Retinoic acid maintains differentiated cell morphology and functions in long-term cultured porcine hepatocytes: obtaining functional cells for prolonged treatments with bioartificial liver.

Porcine hepatocytes show several immunological characteristics and enzymatic activities of human liver, representing an ideal xenogenic source of cells as biological component of bioartificial liver (BAL). Isolated hepatocytes rapidly lose their specific metabolic activities and their typical morphology when cultured in the presence of serum. Since in BAL porcine hepatocytes are perfused by the patient's plasma, procedures able to minimize de-differentiation of cells could be useful for long-term treatment of acute liver failure (ALF). In this work we found that, in the presence of micromolar concentration of All trans-retinoic acid (ATRA), porcine parenchymal liver cells undergo to a lower extent the de-differentiating effects of long-term culture in the presence of serum. The evaluation of lidocaine metabolism showed that ATRA-treated cells retain specific hepatocyte function for a significantly longer time when compared to control hepatocytes. A tyrosine phosphorylation of PLC-gamma1 was observed in concomitance with the ATRA-induced maximal functional activity. An increased expression of PLC-beta3 and PKC-alpha and -beta2 was also evidentiated at the longer time points explored, when the effects of ATRA in preservation of the differentiated morphology were maximal. These results provide the first evidence that ATRA plays a differentiating role in adult porcine hepatocytes cultured under de-differentiating conditions. The administration of ATRA to isolated parenchymal cells from pig liver may provide functional hepatocytes for prolonged treatment with BAL.

Modulation of pro-apoptotic (Bax) and anti-apoptotic (Bcl-2) gene expression in isolated porcine hepatocytes perfused within a radial-flow bioreactor after low-temperature storing.

Due to the scarcity of available human livers, porcine hepatocytes are currently being evaluated as a xenogeneic cell source for extracorporeal bioartificial liver (BAL). Hypothermic storage of isolated porcine hepatocytes could support stocking of cell-loaded bioreactors for BAL use and may provide bioreactors ready to be used at the patient's bedside. For the development of this technology, it is of utmost importance to ensure cell viability and differentiated functions after low-temperature storage and following warm reperfusion. We compared cell viability, functional activity and apoptosis in isolated porcine hepatocytes which were perfused within a radial-flow bioreactor (RFB), stored at 4 degrees C and then reperfused at 37 degrees C. RFBs were loaded with 8 x 10(9), > or = 90% viable hepatocytes at 37 degrees C for 3 h. RFBs were then flushed with 4 degrees C University of Wisconsin solution (UW) and subsequently stored for 24 h or 48 h. RFBs were then reperfused for 8 h with recirculating medium plus serum at 37 degrees C . Cytochrome P450 (CYP) activity was studied before and after cold storage by means of monoethylglycinexylide (MEGX) detection in the effluent medium, after repeated lidocaine injections. After reperfusion experiments, hepatocytes were harvested for total RNA isolation. Reverse transcriptase-polymerase chain reaction (RT-PCR) was used in order to amplify specific mRNAs for Bcl-2 and Bax genes, by using appropriate primers; beta-actin primers were used as control. Total RNA was extracted by northern blotting analysis and for Bcl-2, Bax and beta-actin RNA messenger detection, RT-PCR amplification was used. Freshly isolated hepatocytes perfused into the RFB showed a progressive increase of MEGX while a loss in Bax expression was paralleled by an increase in Bcl-2 expression, in comparison to starting hepatocytes. After 4 degrees C storage and warm reperfusion, MEGX production was preserved in 24 h- and 48 h-stored bioreactors as well as a sharp increase of Bcl-2 and a decrease of Bax mRNAs. Our study suggests that refrigeration of hepatocyte-bioreactors is a suitable strategy to maintain both viability and function of isolated hepatocytes, for up to 48 h a time-length that is compatible with long-distance delivery of ready-to-use bioreactors.

Biologic liver support: optimal cell source and mass.

