Interferon-alpha down-regulates insulin receptors in lymphoblastoid (Daudi) cells. Relationship to inhibition of cell proliferation

The Daudi line of human lymphoblastoid cells requires insulin and transferrin for growth in serum-free medium and is highly sensitive to the inhibitory effect of human leukocyte interferon (IFN-alpha) on cell proliferation. A variant subline of Daudi cells, which is resistant to the antiproliferative action of IFN-alpha, also has been grown in serum-free medium containing insulin and transferrin. The proliferation of IFN-sensitive and -resistant Daudi cells is dependent on the occupancy of insulin receptors, with optimal cell proliferation observed at high receptor occupancy (nearly 100%). No evidence was found for receptors for insulin-like growth factor I on Daudi cells. IFN treatment of IFN-sensitive cells decreased the capacity of the cells to bind 125I-insulin. The altered binding capacity was due to diminished specific, lower affinity insulin binding, as detected at high 125I-insulin concentrations. Higher affinity insulin binding was not altered by IFN. Insulin binding was also reduced in detergent-solubilized extracts from IFN-treated sensitive Daudi cells and the magnitude of the effect was comparable to that observed in intact cells. This indicates that the total number of insulin binding sites (surface + internal) is decreased in IFN-treated sensitive cells. Insulin binding to IFN-sensitive cells decreased linearly with time between 6 and 48 h from the addition of IFN. The effect on lower affinity insulin binding developed more rapidly than the inhibitory effect of IFN on cell proliferation. The insulin-binding capacity of Daudi cells resistant to the antiproliferative effect of IFN was unaffected by IFN, despite the fact that these cells contain as many cell surface IFN receptors as sensitive cells. These observations raise the possibility that lower affinity insulin binding is important in the growth-promoting actions of insulin.     

Thermal sensitivity and resistance of insulin-receptor binding in thermotolerant cells

Cells may be made extremely resistant to elevated temperatures (thermotolerant) by a mild heat shock a few hours prior to more rigorous heating. In the present report, we show that a single cellular process - insulin binding to its receptor (in HA-1 Chinese hamster ovary cells) - may be made similarly heat-resistant. Heat resistance, whether expressed as cell survival or insulin binding, had similar dose-response characteristics, showing maximum resistance after 30 min at 43 degrees C. The processes had similar induction kinetics (2-6 h) and decayed over a similar time-course (100 h) after 43 degrees C, 30 min preheating. Thermal resistance of insulin binding was induced only when residual receptor loss (due to heating) occurred. Also, decay of resistance was closely correlated with recovery of insulin binding capacity. There thus appeared to be an inverse relationship between receptor number and the degree of heat resistance of both receptors and whole cells. (Scatchard analysis indicated that decreased insulin binding was due to receptor loss, not affinity decrease.) Whether the insulin receptor has a direct role in the mediation of cell killing or whether it passively reflects the state of the whole cell is not clear. However, identification of the receptor as an entity specifically protected in the thermotolerant cells may permit examination of the expression of thermotolerance at the molecular level.     

Effect of serum on heat response of synchronized mouse neuroblastoma cells: protection of cell cycle progression, protein synthesis and survival

The effect of serum and temperature elevation on proliferation has been studied in synchronized mouse neuroblastoma (Neuro-2A) cells. The effects of serum were studied on the induction of (a) mitotic delay due to a non-lethal heat treatment (30 min at 42.7 degrees C) and (b) the loss of colony-forming capacity after a more extensive heat treatment (45 min at 44 degrees C or a continuous 42.7 degrees C heat treatment). The following results were obtained. Under conditions of serum depletion, cell cycle extension of heated G1 phase cells was more than that of heated G2 phase cells. Serum protected against heat-induced alterations of cell cycle progression in G1- but not in G2 phase cells. This effect of serum could be mimicked by a supplement to the medium of human transferrin, bovine pancreas insulin and selenium, and was correlated with protection of protein synthesis. Serum also affected heat-induced cell killing. Under conditions of serum depletion, G1 phase cells were more resistant to heat compared to G2 cells. The presence of serum during heat treatment further increased the thermoresistance of G1 phase cells, but did not affect sensitivity of G2 phase cells. This effect of serum could not be mimicked by a supplement of transferrin, insulin and selenium. These results indicate that serum protects G1 phase cells for heat-induced changes of cell cycle progression as well as on cell survival, but the mechanisms involved in both phenomena seem to be different.     

