared from male rat livers, as the Scatchard analysis revealed that the K_d value was 3.3 · 10⁻⁸ M and the number of binding sites was 35.5 fmol/mg protein. Since methyltrienolone also binds glucocorticoid receptor which exists in rat liver, the apparent binding of androgen receptor is faulty when measured in the presence of glucocorticoid receptor. The binding of methyltrienolone to glucocorticoid receptor can be blocked by the presence of a 100-fold molar excess of unlabeled synthetic glucocorticoid, triamcinolone acetonide, without interfering in its binding to androgen receptor, because triamcinolone does not bind to androgen receptor. Triamcinolone-blocked cytosol exhibited that the K_d value was 2.5 · 10⁻⁸ M and the number of binding sites was 26.3 fmol/mg protein, indicating a reduction to of that in the untreated cytosol. The profile of glycerol gradient centrifiguration indicated that [³H]methyltriemolone-bound receptor migrated in the 8–9 S region in both untreated and triamcinolone-blocked cytosols, but the 8–9 S peak in triamcinolone-blocked cytosol was reduced to about of that of untreated cytosol.     

Presence of di- and polyamines covalently bound to protein in rat liver

Acid hydrolysis of trichloroacetic acid precipitate from rat tissue (liver, kidney and testis) homogenate released significant amounts of acid-insoluble putrescine, spermidine and spermine. Following incubation of liver homogenate with [1,4-¹⁴C]putrescine, 1.4% of total radioactivity and 1.0% of labelled diamine were recovered in the acid-insoluble fraction. Exhaustive digestion of acid-precipitable material with proteinases (Pronase, aminopeptidase M, carboxipeptidase A, B and Y) revealed the presence of di- and polyamines and of N¹-(γ-glutamyl)spermidine, N¹-(γ-glutamyl)sperminine and N¹, N¹²-bis(γ-glutamyl)spermine. These derivatives were identified both by chromatographic analysis and by enzymatic digestion with purified γ-glutamylamine cyclotransferase. The finding of di- and polyamine γ-glutamyl derivatives in the proteinase-digested acid-insoluble fraction of homogenate may be considered as a proof of the in vivo transglutaminase-catalyzed binding of polyamines to proteins. This evidence suggests that di- and polyamines might have an important role in mammalian tissues through covalent binding to proteins by either one or both the primary amino groups.     

Regulation of glycogenolysis in the liver of the newborn rat in vivo inhibitory effect of glucose

Newborn rats were injected immediately after delivery with glucose or glucose plus mannoheptulose, and the time-courses of liver glycogen, plasma glucose, insulin and glucagon concentration were studied. The administration of glucose prevented both liver glycogenolysis and the increase in plasma glucagon concentration which normally occurs immediately after delivery. In addition, the administration of glucose prevented the decrease of plasma glucose and insulin concentration which normally occurs during the first hour of extrauterine life. Supplementation of glucose with mannoheptulose prevented the increase of plasma insulin concentrations caused by the administration of glucose; liver glycogenolysis, however, was not stimulated in these circumstances. The increase in the rate of glycogenolysis caused by the administration of glucagon was prevented in newborn rats previously treated with glucose. These results suggest that glucose exerts an inhibitory effect on the stimulation of neonatal liver glycogenolysis by glucagon.