Hepatic support is indicated in acute liver failure (ALF) patients to foster liver regeneration, or until a liver becomes available for orthotopic liver transplantation (OLT), in primary non function of the transplanted liver, and hopefully in chronic liver disease patients affected by ALF episodes, in whom OLT is not a therapeutic option. The concept of bioartificial liver (BAL) is based on the assumption that only the hepatocytes can perform the whole spectrum of biotransformation functions, which are needed to prevent hepatic encephalopathy, coma and cerebral edema. Among others, two important issues are related to BAL development: 1) the choice of the cellular component; 2) the cell mass needed to perform an adequate BAL treatment. Primary hepatocytes, of human or animal origin, should be considered the first choice because they express highly differentiated functions. Accordingly, a minimal cell mass corresponding to 10% of a human adult liver, i.e. 150 grams of freshly isolated, > or = 90% viable hepatocytes should be used. When 4 degrees C cold-stored or cryopreserved hepatocytes are used, the cellular mass should be increased because of a drop in cell viability and function. In case of hepatoma-derived cells, cultured cell lines or engineered cells, an adequate functional cell mass should be used, expressing metabolic and biotransformation activities comparable to those of primary hepatocytes. Finally, the use of porcine hepatocytes or other animal cells in BAL devices should be presently directed only to ALF patients as a bridge treatment to OLT, because of potential transmission of animal retrovirus and prions which may potentially cause major pandemics.

Early experiences with a porcine hepatocyte-based bioartificial liver in acute hepatic failure patients.

Orthotopic liver transplantation (OLT) is the only effective therapeutic modality in severe acute hepatic failure (AHF). The scarcity of organs for transplantation leads to an urgent necessity for temporary liver support treatments in AHF patients. A hepatocyte-based bioartificial liver (BAL) is under investigation with the main purpose to serve as bridging treatment until a liver becomes available for OLT, or to promote spontaneous liver regeneration. We developed a novel radial-flow bioreactor (RFB) for three-dimensional, high-density hepatocyte culture and an integrated pumping apparatus in which, after plasmapheresis, the patient's plasma is recirculated through the hepatocyte-filled RFB. Two hundred thirty grams of freshly isolated porcine hepatocytes were loaded into the RFB for clinical liver support treatment. The BAL system was used 8 times in supporting 7 AHF patients in grade III-IV coma, all waiting for an urgent OLT Three patients with no history of previous liver diseases were affected by fulminant hepatic failure (FHF) due to hepatitis B virus, 3 by primary non-function (PNF) of the transplanted liver, and one by AHF due to previous abdominal trauma and liver surgery. Six out of 7 patients underwent OLT following BAL treatment(s), which lasted 6-24 hours. All patients tolerated the procedures well, as shown by an improvement in the level of encephalopathy, a decrease in serum ammonia, transaminases and an amelioration of the prothrombin time, with full neurological recovery after OLT Our initial clinical experience confirms the safety of this BAL configuration and suggests its clinical efficacy as a temporary liver support system in AHF patients.

Long-term expression of highly differentiated functions by isolated porcine hepatocytes perfused in a radial-flow bioreactor.

To overcome the limitations of standard hollow-fiber module in ensuring efficient cell perfusion and long-term expression of highly differentiated hepatocyte functions, we developed a novel bioreactor in which a three-dimensional hepatocyte culture system was perfused in radial-flow geometry. Isolated porcine hepatocytes were cultured for 2 weeks in recirculating serum-free tissue culture medium, in which NH4Cl and lidocaine were repeatedly added, and ammonia removal, urea synthesis, monoethylglycinexylide (MEGX) production, albumin secretion, Po2, Pco2, O2 consumption, and pH were measured thereafter. During the whole duration of the study, ammonia removal was paralleled by urea production, while MEGX concentration was constantly increased. Our results indicated that hepatocytes remained differentiated and metabolically active throughout the duration of the study. The radial-flow bioreactor allowed physiological contact between recirculating fluid and cells by equalizing the concentration of the perfusing components, including O2, throughout the module, suggesting a potential use of this configuration for extracorporeal liver support.

[Isolated hepatocytes and their potential therapeutic use]. / Epatociti isolati e loro potenziale uso terapeutico.

Isolated hepatocytes in culture represent an idoneous system for the study of liver physiology and metabolism. Furthermore, they are also widely utilized in pharmacological and toxicological study, in evaluating xenobiotic substance effects on the liver. In this paper, we reviewed the enzymatic methods for liver cell isolation in some mammalian species, as well as the techniques for qualitative and quantitative evaluation of cell number, vitality, purity, morphology and function. Recently, there has been a renewed interest in hepatocyte transplantation and hepatocyte-based liver support systems. From a clinical point of view, isolated hepatocytes could be useful in temporarily substituting an acutely damaged liver, a liver affected by a chronic pathology, or to correct an inherited liver disease carrying a severe metabolic derangement. Early experimental results of allogeneic hepatocyte transplantation, as well as the first clinical trials of bioartificial liver support systems employing xenogeneic hepatocytes are promising and contribute to maintain that interest in liver cell isolation and purification methods.