Effects of mild heat shock on glycogenesis and its regulation by insulin in cultured fetal hepatocytes

The effects of a mild heat shock were investigated using cultured 15-day-old fetal rat hepatocytes in which an acute glucocorticoid-dependent glycogenic response to insulin was present. After exposure from 15 min to 2 h at 42.5°C, cell surface [¹²⁵I]insulin binding progressively decreased down to 60% of the value shown in cells kept at 37°C, due to a decrease in the apparent number of insulin binding sites with little change in insulin receptor affinity. In parallel cultures, protein labeling with [³⁵S]methionine exhibited stimulated synthesis of specific proteins, in particular, 73-kDa Hsc (heat shock cognate) and 72-kDa Hsp (heat shock protein). When cells were returned to 37°C after 2 h at 42.5°C, cell surface insulin binding showed a two-third restoration within 3 h (insulin receptor half-life = 13 h), with similar concomitant return of Hsps72,73 synthesis to preinduction levels. The rate of [¹⁴C]glucose incorporation into glycogen measured at 37°C after 1- to 2-h heat treatment revealed a striking yet transient increase in basal glycogenesis (up to 5-fold). At the same time, the glycogenesis stimulation by insulin was reduced (from 3.2 to 1.4—fold), whereas that induced by a glucose load was maintained. Induction of thermotolerance after a first heating was obtained for the heat shock-dependent events except for the enhanced basal glycogenesis. In insulin-unresponsive cells grown in the absence of glucocorticoids, heat shock decreased the glycogenic capacity without modifying the glucose load stimulation, supporting the hypothesis that insulin and thermal stimulation of glycogenesis share at least part of the same pathway. Inverse variations were observed between Hsps72,73 synthesis and both cell surface insulin receptor level and insulin glycogenic response in fetal hepatocytes experiencing heat stress. © 1995 Wiley-Liss, Inc.     

Terguride attenuates prolactin levels and ameliorates insulin sensitivity and insulin binding in obese spontaneously hypertensive rats

Glucose tolerance, serum insulin, insulin receptors in epididymal fat tissue, circulating total cholesterol and triglyceride concentrations as well as serum prolactin were studied in obese and lean spontaneously hypertensive rats (SHR) of both sexes. Obese animals displayed insulin resistance and elevated insulin and triglyceride concentrations. Moreover, in obese rats the increased mass of epididymal fat tissue was accompanied with decreased capacity of high affinity binding sites of insulin receptors in the tissue plasma membranes. Terguride treatment lowered prolactin serum levels which was accompanied by ameliorated insulin sensitivity in obese animals of both sexes. In addition, terguride treatment decreased serum insulin and triglyceride concentrations in obese females and at the same time enhanced the affinity of high affinity insulin binding sites. Our results show that obesity in SHR is associated with a decreased capacity of insulin receptors and that prolactin may play a role in obesity-induced insulin resistance, particularly in female rats.     

Distribution of insulin receptors in human erythrocyte membranes. Insulin binding to sealed right-side-out and inside-out human erythrocyte vesicles

Analyses of insulin binding to human erythrocytes and to resealed right-side-out and inside-out erythrocyte membrane vesicles have revealed that high affinity insulin binding receptors are present on both sides of the erythrocyte membranes. Insulin binding to human erythrocytes was examined with the use of a binding assay designed to minimize the potential errors arising from the low binding capacity of this cell type and from non-specific binding in the assay. Scatchard analysis of equilibrium binding to the cells revealed a class of high affinity sites with a dissociation constant (Kd) of (1.5 +/- 0.5) X 10(-8) M and a maximum binding capacity of 50 +/- 5 sites per cell. Interestingly, both resealed right-side-out and inside-out membrane vesicles exhibited nearly identical specific sites for insulin binding. At the high affinity binding sites, for both right-side-out and inside-out vesicles, the dissociation constant (Kd) was (1.5 +/- 0.5) X 10(-8) M, and the maximum binding capacity was 17 +/- 3 sites per cell equivalent. These findings suggest that insulin receptors are present on both sides of the plasma membrane and are consistent with the participation of the erythrocyte insulin receptors in an endocytic/recycling pathway which mediates receptor-ligand internalization/externalization.     

