Plasma protein synthesis by isolated rat hepatocytes

A system of preparation of rat hepatocytes with extended viability has been developed to study the role of hormones and other plasma components upon secretory protein synthesis. Hepatocytes maintained in minimal essential medium reduced the levels of all amino acids in the medium except the slowly catabolized amino acids leucine, isoleucine, and valine, which steadily increase as the result of catabolism of liver protein. Although the liver cells catabolize 10-15% of their own protein during a 20-h incubation, the cells continue to secrete protein in a linear fashion throughout the period. The effects of insulin, cortisol, and epinephrine on general protein synthesis, and specifically on fibrinogen and albumin synthesis, have been tested on cells from both normal rats and adrenalectomized rats. Cells from normal animals show preinduction of tyrosine amino transferase (TAT), having at the time of isolation a high level of enzyme which shows only an increase of approximately 60% upon incubation with cortisol. In contrast, cells from adrenalectomized animals initially have a low level of enzyme which increases fourfold over a period of 9 h. The effects of both epinephrine and cortisol on protein synthesis are also much larger in cells from adrenalectomized animals. After a delay of several hours, cortisol increases fibrinogen synthesis sharply, so that at the end of the 20-h incubation, cells treated with hormone have secreted nearly 2.5 times as much fibrinogen as control cells. The effect is specific; cortisol stimulates neither albumin secretion nor intracellular protein synthesis. The combination of cortisol and epinephrine strongly depresses albumin synthesis in both types of cells. Insulin enhances albumin and general protein synthesis but has little effect on fibrinogen synthesis.     

Metallothionein induction in freshly isolated rat hepatocytes

The control of metallothionein (MT) synthesis was investigated in freshly prepared rat hepatocytes in experiments of short-term duration. Viability and metabolic function were maintained in incubations of 6-h duration. MT synthesis was measurable in hepatocytes from fed rats at Zn concentrations down to 1 μM. Zn and dexamethasone induced concentration-dependent increases in the synthesis of MT with maximal increases above the 5-h control of 3.2- and 2.5-fold, respectively. Zn induction of MT was first measurable at 2 h and was inhibited by actinomycin C. Although initial (0 h) MT concentrations in hepatocytes from fasted rats were double those from fed rats, after 6-h incubation in the presence of 50 μM Zn, the fasted rat hepatocytes showed only half the MT concentrations of the fed rat hepatocytes. Glucagon and interleukin-6 (IL-6) were less effective inducers and increased MT synthesis by 28 and 17%, respectively. IL-6 (100 U/mL) was found to have an additive effect on MT synthesis above that of Zn alone (1–50 μM) or Zn plus dexamethasone (1 μM). A supernatant from LPS-stimulated macrophages increased MT synthesis by 40%. The basal MT synthesis was not increased by either tumor necrosis factor-α (TNF-α) or interleukin-1 (IL-1). All incubations were carried out in the presence of RPMI 1640 medium with Hepes (20 mM), bicarbonate (24 mM), and fatty acid-free albumin (FAFA; 0.5% w/v). MT synthesis was also seen using Krebs bicarbonate buffer with glucose (10 mM), Hepes (20 mM), and FAFA (0.5% w/v), and although the level of MT synthesis was less than in RPMI, the increases in concentrations of MT at 5 h were 225, 139, 36 and 20% for Zn, dexamethasone, glucagon, and control, respectively. It is concluded that MT synthesis occurs in freshly prepared hepatocytes and that these cells are responsive to some of the established inducers of MT. This system enables the study of MT synthesis in individual rats in various metabolic and pathological states.     

Inhibition of protein degradation in isolated rat hepatocytes

1. Isolated parenchymal cells were prepared by collagenase perfusion of livers from fed rats that had been previously injected with [³H]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 [³H]leucine into the medium at a rate accounting for the degradation of 4.5% of the labelled cell protein per h. 3. Degradation of [³H]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.     