[In vitro experimentation of a new model of radial flow bioreactor containing isolated hepatocytes]. / Sperimentazione in vitro di un nuovo modello di bioreattore a flusso radiale contenente epatociti isolati.

Hepatocyte based artificial liver support systems are under investigation to support acute liver failure patients. The main purpose of such systems is to serve as a bridge to liver transplantation, or to promote spontaneous liver recovery. Limitation in mass-transfer capacity makes hollow-fiber bioreactors unsuited for long-term functioning of hybrid devices. We developed a novel radial-flow bioreactor in which the fluid perfuses the module from the center to the periphery, after having diffused through a space occupied by a three-dimensional structure filled with the hepatocytes. Five grams of freshly isolated porcine hepatocytes were seeded into uncoated, woven-non woven, hydrophilic polyester fabric, overlaid by two polyethersulfone membranes. Liver cells were perfused with 37 degrees C-warm, oxygenated, serum-free tissue culture medium, in which NH4Cl and Lidocaine were added at the final concentration of 1 mM and 60 micrograms/ml, respectively. Ammonium chloride removal, urea synthesis, monoethylglycinexylide (MEGX), pO2, pCO2, and pH were measured throughout the 14 day duration of the study. In a separate set of experiments, a scaled-up version of the radial flow bioreactor containing 150 grams of cells was perfused for 7 h with recirculating human plasma and MEGX production was monitored. During the 2 weeks of the study, an increasing production of urea was paralleled by constant ammonium removal. MEGX concentration after Lidocaine addition increased throughout the 14 days of perfusion with tissue culture medium, as well as after 7 hour perfusion with human plasma. Under transmission and scanning electron microscopy cells appeared attached to the polyester and one to each other, displaying ultrastructural features typical of functioning hepatocytes. Our study showed that liver cells were metabolically active when perfused into the radial-flow bioreactor. This configuration allowed close contact between media, or plasma, and cells at a physiological flow rate, by equalizing the concentration of the perfusing components, including O2, throughout the module. Our results suggest a potential use of this system for temporary extracorporeal liver support in acute hepatic failure patients.

Biochemical assessment and clinical evaluation of a non-ionic adsorbent resin in patients with intractable jaundice.

We investigated in vitro and in vivo the ability of a non-ionic adsorbing resin (styrenedivinylbenzene copolymer) to remove bilirubin and bile acids from human plasma. In preliminary experiments, human plasma from healthy donors, enriched in conjugated bile acids and bilirubin, and pooled plasma from jaundiced patients were recirculated through the resin column. The removal of bilirubin and bile acids was evaluated at two different flow rates (200 ml/min and 40 ml/min), and compared to an activated charcoal column. Four patients with severe jaundice were subsequently treated by 4-hour plasmaperfusion through the resin. The in vitro studies showed that after 1 hour the removal of bile acids was almost complete and bilirubin level decreased significantly, reaching a plateau after 4 hours. In the in vivo study, all treatments were well tolerated. After plasmaperfusion, serum bile acid levels decreased by 64.9-94.6% and total bilirubin by 35.3-57.7%. No clinical or biochemical side effects were observed. Our data suggest that plasmaperfusion through this resin is safe and efficient for removal of bilirubin and bile acids in jaundiced patients. Thus, it may serve as a method of artificial liver support in the treatment of cholestatic syndromes.

Morphological and functional evaluation of isolated rat hepatocytes in three dimensional culture systems.

Various three-dimensional configurations, such as polyester tissue and woven-nonwoven, hydrophilic polyester fabric, either collagen-coated or uncoated, were investigated as potential scaffold for hepatocyte culture, in view of their use in bioreactors for hybrid liver support systems. Attachment, morphology and ultrastructure of primary adult rat hepatocytes were evaluated, as well as urea production and ammonium detoxification during a 24h incubation period in serum-free tissue culture medium. As control, hepatocytes were also plated onto collagen-coated dextran microcarriers and on plastic petri dishes, either collagen-coated or uncoated. In all the three-dimensional cultures, hepatocytes appeared morphologically intact without any statistically significant difference in metabolic activity. Collagen-coating did not influence cell attachment to polyester substrates, whereas woven-nonwoven hydrophilic polyester fabric may offer some potential advantages as three-dimensional system for hepatocyte culture in hybrid liver support systems.

