Project description:1. Isolated parenchymal cells were prepared by collagenase perfusion of livers from fed rats that had been previously injected with [(3)H]leucine to label liver proteins. When these cells were incubated in a salts medium containing glucose, gelatin and EDTA, cellular integrity was maintained over a period of 6h. 2. Cells incubated in the presence of 2mm-leucine to minimize radioactive isotope reincorporation released [(3)H]leucine into the medium at a rate accounting for the degradation of 4.5% of the labelled cell protein per h. 3. Degradation of [(3)H]protein in these cells was inhibited by insulin and by certain amino acids, of which tryptophan and phenylalanine were the most effective. 4. Protein degradation was decreased by several proteinase inhibitors, particularly those that are known to inhibit lysosomal cathepsin B, and by inhibitors of cell-energy production. 5. Ammonia inhibited degradation, but only at concentrations above 1.8mm. Aliphatic analogues of ammonia were effective at lower concentrations than was ammonia. 6. High concentrations of ammonia inhibited degradation by 50%. The extent of this inhibition could not be increased further by the addition of the cathepsin B inhibitor leupeptin, which by itself inhibited degradation by approx. 30%. 7. The sensitivity of proteolysis in isolated hepatocytes to these various inhibitory agents is discussed in relation to their possible modes of action.

Project description:The major steps in cholera-toxin action, i.e. binding, internalization, generation of A1 peptide and activation of adenylate cyclase, were examined in isolated hepatocytes. The binding of toxin involves a single class of high-affinity sites (KD congruent to 0.1 nM; Bmax. congruent to 10(7) sites/cell). At 37 degrees C, cell-associated toxin is progressively internalized, as judged by the loss of its accessibility to antibodies against whole toxin, A and B subunits (about 50, 75 and 30% of initially bound toxin after 40 min respectively). Two distinct pathways are involved in this process: endocytosis of the whole toxin, and selective penetration of the A subunit into the plasma membrane. Exposure of hepatocytes to an acidic medium (pH 5) results in a rapid and marked disappearance of the A subunit from the cell surface. Generation of A1 peptide and activation of adenylate cyclase by the toxin occur after a lag phase (10 min at 37 degrees C), and increase with time in a parallel manner up to 2-3% A1 peptide generated; they are unaffected by exposure of cells to an acidic medium. Chloroquine and monensin, which elevate the pH in acidic organelles, inhibit by 2-4-fold both the generation of A1 peptide and the activation of adenylate cyclase. Unexpectedly, these drugs also inhibit the internalization of the toxin. These results suggest that an acidic pH facilitates the penetration of A subunit into the plasma membrane and presumably the endosomal membrane as well, and that endocytosis of cholera toxin is required for generation of A1 peptide and activation of adenylate cyclase.

Project description:In freshly isolated hepatocytes, in which extracellular degradation of insulin was very low, the degradation velocity was first-order with respect to the amount of insulin bound at steady state. The addition of bacitracin decreased the degradation velocity considerably, so that a higher proportion of cell-associated radioactivity remained intact. The results demonstrate that bacitracin affects the mechanism of insulin processing by intact hepatocytes.

Project description:We have shown that degradation of asialo-orosomucoid (ASOR) in isolated rat hepatocytes occurs by two different intracellular pathways [Clarke, Oka & Weigel (1987) J. Biol. Chem. 262, 17384-17392] mediated by two subpopulations of cell surface galactosyl (Gal) receptors, designated State 1 or State 2 receptors. In the present study, several inhibitors were tested for their effects on ligand degradation by the State 1 or State 2 pathway. Leupeptin, monensin and chloroquine completely inhibited degradation of 125I-labelled ASOR in both pathways. Dose-response studies showed, however, that the State 2 pathway was more sensitive to leupeptin or monensin than the State 1 pathway. No differences were observed with chloroquine. For example, the onset of inhibition in the State 2 and State 1 pathways occurred at about 0.05 and 0.3 microM-leupeptin respectively, a 6-fold difference. At 3.5 microM-monensin, 125I-ASOR degradation in the State 2 pathway was completely blocked, whereas degradation in the State 1 pathway was essentially unaffected. Colchicine was observed to give the largest differential sensitivity between the two pathways. The State 2 degradation pathway was about 30-fold more sensitive to colchicine than the State 1 pathway. Lumicolchicine had no affect. The onset of inhibition of the rate of 125I-ASOR degradation in the State 2 and State 1 pathways occurred at approximately 0.1 and 3.0 microM-colchicine respectively. At very high concentrations (greater than 0.1 mM), the State 1 pathway could be completely inhibited. We conclude that intracellular 125I-ASOR processing or delivery to degradative compartments in both the State 1 and State 2 Gal receptor pathways requires low pH. Ligand delivery to the degradative compartment does not require microtubules in the State 1 pathway, consistent with the very rapid onset of degradation in this pathway. The State 2 degradation pathway does require microtubules.

