Receptor-mediated insulin degradation and insulin-stimulated glycogenesis in cultured foetal hepatocytes.

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.     

Cell-surface insulin receptor cycling and its implication in the glycogenic response in cultured foetal hepatocytes.

The insulin-receptor cycle was investigated in cultured foetal rat hepatocytes by determining the variations in insulin-binding sites at the cell surface after short exposure to the hormone. Binding of 125I-insulin was measured at 4 degrees C after dissociation of prebound native insulin. Two protocols were used: exchange binding assay and binding after acid treatment; both gave the same results. Cell-surface 125I-insulin-receptor binding decreased sharply (by 40%) during the first 5 min of 10 nM-insulin exposure (t1/2 = 2 min) and remained practically constant thereafter; subsequent removal of the hormone restored the initial binding within 10 min. This fall-rise sequence corresponded to variations in the number of insulin receptors at the cell surface, with no detectable change in receptor affinity. The reversible translocation of insulin receptors from the cell surface to a compartment not accessible to insulin at 4 degrees C was hormone-concentration- and temperature-dependent. SDS/polyacrylamide-gel electrophoresis after cross-linking of bound 125I-insulin to cell-surface proteins with disuccinimidyl suberate showed that these variations were not associated with changes in Mr of binding components, in particular for the major labelled band of Mr 130,000. The insulin-receptor cycle could be repeated after intermittent exposure to insulin. Continuous or intermittent exposure to the hormone gave a similar glycogenic response, contrary to the partial effect of a unique short (5-20 min) exposure. A relationship could be established between the repetitive character of the rapid insulin-receptor cycle and the maximal expression of the biological effect in cultured foetal hepatocytes.     

Ontogeny of the glucocorticoid receptor and its relationship to tyrosine aminotransferase induction in cultured foetal hepatocytes.

The glucocorticoid receptor activity that can be detected in the liver from 15-day foetal rats would appear to be associated with the haemopoietic cells. In hepatocytes, purified by culture for 1-2 days from 15-day foetal rats, the glucocorticoid receptor activity is low and dexamethasone does not induce the enzyme tyrosine aminotransferase. If culture is continued both receptor activity and steroid responsiveness are acquired. Cultured hepatocytes from 19-day foetal liver contain receptor from the first day of culture and, furthermore, the subsequent level of response to glucocorticoids is directly correlated with the actual receptor concentration. It would appear that the glucocorticoid receptor is not acquired by hepatocytes until after 18 days of gestation. Nevertheless, the fact that bromodeoxyuridine has no effect on the rate of accumulation of receptor in hepatocytes suggests that the differentiative event leading to the subsequent appearance of the receptor has already occurred before day 15 of gestation. However, the acquisition of the receptor would appear to be dependent on mitosis as cytosine arabinoside can inhibit the process.     

Reutilization of insulin receptor and hormonal response in cultured foetal hepatocytes: the effects of chloroquine and vinblastine

The effects of chloroquine and vinblastine (10-100 microM) on insulin degradation and biological action were studied in cultured foetal rat hepatocytes. Insulin degradation, as measured by the release of trichloroacetic acid-soluble radioactivity from 125I-insulin into the medium, was strictly cell-associated, saturable with respect to insulin concentrations and linearly related to the amount of cell-associated hormone. The maximal rate of insulin degradation was 4,700 molecules/min per cell, and its KM about 5 nM. Thus, insulin receptors (30,000 sites/cell; half-life close to 13 hr) must be reutilized 450-fold before being degraded with an average time of reutilization inferior to 10 min. In the presence of 70 microM chloroquine or 100 microM vinblastine, insulin degradation was inhibited by 80% and the amount of cell-associated hormone enhanced 2-3-fold. Nearly total inhibition of insulin-stimulated glycogenesis was obtained with 70 microM chloroquine and 45 microM vinblastine. When hepatocytes were preincubated with chloroquine or vinblastine, insulin binding remained high for up to 4 hr, then progressively decreased thereafter. The addition of 10 nM native insulin during preincubation with the drugs resulted in an earlier and more pronounced decrease in insulin binding, whereas native insulin alone did not induce any change. Both the inhibition of insulin degradation and onset of receptor down-regulation suggest a drug-induced impairment in the receptor reutilization. This defect is correlated to a loss of the glycogenic effect of insulin in cultured foetal rat hepatocytes.     