Role of Hsp70 synthesis in the fate of the insulin-receptor complex after heat shock in cultured fetal hepatocytes

The influence of a mild heat shock on the fate of the insulin-receptor complex was studied in cultured fetal rat hepatocytes whose insulin glycogenic response is sensitive to heat [Zachayus and Plas (1995): J Cell Physiol 162:330–340]. After exposure from 15 min to 2 hr at 42.5°C, the amount of ¹²⁵I-insulin associated with cells at 37°C was progressively decreased (by 35% after 1 hr), while the release of ¹²⁵I-insulin degradation products into the medium was also inhibited (by 75%), more than expected from the decrease in insulin binding. Heat shock did not affect the insulin-induced internalization of cell surface insulin receptors but progressively suppressed the recycling at 37°C of receptors previously internalized at 42.5°C in the presence of insulin. When compared to the inhibitory effects of chloroquine on insulin degradation and insulin receptor recycling, which were immediate (within 15 min), those of heat shock developed within 1 hr of heating. The protein level of insulin receptors was not modified after heat shock and during recovery at 37°C, while that of Hsp72/73 exhibited a transitory accumulation inversely correlated with variations in insulin binding, as assayed by Western immunoblotting from whole cell extracts. Coimmunoprecipitation experiments revealed a heat shock-stimulated association of Hsp72/73 with the insulin receptor. Affinity labeling showed an interaction between ¹²⁵I-insulin and Hsp72/73 in control cells, which was inhibited by heat shock. These results suggest that increased Hsp72/73 synthesis interfered with insulin degradation and prevented the recycling of the insulin receptor and its further thermal damage via a possible chaperone-like action in fetal hepatocytes submitted to heat stress. © 1996 Wiley-Liss, Inc.     

Impact of combined hormonal pretreatment (insulin+TSH) on the imprinting of hormones administered in combination to Chinese hamster ovary cell culture.

Cultured Chinese hamster ovary (CHO) cells were treated (imprinted) with insulin and with thyrotropin (TSH) related to gonadotropins (FSH+LH). When one week later the treatment was repeated with one of the hormones, considerable differences could be observed in the binding capacity of the cells. In the hormone combination TSH was able to evoke persistent imprinting only to a markedly lesser degree than insulin, meanwhile the imprintatory effect of insulin was of greater extent even on the cell regarded to be unspecific for insulin. Hormone treatment of one hour duration--when investigated immediately after--did not extinct the binding capacity to TSH but enhanced that to insulin. With the deterioration of the conditions of culturing, the enhanced binding capacity disappeared.     

Hormonal imprinting in cell culture I. Impact of a single exposure to insulin on cellular insulin binding capacity in permanent cell lines

Three permanent cell lines showed a durable change in cellular insulin binding capacity in response to a single exposure to insulin. Initial increase in binding of FITC-labeled insulin to both cytoplasmic and nuclear membrane was followed by a lasting decrease in the case of fibroblasts (NCTC) and return to approximately the control level in epithelial (Chang liver) and tumour (HeLa) cell cultures. While the amplifying effect of a single 4-h exposure was measurable as soon as after 24 h, that of a single 24-h exposure came into display only after 72 h in the epithelial and tumour cell cultures. The latter two lines showed return of the binding capacity to the control value and a drop of it to a minimum 20 days after exposure for 4 and 24 h, respectively. These observations support the implication that although the degree and manner of insulin binding differs between cell lines, the impact of a single exposure to insulin is durably "felt" by all.     