An update on high-yield hepatocyte isolation methods and on the potential clinical use of isolated liver cells.

Isolated hepatocytes are a suitable system for the study of hepatic physiology and metabolism. They are also used for pharmacological and toxicological studies related to hepatic uptake, metabolism, excretion and toxicity of xenobiotics, as well as morphological and metabolic effects induced in the liver as a result of drug or toxic substance exposure. In this paper, the enzymatic methods for hepatocyte isolation in some mammalian species are reviewed, and methods for evaluating cell purification and assessment of cellular morphology and function are also examined. More recently, interest in hepatocyte transplantation has increased, and the clinical experimentation of hepatocyte-based liver support systems has attracted the attention of scientists and hepatologists. From a clinical perspective, using isolated hepatocytes could be useful both for supporting an acutely devastated liver, a chronically diseased liver, and for correcting genetic disorders resulting in metabolically deficient states. Reports of clinical usage of isolated allogenic hepatocytes in hepatocellular transplantation and of xenogenic liver cells in constructing bio-artificial liver support systems are promising, and are renewing interest in the development of methods for isolation and purification of hepatocytes.

Bile salt-induced cytotoxicity and ursodeoxycholate cytoprotection: in-vitro study in perifused rat hepatocytes.

OBJECTIVES: Membrane toxicity induced by hydrophobic bile salts may be important in liver diseases. Administration of ursodeoxycholate reduces serum liver enzymes in chronic liver diseases, but the nature of this effect is still unclear. We aimed at establishing a convenient in-vitro system for investigating the hepatotoxic properties of hydrophobic bile salts and the putative hepatoprotective effect of ursodeoxycholate. METHODS: About 100 mg of freshly isolated rat hepatocytes were suspended on a resin column (Bio-Gel P4 fine) and perifused with different concentrations of bile salts. The effluent was collected at 5-min intervals and assayed for lactate dehydrogenase (LDH), aspartate aminotransferase (AST) and alanine aminotransferase (ALT) activity. Enzyme leakage induced by bile salts was compared with that induced by Triton X-100 (Union Carbide, Danbury, CT, USA) at different concentrations. After perifusion, hepatocytes were collected for electron microscopic observation. RESULTS: Cytotoxicity of individual bile salts, assessed by enzyme release, was time and concentration dependent and corresponded to their hydrophilic-hydrophobic balance. Perifusion with hydrophilic bile salts, cholate and ursodeoxycholate, did not result in a significant enzyme release in concentrations up to 5 mmol/l, whereas hydrophobic bile salts, chenodeoxycholate and deoxycholate, induced significant enzyme leakage even in low concentrations, 0.5 and 0.1 mmol/l, respectively. Addition of ursodeoxycholate significantly reduced the hepatotoxic effect of deoxycholate. This protective effect was evident within minutes. The ultrastructural appearance of hepatocytes exposed to hydrophobic bile salts was very similar to the non-specific cellular lysis observed after exposition to Triton X-100, suggesting that they act mainly in a detergent-like fashion. CONCLUSION: Perifused rat hepatocytes seem a convenient in-vitro system for investigating the hepatotoxic properties of bile salts and hepatoprotective effect of ursodeoxycholate, offering the opportunity to investigate the effects of bile salts under dynamic conditions, mimicking the in-vivo situation, and allowing continuous enzyme release monitoring. Hydrophobic bile salts seem to act mainly in a detergent-like fashion; ursodeoxycholate-related hepatoprotection could be due not only to a dilution effect of toxic bile salts, but also to a direct cytoprotective effect.

Identification of alpha-adrenergic receptors in catfish liver and their involvement in glucose release.