Uncoupling between the insulin-receptor cycle and the cellular degradation of the hormone in cultured foetal hepatocytes. Effect of drugs and temperature that inhibit insulin degradation.

Sequential changes in the numbers of cell-surface receptors induced by a transitory exposure to insulin in cultured 18-day foetal-rat hepatocytes were investigated in the presence of drugs and at a temperature of 22 degrees C, which inhibit cellular insulin degradation. Chloroquine (70 microM) and monensin (3 microM) did not greatly change the initial rate of internalization of cell-surface receptor sites after exposure to 10 nM-insulin, but led to a steady state after 20 min, which represented 40% of the initial binding, compared with 5 min and 60% in the absence of the drug. Moreover, these drugs strongly decreased the proportion of receptor sites recovered at the cell surface after subsequent removal of the hormone. They were ineffective when insulin was not present. The removal of monensin together with the hormone allowed partial restoration of cell-surface receptor sites and degradation of cell-associated insulin to start again at the initial speed, indicating a reversible effect of the drug. During this phase, the drug concentration-dependence for the two effects showed that receptor recycling was restored with concentrations of monensin not as low as for insulin degradation. The effect of vinblastine (50-100 microM) was similar to that of chloroquine and monensin, whereas no modification in the internalization and recovery processes was observed in the presence of bacitracin concentrations (1-3 mM) that inhibit insulin degradation by 70%. A temperature of 22 degrees C did not prevent the receptor internalization, but had a slowing effect on the recycling process, which appeared to vary in experiments where insulin degradation remained inhibited. The present study shows that the process of insulin degradation mediated by receptor endocytosis is not a prerequisite for insulin-receptor recycling in cultured foetal hepatocytes.     

Dexamethasone stimulates insulin receptor synthesis in cultured rat hepatocytes

The ability of the glucocorticoid dexamethasone to modulate the insulin receptor was examined directly in primary cultures of hepatocytes prepared from adult male rats. Hepatocytes were cultured in a defined medium in the presence and absence of dexamethasone, 0.1 microM. The exposure of hepatocytes to dexamethasone resulted in a time-dependent (steady state by 32 h) increase in insulin binding in both intact hepatocytes and Triton X-100-soluble extracts (total insulin receptor content). The enhanced insulin binding found in soluble extracts of dexamethasone-treated hepatocytes was the result of an increase in insulin receptor number without a change in receptor affinity. In order to assess the mechanism by which dexamethasone "up-regulates" the insulin receptor, the heavy isotope density-shift technique was used to analyze insulin receptor turnover in control and dexamethasone-treated hepatocytes. Hepatocytes were initially cultured for 32 h in standard culture media containing only "light" (14C, 12C, 1H) amino acids. In hepatocytes exposed to dexamethasone, a 417% increase in insulin binding in Triton X-100-soluble extracts was observed. After 32 h, when steady state binding is achieved in dexamethasone-treated cultures, parallel cultures of hepatocytes incubated in the absence and presence of dexamethasone were washed and subsequently cultured in media containing "heavy" amino acids (15N, 13C, 2H). The time-dependent disappearance of light insulin receptor (receptor degradation) and appearance of heavy insulin receptor (receptor synthesis) were monitored using CsCl gradients to resolve the two density species of receptor. At steady state, the rate of receptor synthesis (k8) was 2.94 and 0.62 fmol of insulin bound h-1 in dexamethasone-treated and control hepatocytes, respectively. In contrast to this large increase in the rate of receptor synthesis observed in dexamethasone-treated cells, the first order rate constant for decay (k d) was the same in dexamethasone-treated (0.074 h-1) and in control (0.077 h-1) hepatocytes. We therefore conclude that glucocorticoid-induced up-regulation of the insulin receptor in the liver is due to stimulation of insulin receptor synthesis.     