Amiloride inhibits protein synthesis in isolated rat hepatocytes

The effects of amiloride on Na⁺ ion influx, amino acid transport, protein synthesis and RNA synthesis have been studied in isolated rat hepatocytes. The initial rate of ²²Na⁺ uptake and the amount of ²²Na⁺ taken up at later time points were decreased in hepatocytes incubated in the presence of amiloride. Amiloride inhibited by about 25% the influx of α-methylamino[1?¹⁴C]isobutyric acid, a specific substrate for the A (Alanine preferring) system of neutral amino acid transport. By contrast, the activity of system L (Leucine preferring) was not affected by amiloride. Rates of protein synthesis were determined by using high extracellular concentrations of [¹⁴C]valine in order to maintain a constant amino acid precursor pool. Amiloride inhibited protein synthesis by 85% and had no effect on RNA synthesis. Half-maximal inhibition of protein synthesis occurred with amiloride at about 150 μM. In the absence of Na⁺ in the incubation medium, the rate of protein synthesis was reduced by about 35% and no further inhibition was observed with amiloride. These results suggest that in isolated rat hepatocytes protein synthesis is partially dependent on Na⁺, and that amiloride is an efficient inhibitor of protein synthesis.     

Vanadate inhibits protein degradation in isolated rat hepatocytes

Vanadate (10 mM) strongly inhibited endogenous protein degradation as well as the degradation of an exogenous, endocytosed protein (asialofetuin) in isolated rat hepatocytes. Protein synthesis and cellular viability were unaffected, but changes in cell morphology suggested some interference with cytoskeletal elements. The effect of vanadate was comparable to the effects of several other degradation inhibitors (lysosomotropic amines, leupeptin, vinblastine, amino acids, dimethylaminopurine riboside) known to inhibit the autophagic/lysosomal pathway of protein degradation. Vanadate inhibited proteolysis in a liver homogenate at pH 5, suggesting a direct effect upon the lysosomal proteinases.     

Rates of protein synthesis by hepatocytes isolated from rats of various ages

The rate of total protein synthesis in isolated hepatocytes was determined. The incorporation of L-[³H]valine into protein is linear for at least two hours of incubation and is affected by the concentration of amino acids in the medium. Uptake of valine by hepatocytes from 1.5- and 18-month-old rats was identical and appears to occur by simple passive diffusion. Within five minutes, the specific activities of the intracellular and extracellular valine pools are equivalent. The specific activities of these pools are saturated by 1.6 mM valine and remain constant for 60 minutes of incubation. The rates of protein synthesis by hepatocytes from 1- to 2-month-old rats is 96.8 pmoles of valine per minute per milligram protein. This is comparable to rates of protein synthesis reported for perfused liver and liver in vivo and is approximately 64% higher than the rate of protein synthesis by hepatocytes from 18-month-old rats.     

Inhibition of hormonal induction of tyrosine aminotransferase by polyamines in freshly isolated rat hepatocytes.

We have analysed the effects of natural aliphatic polyamines on hormonal induction of tyrosine aminotransferase (TAT) in suspensions of hepatocytes isolated from adult fed rats. Glucagon or cyclic AMP derivatives (dibutyryl and 8-bromo) used alone caused a 4-5 fold increase in enzyme activity within 4h. This effect was independent of glucocorticoids, which also increased TAT activity (2.5-fold); when combined, the effects of the two inducers were additive. Spermine and putrescine totally inhibited the hormonally-mediated increase in enzyme activity when added at the onset of incubation with the inducers. Furthermore, polyamines could block the hormonal effect at any time during the course of TAT induction, with, however, a 30 min lag period, suggesting that they must enter the cells. Hepatocytes were indeed shown to take up spermine. At low external concentrations (less than 50 microM), an Na+-dependent, saturable and concentrative mechanism was predominant; at high concentrations (greater than 0.5 mM) transport occurred mainly through a non-saturable, Na+-independent mechanism, building up intracellular concentrations slightly lower than those in the medium. Dose-dependence analysis of the polyamine effect on enzyme induction indicated that half-maximal and maximal inhibition occurred with 0.75 mM- and 2.5 mM-spermine respectively, whereas 2.5mM- and 7.5 mM-putrescine were required respectively to obtain similar effects. Spermidine was much less effective and cadaverine had virtually no effect. None of the polyamines affected the rate of decay of TAT, nor did they directly or indirectly cause enzyme inactivation, indicating that a post-translational modification was unlikely to account for the polyamine effects. Similarly, these effects could not be ascribed to a non-specific inhibition of overall protein synthesis. We conclude that, in hepatocytes, polyamines (or their metabolites) directly interfere with one or several steps controlled by hormones in the synthesis of tyrosine aminotransferase.     