This study aimed to characterize alpha-adrenergic receptors in catfish hepatocytes in which catecholamine-induced calcium transients have been observed. alpha-Adrenergic binding sites were studied in purified liver membranes using the specific alpha 1-receptor antagonist [3H]prazosin. At 22 degrees C specific binding of [3H]prazosin is saturable, reversible, and linear as a function of tissue concentration; the association reaches a maximum at 15 min, and the half-time for dissociation is about 4 min. Analysis of binding data suggests a single class of binding sites with a Kd of 1.6 nM and a Bmax of 182.1 fmol/mg protein. The relative potency of selective adrenoceptor ligands points to the presence in catfish liver of alpha-adrenergic receptors in addition to the beta-adrenergic receptor population previously characterized. Moreover, the binding data have been correlated to the glucose release from isolated hepatocytes suspended and perifused in a BioGel column, suggesting the involvement of alpha-adrenergic receptors in the glycogenolytic response to catecholamines in catfish hepatocytes.

Hormone responsiveness of isolated catfish hepatocytes in perifusion system is higher than in flasks incubation.

Hepatocytes were isolated from catfish (lctalurus melas) by conventional collagenase digestion. Sensitivities of liver cells isolated from the same fish to the glycogenolytic action of epinephrine, mammalian glucagon, catfish glucagon, catfish glucagon-like peptide, synthetic fragment 19-29 of anglerfish glucagon I, fragment 19-29 of anglerfish glucagon II, and anglerfish glucagon II were compared in two different systems: perifusion in a Bio-Gel P4 column and flask incubation. Both experimental procedures were continued for a total of 100-120 min, while hormones were applied simultaneously to both preparations for 10 min. Effluent fractions from the columns and incubation media from the flasks were collected for glucose determination. The hormonal effects were clearly enhanced in perifused cells compared to those in cells incubated in flasks, the effect being especially evident at physiological concentrations of hormones. The hormonal effects in both systems were dose-dependent. Epinephrine and mammalian glucagon (10 nM), applied separately to the same column, produced two different peaks, glucagon causing more glucose production than epinephrine. In the presence of 0.4 mM glucose in the perifusion system, hormonal effects were diminished, implying that glucose accumulation during incubation of liver cells in flasks might affect hormonal effects. The results obtained in this study indicate that piscine hepatocytes suspended and perifused in a Bio-Gel column are more sensitive to physiological concentrations of glycogenolytic hormones and may represent a new tool for experimental studies of fish liver metabolism and its hormonal regulation.

Alpha-mediated changes in hepatocyte intracellular calcium in the catfish, Ictalurus melas.

Adult catfish, Ictalurus melas, hepatocytes respond to alpha-agonists by increasing intracellular free calcium concentrations ([Ca2+]i) in a dose-dependent manner. Basal [Ca2+]i were approximately 78 nM in catfish hepatocytes; this value was increased by 213, 243, 131, and 238 nM in the presence of epinephrine (Epi; 10(-6) M), norepinephrine (NE; 10(-5) M), phenylephrine (PE; 10(-4) M), and isoproterenol (Iso; 10(-4) M), respectively. The binding constants were 3.4 x 10(-8), 2.6 x 10(-7), 9.8 x 10(-7), and 6.1 x 10(-5) M for Epi, NE, PE, and Iso, respectively, which is the same order of potency for these agonists reported for the alpha 1-adrenoceptor system of mammalian hepatocytes. The Epi-induced changes in [Ca2+]i were antagonized equally by phentolamine (PH; 10(-8) M) and yohimbine (10(-8) M) but poorly by propranolol (Prop; 10(-6) M), as indicated by their respective inhibitory constants. Epi (10(-7) M) induced a time-dependent increase in hepatocyte adenosine 3',5'-cyclic monophosphate concentration that was antagonized by Prop but not PH. There were, however, no clear agonist-induced changes in the activities of glycogen phosphorylase (total, a, or %a) under these conditions. These studies provide evidence that Epi and other adrenergic agonists increase [Ca2+]i by an alpha- or alpha 1-like adrenoceptor pathway in catfish hepatocytes, but the biochemical effector system responding to changes in [Ca2+]i has yet to be elucidated.

Beta-adrenergic receptors in catfish liver membranes: characterization and coupling to adenylate cyclase.

beta-Adrenergic binding sites in catfish liver membranes have been characterized by centrifugal assay, using a beta-adrenergic receptor antagonist, (-)-[3H]dihydroalprenolol ([3H]DHA). Binding of the radioligand was saturable and reversible. At 22 degrees equilibrium conditions were established in 15 min and the half-time for dissociation of bound [3H]DHA was approximately 4 min. Analysis of binding data was compatible with the existence of two classes of binding sites: a low-affinity site had a Kd of 62.3 nM and a Bmax of 452.0 fmol/mg protein, while the high-affinity site had a Kd of 2.04 nM and a Bmax of 46.7 fmol/mg protein. The dissociation constant of (-)-alprenolol for the beta-adrenergic receptors was about 2 nM as determined independently by direct kinetic studies and by inhibition of isoproterenol-stimulated adenylate cyclase activity. Phenylephrine was as potent as other catecholamines in inhibiting [3H]DHA binding, indicating that fish adrenoceptor subtyping is different from that of mammals.