Differences between glucose and insulin stimulation of glycogenesis in cultured fetal hepatocytes

The glycogenic effects of a glucose load (15 mM) and/or insulin (10 nM) were studied in 18-day-old fetal rat hepatocytes after 2 days of culture when medium contained 4 mM glucose. A glucose load led to a stimulation of [¹⁴C]glucose glycogen labelling (20 min) earlier than with insulin (30–40 min); maximal stimulations were 3-fold after 1 h for the glucose load and 5-fold after 2–3 h for insulin. Simultaneous addition of the two agents produced synergic effects. When insulin was added 4 h after a glucose load (or vice versa), a second glycogenic response was elicited: a further addition of the same glycogenic agent was ineffective. The early glycogenic effects (up to 2 h) also occurred in the presence of 10 μM cycloheximide, with, however, some decrease of insulin stimulation. The contribution of medium glucose to the glycogen formed for 2 days (67% in the absence of glycogenic agent) was clearly enhanced by a glucose load and to a lesser degree by insulin after a 4-h exposure (83 and 71%, respectively). This was accompanied by a related modification of the participation of glucogenic precursors such as fructose and galactose. Thus, acute glycogenic response to glucose and insulin appeared both synergic and independent, and quite different in several aspects in cultured fetal hepatocytes.     

Intermediate peptides of insulin degradation in liver and cultured hepatocytes of rats

1. Bestatin, a microbial aminopeptidase inhibitor, induced accumulation of low-molecular weight intermediate peptides of insulin degradation in liver of rats in vivo and in primary cultured rat hepatocytes. However, bestatin did not affect the association and internalization of the hormone into hepatic cells. 2. Results of the HPLC analyses showed that the intermediate peptides of insulin degradation are small ones and specifically accumulate only in the presence of bestatin. 3. The above results, together with those employing other protease inhibitors, show that cytosolic bestatin-sensitive protease(s), trypsin-like protease(s) and thiol protease(s) play an important role in the intracellular degradation process of insulin.     

Differences in the accessibility of the beta-adrenergic receptor in isolated hepatocytes from foetal and adult rats.

Beta-receptor number (measured by [3H]-CGP 12 177 binding) and beta-adrenergic response (measured by isoproterenol stimulated glucose liberation and isoproterenol stimulated adenylate cyclase activity) were compared in hepatocytes isolated from foetal (on day 22 of gestation), adult female and adult male rats. Beta-receptor numbers in crude membrane preparations of hepatocytes from adult female and adult male rats were found to be nearly equal (15.5 and 15.1 fmol/mg), but in crude membrane preparations of foetal rats beta-adrenergic receptor number was significantly higher (34.3 fmol/mg). Determination of number of beta-adrenergic surface receptors of intact hepatocytes showed relative high values in foetal rats (about 22,000/cell) and adult female rats (about 20,000/cell), but in male rats the number was less (about 6500/cell). Glucose liberation was stimulated by isoproterenol to the same extent in hepatocytes isolated from adult female and foetal rats (about 150% over basal), whereas no effect was found in hepatocytes isolated from adult male rats. Dose-response curves showed that in foetal rat hepatocytes glucose release was already increased by 10(-8) M isoproterenol, whereas in female rat hepatocytes at least 10(-6) M isoproterenol was required. Adenylate cyclase was stimulated by isoproterenol in lysates of hepatocytes from adult female rats by about 180% and from foetal rats by about 250%. No effects were observed using lysates of hepatocytes from adult male rats. We interpret the observed differences of beta-adrenergic responses between adult female and male rats as being primarily caused by different accessibility of the beta-receptor to the beta-agonist isoproterenol in intact hepatocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pathways of glycogen synthesis from glucose during the glycogenic response to insulin in cultured foetal hepatocytes.