Plasma membrane specialization and intracellular polarity of freshly isolated rat hepatocytes

It was investigated whether rat hepatocytes maintain their plasma membrane specialization (sinusoidal, lateral and bile canalicular sites) and their intracellular polarity (peribiliary region, rich in lysosomes and poor in mitochondria) after isolation. The morphology of the hepatocytes and the cytochemical localization of marker enzymes for the bile canalicular membrane (alkaline phosphatase, adenosine triphosphatase and 5' nucleotidase), for the lysosomes (acid phosphatase) and for the mitochondria (beta-hydroxybutyrate dehydrogenase and succinate dehydrogenase) were studied in situ and directly after isolation using both light and electron microscopy. The morphology of the cells and the cytochemical activity of acid phosphatase, succinate dehydrogenase and beta-hydroxybutyrate dehydrogenase showed that in isolated cells, as in situ, the lysosomes were concentrated in bands, devoid of mitochondria. Unlike in situ the reaction product of alkaline phosphatase, adenosine triphosphatase and 5'nucleotidase was evenly distributed along the entire plasma membrane of the isolated cells. Morphologically, no tight or gap junctions or desmosomes could be detected in the isolated cells, while the plasma membrane appeared to be homogeneously covered with uniform microvilli. In conclusion it can be stated that during isolation the hepatocytes loose their distinct plasma membrane specialization, but maintain their peribiliary region rich in lysosomes and poor in mitochondria.     

Glucagon binding by isolated chick hepatocytes

Studies have been made on the binding of 125I-glucagon by isolated chick hepatocytes. It was shown that pH and temperature dependence of the binding does not differ from that in rat hepatocytes. Optimum binding was observed at pH 7.6, the rate of binding being higher at 37 degrees C as compared to that at 20 degrees C, although the binding capacity increased with the decrease in the temperature. Unlabeled glucagon was able to compete with 125I-glucagon at the binding sites. Scatchard plot was found to be curvilinear revealing two classes of the binding sites with Kd values 10(-9) and 10(-7) M at temperatures 20 and 37 degrees C correspondingly. Earlier studies revealed in rats the binding sites of a sole class with Kd value 10(-9) M. Preincubation of cells with native glucagon results in changes of labeled glucagon binding, the effect being proportional to the concentration of native glucagon. Preincubation effect was observed at 37 degrees C, being absent at 20 degrees C; the effect was due to the decrease in the number of both high and low affinity binding sites. The presence of down-regulation of glucagon receptors in chick hepatocytes is suggested.     

Zinc uptake by isolated rat hepatocytes

Isolated rat hepatocytes were used to investigate the uptake of zinc at early exposure times. Hepatocytes were incubated with ⁶⁵Zn (1–500 μM) and samples were withdrawn at times ranging from 25 s to 60 min. A biphasic pattern of uptake was observed with a rapid first phase of uptake followed by a slower second phase. The relationship between velocity of uptake and substrate concentration for the first phase was nonlinear, while that of the second phase was linear. The presence of 10 μM cadmium produced a decrease in the velocity of uptake of only the first phase. This suggests that the first phase is at least partly carrier mediated, while there is no indication of involvement of a carrier in the second phase. KCN (1 mM) and carbonyl cyanide m-chlorophenylhydrazone (2 μM), did not cause any change in the uptake of ⁶⁵Zn (1 μM), which suggests that there is no active component in the uptake of zinc.     

Enzyme-induced aziridine formation by isolated hepatocytes

The metabolism of 2-bromoethylaminonaphthoquinone in hepatocytes isolated from rats was studied. This compound was chemically inert in the reaction system used. However, in buffer solution containing isolated hepatocytes, it was gradually converted into aziridinylnaphthoquinone. Under the same reaction conditions, 4-chlorobutylaminonaphthoquinone also gave the cyclization products, pyrrolidinylnaphthoquinone. Cellular GSH decreased in both reactions.     

Insulin enhances protein phosphorylation in isolated hepatocytes by inhibiting an amiloride sensitive phosphatase

The effects of amiloride on basal and hormone-stimulated protein phosphorylation were studied in isolated rat hepatocytes labeled with ³²P-phosphate. Two types of effect on basal phosphorylation were detected: 1. an increase in labeling of two proteins with molecular weights 93,000 and 18,000; 2. a decrease in labeling of proteins with molecular weights 46,000, 34,000, 22,000 and 13,000. All these effects were dose-dependent (maximum with 0,8-to 1 mM) and reached a maximum after 30 to 40 min treatment of the cells with the drug. Amiloride inhibited specifically all insulin effects whereas glucagon specific effects were largely unaffected. In pulse-chase experiments, amiloride increased and insulin decreased the rate of dephosphorylation of the same proteins (Mr 46,000, 34,000 and 22,000). The data support the conclusion that in hepatocytes insulin increases the degree of phosphorylation of proteins by inhibiting an amiloride-sensitive phosphatase.     