Interaction of salmon glucagon, glucagon-like peptide, and epinephrine in the stimulation of phosphorylase a activity in fish isolated hepatocytes.

The simultaneous addition of epinephrine and salmon glucagon to catfish (Ictalurus melas) and trout (Salmo gairdneri) hepatocytes did not induce greater increases in glycogen phosphorylase a activity and in glucose release than those caused by epinephrine alone. The effects of epinephrine are greater than those of glucagon. Propranolol added to the hormonal pool blocked the epinephrine effects. In trout cells, epinephrine and glucagon-like peptide (GLP) had similar effects and when they were added simultaneously the stimulation of metabolic indices was higher compared to that obtained with either epinephrine or GLP. However, the effects were not additive. In the presence of epinephrine plus GLP the inhibitory effect of propranolol was not evident, due to the effect induced by GLP, on which propranolol was not effective. This may indicate that epinephrine masks the GLP effect. Results could mean that epinephrine and glucagon-family peptides act in catfish and trout hepatocytes through different receptors on the same pathway leading to glycogen phosphorylase a activation.

Glycogenolytic action of glucagon-family peptides and epinephrine on catfish hepatocytes.

Glycogenolytic effects of salmon and mammalian glucagons, salmon glucagon-like peptide (GLP) and epinephrine were studied on liver cells isolated from catfish (Ictalurus melas). In spring and summer, salmo-glucagon (3×10(-10) to 3×10(-8) M) was more effective than its mammalian counterpart in the stimulation of glucose release and cAMP synthesis in hepatocytes. GLP was less potent as compared to both glucagons. γ-amylase activity was not affected by the treatment with either glucagon-family peptides or epinephrine.The comparison of the glycogenolytic effects of salmon glucagon to those of epinephrine reveals a greater potency of the latter hormone in the stimulation of cAMP synthesis, glycogen-phosphorylase activity and glucose release. Glycogen content in the liver cells was equally depleted after treatment with both of the two hormones.

Adenylate cyclase of catfish hepatocyte membranes: basal properties and sensitivity to catecholamines and glucagon.

Some characteristics of adenylate cyclase of catfish (Ictalurus melas) liver membranes were studied, and the effects of catecholamines and of glucagon were tested. The enzyme has an optimum temperature of 40 degrees C, and a Km for ATP of 0.16 mM at 30 degrees C, and requires Mg2+ for its activity. The enzyme activity is inhibited with a Ca2+ concentration higher than 5 X 10(-5) M, and enhanced with F- higher than 10(-4) M. The response of adenylate cyclase to GTP is biphasic, with a maximum of activity at 10(-5) M GTP. Catecholamines (epinephrine, norepinephrine, isoproterenol, phenylephrine) enhance cyclase activity. Propranolol inhibits the increase in enzyme activity induced by catecholamines, whereas phentolamine is ineffective. This indicates that catecholamines (phenylephrine included) activate adenylate cyclase through a beta-adrenergic mechanism. Glucagon (mammalian) has a smaller effect than epinephrine in increasing the enzyme activity of catfish hepatocyte membranes. This fact is the opposite of that observed for the cyclase activity of rat liver membranes.

Glucagon control of glycogenolysis in catfish tissues.

1. In catfish (Ictalurus melas) after glucagon treatment blood glucose increased until 150 min, then it gradually decreased towards control values at the 5th hr. 2. In glucagon treated fish, liver glycogen levels were significantly lower then in controls 30 min after hormone administration; thereafter, liver glycogen levels returned rapidly to initial values. Glucagon did not induce any significant effect on the glycogen content in white and red muscles. 3. In liver slices, the addition of glucagon to the incubation medium significantly enhanced the glycogen phosphorylase activity and decreased the level of glycogen. Both phosphorylase activity and glycogen content of white and red muscle slices were practically unaffected by glucagon.