The pathways of glycogen synthesis from glucose were studied using double-isotope procedures in 18-day cultured foetal-rat hepatocytes in which glycogenesis is strongly stimulated by insulin. When the medium containing 4 mM-glucose was supplemented with [2-3H,U-14C]glucose or [3-3H,U-14C]glucose, the ratios of 3H/14C in glycogen relative to that in glucose were 0.23 +/- 0.04 (n = 6) and 0.63 +/- 0.09 (n = 8) respectively after 2 h. This indicates that more than 75% of glucose was first metabolized to fructose 6-phosphate, whereas 40% reached the step of the triose phosphates prior to incorporation into glycogen. The stimulatory effect of 10 nM-insulin on glycogenesis (4-fold) was accompanied by a significant increase in the (3H/14C in glycogen)/(3H/14C in glucose) ratio with 3H in the C-2 position (0.29 +/- 0.05, n = 6, P less than 0.001) or in the C-3 position (0.68 +/- 0.09, n = 8, P less than 0.01) of glucose, whereas the effect of a 12 mM-glucose load (3.5-fold) did not alter these ratios. Fructose (4 mM) displaced [U-14C]glucose during labelling of glycogen in the presence and absence of insulin by 50 and 20% respectively, and produced under both conditions a similar increase (45%) in the (3H/14C in glycogen)/(3H/14C in glucose) ratio when 3H was in the C-2 position. 3-Mercaptopicolinate (1 mM), an inhibitor of gluconeogenesis from lactate/pyruvate, further decreased the already poor labelling of glycogen from [U-14C]alanine, whereas it increased both glycogen content and incorporation of label from [U-14C]serine and [U-14C]glucose with no effect on the relative 3H/14C ratios in glycogen and glucose with 3H in the C-3 position of glucose. These results indicate that an alternative pathway in addition to direct glucose incorporation is involved in glycogen synthesis in cultured foetal hepatocytes, but that insulin preferentially favours the classical direct route. The alternative foetal pathway does not require gluconeogenesis from pyruvate-derived metabolites, contrary to the situation in the adult liver.     

Regulatory relation between insulin receptor and its functional responses in primary cultured hepatocytes of adult rats

The relation between changes of insulin receptor and various metabolic responses were studied in adult rat hepatocytes in primary culture. In cells cultured for 3 h without insulin, the number of high affinity sites and the dissociation constant (Kd) of insulin receptor, determined from a Scatchard plot, were 1.05 x 10(5) sites/cell and 1.5 x 10(-9) M, respectively. The receptor number increased 2-fold, but the Kd value remained constant during 2-days culture in insulin-free medium (up-regulation). Addition of dexamethasone (Dex), growth hormone, glucagon or triiodothyronine did not change the number of insulin receptors or the Kd value. In contrast, 1-day culture in insulin (1 x 10(-7) M) medium decreased the receptor number by half (down-regulation) without change of the Kd value. Short-term responses of glycogenesis, amino acid transport and lipogenesis by insulin increased as the receptor number increased. In these cases, the sensitivity to insulin (Ka: half dose for the maximum response) did not change in cells with different receptor numbers, but the maximum response changed. These results show that hepatocytes, unlike adipocytes, do not have spare receptors of insulin. During down-regulation, the receptor number decreased by only half, but the insulin responses were lost almost completely. The receptor number returned to the normal level after culture in insulin-free medium for 12 h, but recovery of the responses took longer, suggesting that for the insulin response not only change of receptor number, but also other regulatory mechanisms for post-receptor processes, such as desensitization, are involved.     