Project description:Monensin, a univalent ionophore, is a carboxylic acid produced by Streptomyces cinnamonensis. It will complex various alkali-metal ions, but most readily binds Na+. Because of interest in the possible role of Na+ in the regulation of insulin secretion, we examined its effects on several aspects of the metabolism of isolated rat islets of Langerhans. The ionophore inhibited glucose-stimulated insulin release in a concentration-dependent manner, completely inhibiting secretion evoked by 20 mM-glucose at concentrations as low as 0.1 microM in static incubations. In perifusion experiments, both phases of insulin release were equally affected. Monensin (0.1 microM) had no significant effect on glucose oxidation as measured by the generation of 14CO2 from [14C]glucose. Monensin increased the rate of 22Na+ efflux from preloaded islets and net 22Na+ uptake over 30 min, in the absence of changes in islet volume or extracellular space. The ionophore increased the Rb+/K+ permeability of islet cells, as shown by its inhibition of 86Rb+ retention and stimulation of 86Rb+ efflux. At 0.1 microM, monensin abolished glucose-stimulated 45Ca2+ uptake by islets during 5 min incubations, and stimulated 45Ca2+ efflux from preloaded islets perifused with Ca2+-free medium, even in the complete absence of extracellular Na+. Studies of the uptake of 14C-labelled 5,5-dimethyloxazolidine-2,4-dione showed that 0.1 microM-monensin increased net intracellular pH from 7.05 to 7.13. 7 Monensin has widespread, complex, effects on the secretory responses and ion handling by the B cells, which are difficult to interpret in terms solely of actions as a Na+ ionophore.

Project description:The effects of carbon tetrachloride on protein and lipoprotein secretion, and on lipid peroxidation, have been investigated in isolated rat hepatocytes. It was found that although the free-radical scavenger promethazine completely suppressed the increased peroxidation produced by carbon tetrachloride, it had no effect on the inhibitory action of carbon tetrachloride on lipoprotein secretion. In consequence, the latter effect of carbon tetrachloride does not appear to be mediated through a peroxidative stage.

Project description:Protein synthesis in isolated rat hepatocytes, as measured by the incorporation of [14C]-valine at constant specific radioactivity, proceeded at a rate of 0.3-0.5%/h in an unsupplemented medium, i.e. only about one-tenth the rate of protein degradation (4%/h). Leupeptin, which inhibits lysosomal protein degradation (previously found to be 75% of the total degradation in hepatocytes), had no effect on protein synthesis, showing that endogenous protein degradation supplied amino acids in excess of the substrate requirements for protein synthesis. The inhibition of protein synthesis by NH4Cl (another inhibitor of lysosomal protein degradation) as well as the stimulation by a physiological amino acid mixture must therefore represent indirect effects, either on general energy metabolism, or on unknown regulatory processes.