Hormonal induction of alpha2u-globulin synthesis in isolated rat hepatocytes.

Hepatocytes freshly prepared with collagenase synthesize alpha 2u-globulin and other hepatic proteins in vitro at approximately the same rate throughout 30 h of incubation. The newly synthesized proteins are efficiently secreted into the medium throughout this period. That the secretion of proteins by hepatocytes is not due to cell leakage is shown by the fact that 30 micrometer colchicine prevents the appearance of labeled alpha2u-globulin and other proteins in the medium. Hepatocytes isolated from animals in different endocrine states synthesize alpha2u-globulin in vitro at rates consistent with the hormonal effects upon its in vivo biosynthesis. In vitro addition of androgens to hepatocytes isolated from castrated male rats evokes an elevation of general protein synthesis in these hepatocytes. Glucocorticoids, added in vitro, specifically induce and elevated rate of alpha2u-globulin synthesis.     

Inhibition of autophagic vacuole formation and protein degradation by amino acids in isolated hepatocytes

An amino acid mixture, specifically developed to suppress endogenous protein degradation in isolated hepatocytes, inhibited lysosornal (propylamine-sensitive) protein degradation by 70–75% and reduced the cytoplasmic volume fraction of the autophagic/lysosomal compartment to a similar extent. Incubation with the amino acid mixture for 1 h reduced the subcompartment of early autophagic vacuoles by 95%. These results support the hypothesis that autophagy is the major route of delivery of endogenous proteins to the lysosomes, and that amino acids exert their regulatory function on protein degradation by controlling the sequestration step of autophagy.     

Aminooxyacetate inhibits gluconeogenesis by isolated chicken hepatocytes

Although the pathway for glucose synthesis from lactate in avian liver is not thought to involve transamination steps, inhibitors of transamination (aminooxyacetate and L-2-amino-4-methoxy-trans-3-butenoic acid) block lactate gluconeogenesis by isolated chicken hepatocytes. Inhibition of glucose synthesis from lactate by aminooxyacetate is accompanied by a large increase in the lactate-to-pyruvate ratio. Oleate largely relieves inhibition by aminooxyacetate and lowers the lactate-to-pyruvate ratio. In parallel studies with rat hepatocytes, oleate did not overcome aminooxyacetate inhibition of glucose synthesis. The ratios of lactate used to glucose formed were greater than 2 with both rat and chicken hepatocytes, were increased by aminooxyacetate, and were restored toward 2 by oleate. Thus, in the absence of oleate, lactate is oxidized to provide the energy needed to meet the metabolic demand of chicken hepatocytes. Excess cytosolic reducing equivalents generated by the oxidation of lactate to pyruvate are transferred from the cytosol to the mitosol by the malate-aspartate shuttle. Aminooxyacetate inhibits the shuttle and, consequently, glucose synthesis for want of pyruvate.     

Free fatty-acid uptake by isolated rat hepatocytes

In isolated rat hepatocytes, the rate of palmitic acid binding and uptake is directly related to the concentration of free fatty acid (FFA) in the medium. After their entry into the cell, FFA are immediately incorporated into cellular phospholipids and triglycerides and no accumulation of free fatty acids can be demonstrated inside the cell. The rate of free fatty-acid uptake remains unchanged after incubation in a 2 mM KCN containing medium, indicating that in the range of fatty-acid concentrations used in this study, this phenomenon does not require energy.     

Studies on gluconeogenesis and protein synthesis in isolated hepatocytes.

Glucose production was studied in isolated hepatocytes using various substrates and with increasing substrate concentrations (0-10 mM). Fructose was the best gluconeogenic substrate while other substrates studied stimulated net glucose production in the following decreasing order: lactate, pyruvate, glycerol, galactose, alanine, and succinate. Studies on oxygen consumption showed that endogenous respiration was linear for 60 min and was not altered by extracellular calcium. Studies on the incorporation of 14C-leucine into protein was linear for only 3-4 hr in cells containing low glycogen. However, cells containing high glycogen incorporated 14C-leucine into protein linearly for 8-10 hr. About 3 mg of protein per g per hr was synthesized by isolated cells when incubated for 4 hr with amino acids mixture, glucose, lactate, and insulin.