Glucocorticoid regulation of chloroquine nonsensitive insulin degradation in cultured fetal rat hepatocytes

The influence of cortisol and other culture conditions on insulin degradation by the chloroquine-sensitive pathway and the chloroquine-nonsensitive pathway (CNP) was investigated in fetal rat hepatocytes during 3 days of culture. The proportions of the chloroquine nonsensitive release of 125I-insulin degradation products into the conditioned medium/h increased from the 1st to the 3rd day of culture, i.e. from 19 to 50% by cells grown in the presence of cortisol and from 17 to 82% by those grown in the absence of cortisol. Replacement of the conditioned medium with the respective fresh medium dramatically enhanced cellular insulin degradation by CNP, i.e. from 22 to 58%, and 19 to 85% in cells grown for 2 days in the presence and absence of cortisol, respectively. Thus, the conditioned medium contained some factor(s) that inhibited CNP. Therefore, we used the inhibited insulin and alpha-casein degradation by papain in vitro as an assay to investigate the nature of the putative anti-(insulin) protease. Cycloheximide completely prevented the appearance of anti-papain activity in the medium. Conditioned medium obtained from cells grown in the presence of cortisol contained about 2-fold more anti-papain activity than the medium that was obtained in the absence of the steroid. The release of anti-papain activity also declined with time from 1 to 3 days of culture and showed an inverse relationship with the magnitude of cellular insulin degradation by CNP. The inhibition of papain-mediated insulin degradation by the anti-(insulin) protease was noncompetitive. The anti-(insulin) protease was nondialyzable (up to the 10-kDa exclusion limit) and inactivated by heat treatment at 50 degrees C for 30 min. These results suggest that fetal hepatocytes synthesize and secrete a glucocorticoid-regulated heat-labile low molecular mass (less than 25 kDa) anti-(insulin) protease, which may contribute to the suppression of insulin degradation caused by the enzymes involved in CNP.     

Hormonal regulation of two urea-cycle enzymes in cultured foetal hepatocytes.

Foetal-rat hepatocytes were cultured in primary monolayer culture, and activity changes of argininosuccinate synthetase (ASS, EC 6.3.4.5) and argininosuccinase (ASL, EC 4.3.2.1) were followed under defined hormone conditions. In hormone-free medium, cultured cells maintained the enzyme activities at values equal to those of freshly isolated cells for at least 3 days. Continuous addition of dexamethasone produced the development of the two enzyme activities, but only after the first 20h of culture. Under these conditions, urea production by the foetal hepatocytes was concomitantly increased in the culture medium. Pretreatment with dexamethasone for 20h was sufficient to produce the development of ASL activity within the 2 following days. Introduced alone, glucagon induced an increase of ASL activity, but did not affect the ASS activity. The most powerful stimulation of ASS and ASL could be observed in cultured hepatocytes if glucagon and dexamethasone were added simultaneously or sequentially. These results indicated that the development of the receptor complex for the induction of urea-cycle enzymes appears early before birth and established that glucocorticoids amplify the glucagon stimulation of these enzyme activities during foetal life.     

Role of dexamethasone and insulin on the development of the five urea-cycle enzymes in cultured rat foetal hepatocytes.

The activity changes of the urea-cycle enzymes were monitored in cultured foetal hepatocytes after dexamethasone and insulin treatments. Addition of dexamethasone induced the development of carbamoyl-phosphate synthetase, argininosuccinate synthetase, argininosuccinase and arginase activities as soon as day 16.5 of gestation. When insulin was added together with dexamethasone, it markedly inhibited the steroid-induced increase in carbamoyl-phosphate synthetase, argininosuccinate synthetase and argininosuccinase activities.     

Regulation of RNA degradation in cultured rat hepatocytes: Effects of specific amino acids and insulin

The regulation of RNA degradation by specific amino acids and insulin was investigated in cultured rat hepatocytes from fed rats previously injected in vivo with [6-¹⁴C]orotic acid. The effects of three groups of amino acids were compared to those of a complete amino acid mixture. The first one consisted of the eight amino acids (leucine, proline, glutamine, histidine, phenylalanine, tyrosine, methionine, tryptophan) previously found to be particularly effective in the control of proteolysis. The two other groups were defined from our study with single additions of amino acids, one consisting of proline, asparagine, glutamine, alanine, phenylalanine, and leucine and the other including the latter group with serine, histidine, and tyrosine. The results showed that these three groups were able to strongly inhibit deprivation-induced RNA breakdown at one and ten times normal plasma concentrations but to a lower extent than the complete amino acid mixture. Six amino acids (proline, asparagine, glutamine, alanine, phenylalanine, leucine) inhibited individually RNA degradation by more than 20%. However, the deletions of proline, asparagine, glutamine, or alanine from the group of these six amino acids were not followed by a loss of inhibitory effect. On the contrary, an important loss of inhibition was observed when leucine and phenylalanine were deleted. Furthermore, only these two amino acids exhibited an additive inhibitory effect. Thus leucine and phenylalanine could be considered as important inhibitors of RNA breakdown in cultured rat hepatocytes. Finally, insulin which had no significant effect on RNA degradation in the absence of amino acids, was able to potentiate the inhibitory effect of different amino acid groups. © 1993 Wiley-Liss, Inc.     