Project description:Insulin-stimulated glycogenesis and insulin degradation were studied simultaneously at 37 degrees C in cultured foetal hepatocytes grown for 2-3 days in the presence of cortisol. Degradation of cell-associated insulin, as measured by trichloroacetic acid precipitation, was significant after 4 min in the presence of 1-3 nM-125I-labelled insulin. This process became maximal (30% of insulin degraded) after 20 min, a time when binding-state conditions were achieved. No insulin-degradative activity was detected in a medium that had been exposed to cells. At steady-state, the appearance of insulin degradation products in the medium was linearly dependent on time (1.5 fmol/min per 10(6) cells at 1nM-125I-labelled insulin). Chloroquine (3-50 microM), bacitracin (0.1-10 mM) and NH4Cl (1-10 mM) inhibited insulin degradation as soon as this became detectable and caused an increase in the association of insulin to hepatocytes after 20 min. Lidocaine and dansylcadaverine had similar effects, whereas N-ethylmaleimide, aprotinin, phenylmethanesulphonyl fluoride and leupeptin were found to be ineffective. Chloroquine, and also bacitracin, at concentrations that inhibited insulin degradation, decreased the insulin-stimulated incorporation of [14C]glucose into glycogen over 2 h. This effect of chloroquine was specific, since it did not modify the basal glycogenesis, or the glycogenic effect of a glucose load in the absence of insulin. It therefore appears that the receptor-mediated insulin degradation (or some associated pathway) is functionally related to the glycogenic effect of insulin in foetal hepatocytes.

Project description:1. Adipocytes isolated from epididymal fat-pads of fed rats were incubated with different concentrations of glucagon, insulin, adrenaline and adenosine deaminase, and the effects of these agents on the ;initial' activity of acetyl-CoA carboxylase in the cells were studied. 2. Glucagon (at concentrations between 0.1 and 10nm) inhibited acetyl-CoA carboxylase activity. Maximal inhibition was approx. 70% of the ;control' activity in the absence of added hormone, and the concentration of hormone required for half-maximal inhibition was 0.3-0.5nm-glucagon. 3. Incubation of cells with adenosine deaminase resulted in a similar inhibition of acetyl-CoA carboxylase activity. Preincubation of adipocytes with adenosine deaminase did not alter either the sensitivity of carboxylase activity to increasing concentrations of glucagon or the maximal extent of inhibition. 4. Adrenaline inhibited acetyl-CoA carboxylase to the same extent as glucagon. Preincubation of the cells with glucagon did not alter the sensitivity of enzyme activity to adrenaline or the degree of maximal inhibition. 5. Insulin activated the enzyme by 70-80% of ;control' activity. Preincubation of the cells with glucagon did not alter the concentration of insulin required to produce half the maximal stimulatory effect (about 12muunits of insulin/ml). The effects of insulin and glucagon appeared to be mediated completely independently, and were approximately quantitatively similar but opposite. These characteristics resulted in the mutual cancellation of the effects of the two hormones when they were both present at equally effective concentrations. 6. The implications of these findings with regard to current concepts about the mechanism of regulation of acetyl-CoA carboxylase and to the regulation of the enzyme in vivo are discussed.

Project description:Autophagy dysfunction is considered as a potential toxic mechanism of nanomaterials. Silica nanoparticles (SiNPs) can induce autophagy, but the specific mechanism involved remains unclear. Therefore, the aim of this study was to confirm the effects of SiNPs on autophagy dysfunction and explore the possible underlying mechanism. In this article, we reported that cell-internalized SiNPs exhibited dose- and time-dependent cytotoxicity in both L-02 and HepG2 cells. Multiple methods verified that SiNPs induced autophagy even at the noncytotoxic level and blocked the autophagic flux at the high-dose level. Notably, SiNPs impaired the lysosomal function through damaging lysosomal ultrastructures, increasing membrane permeability, and downregulating the expression of lysosomal proteases, cathepsin B, as evidenced by transmission electron microscopy, acridine orange staining, quantitative reverse transcription-polymerase chain reaction, and Western blot assays. Collectively, these data concluded that SiNPs inhibited autophagosome degradation via lysosomal impairment in hepatocytes, resulting in autophagy dysfunction. The current study not only discloses a potential mechanism of autophagy dysfunction induced by SiNPs but also provides novel evidence for the study of toxic effect and safety evaluation of SiNPs.