Vanadate down-regulates cell surface insulin and growth hormone receptors and inhibits insulin receptor degradation in cultured human lymphocytes

Insulin is able to down-regulate its specific cell surface receptor in cultured human lymphocytes. The effect of vanadate, a known insulinomimetic agent, was examined to determine whether it could mimic insulin to down-regulate the insulin receptor. Exposure of cultured human lymphocytes (IM-9) to vanadate (0-200 microM) resulted in a time- and dose-dependent decrease in cell surface insulin receptors to 60% of control, while insulin (100 nM) down-regulated to 40%. The vanadate effect, in contrast to the rapid effect of insulin, was slow to develop (4-6 h). Surface receptor recovery after 18 h exposure was rapid after vanadate removal (20 min), but it required hours after insulin suggesting the presence of an intracellular (cryptic) pool of receptors after vanadate treatment. Insulin binding to Triton X-100-solubilized whole cells after 18 h treatment revealed that total cell receptors had decreased to 50% of control after insulin but increased to 120 and 189% of control after 100 and 200 microM vanadate, respectively. Furthermore, vanadate inhibited the insulin-mediated loss of total cell receptors from 50 to 28%. Removal of cell surface receptors by trypsin before cell solubilization revealed that 100 microM vanadate increased insulin binding to 321% of control indicating an accumulation of intracellular receptors. Labeling of cell surface proteins with Na125I and lactoperoxidase followed by immunoprecipitation of solubilized receptors with anti-receptor antibody after incubation for various times up to 20 h and quantitation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that, while insulin shortened t1/2 from 7.3 to 5.3 h, vanadate prolonged receptor t1/2 to 14 h. No effect of vanadate was detected on insulin receptor tyrosine kinase activity with up to 4 h incubation at the vanadate concentrations used in this study. Furthermore, human growth hormone surface receptors were similarly down-regulated by vanadate. We conclude that 1) vanadate has an apparent insulin-like effect to down-regulate cell surface insulin receptors in cultured human lymphocytes; 2) in contrast to insulin-induced down-regulation which is associated with receptor degradation vanadate causes an accumulation of intracellular (cryptic) receptors and inhibits insulin receptor degradation; and 3) these effects of vanadate may be exerted on other cell surface receptors.     

Insulin antagonism of glucocorticoid induction of tyrosine aminotransferase in cultured foetal hepatocytes

Polyadenylated RNA from developing Artemia salina cysts was fractionated by centrifugation through a sucrose gradient containing methylmercuric hydroxide (CH3HgOH). Aliquots of each fraction were directly added to a rabbit reticulocyte lysate to program protein synthesis in vitro. The translation products were assayed for eukaryotic elongation factor Tu (eEF-Tu) by immunoprecipitation with an antibody raised in rabbits and purified by affinity chromatography. The immunoprecipitated radioactivity was analyzed by polyacrylamide gel electrophoresis in the presence of sodium dodecylsulphate. Sequences coding for eEF-Tu sediment in the 20-S region of the gradient and form a major component of the poly(A)-containing RNA. The mRNA of the 20-S region, comprising about 10% of the poly(a)-containing RNA fractionated on the gradient, has been translated in vitro and 30% of the translation products represent immunoprecipitable eEF-Tu protein chains with an Mr of 50000.