Retinoic acid alters subcellular compartmentalization of ATP pools in 3T3 cells but not in HeLa cells

From the Chinese hamster ovary (CHO) cell, genetic variants (MonR-31 and MonR-32) relatively resistant to monensin, an ionophoric antibiotic, have been isolated. Growth of both MonR-31 and MonR-32 clones required higher doses of serum than CHO. Addition of insulin to media containing a low dose of serum restored full colony formation, but growth of MonR-31 or MonR-32 cells required more insulin than CHO cells. Specific binding of [125I]insulin was observed in these cell lines. The two MonR clones bound about one-half or less the [125I]insulin bound by CHO cells. Scatchard analysis for [125I]insulin binding at 4 degrees C and 37 degrees C showed altered number of binding sites, but not insulin affinity: The number of binding sites in the MonR cell was about a half or less that of the parental CHO cell. Down-regulation of insulin receptor was assayed when both CHO and MonR cells were incubated with 1 microgram/ml insulin. A 50-60% decrease in levels of insulin surface binding capacities was observed in CHO after exposure to insulin, whereas there was no decrease in MonR cell. The cellular uptake of 2-[3H]deoxyglucose into CHO cells was significantly enhanced in the presence of insulin, but only slight, if any, increase was observed in MonR cells.     

Routine heat inactivation of serum reduces its capacity to promote cell attachment

Summary Heat inactivation (56°C for 40 min) of bovine calf serum was shown to diminish its capacity to promote the attachment of cells to plastic or glass surfaces. This effect was not observed in stationary cultures (culture dishes) but became manifest under conditions in which the cells were subjected to a small amount of liquid shear force, i.e. by growing cells in roller bottles or culture tubes. Of four cell lines tested on bovine calf serum (SV-BHK, BALB-3T3, CV-1, and FS-4) SV-BHK and CV-1 cells showed the greatest sensitivity to loss of attachment-promoting activity. Fetal bovine serum also seemed to be affected by heat inactivation but to a lesser degree than bovine calf serum. Treatment of vessel surfaces with either unheated calf serum or specific attachment factors (gelatin, poly-d-lysine, and fibronectin) greatly increased cell attachment in the presence of heat inactivated serum. Heat inactivation did not seem to affect the ability of cells to grow after attachment. Of the four cell lines tested, the normal human fibroblast line (FS-4) was shown to be most effective at conditioning medium and restoring its capacity to promote the attachment of all four cell lines. This research was supported in part by VECOL, Inc., Bogata, Columbia and by grant SRC 5 U24 RR02557-02 from the National Institutes of Health, Bethesda, MD.     

Obese mice have higher insulin receptor levels in the hepatocyte cell nucleus following insulin stimulation in vivo with an oral glucose meal.

Internalization of the insulin receptor occurs following insulin binding at the cell surface, which serves to attenuate the insulin signal as well as modulate the number of surface insulin receptors. Obese animals exhibit decreased cell surface insulin receptor number as well as defects in insulin receptor internalization and processing. The insulin receptor may also translocates to the nucleus of hepatocytes and adipocytes following stimulation of cells with insulin. The objective of this study was to determine if insulin receptor trafficking to the hepatocyte cell nucleus could be observed in vivo and whether this process was altered in obese compared to lean mice. Mice were fasted for 12 h to reduce serum insulin to basal levels. Animals were then given an oral meal of glucose to stimulate the binding of insulin to receptor in vivo. Hepatocyte plasma membrane and nuclei were fractionated to purity following the glucose meal. Levels of insulin receptor were determined using insulin binding assays and a Western blotting assay using anti-insulin receptor antibody. As the amount of serum insulin increased following the glucose meal, a corresponding increase in nuclear insulin binding occurred in lean animals but not obese animals (P<0.05). Following the glucose meal, insulin receptor detected in the cell nucleus was increased in obese compared to lean mice (P<0.05). Thus insulin receptor translocation to the nucleus was demonstrated in vivo following a glucose meal in hepatocytes of both lean and obese animals. It is suggested that serum hyperglycemia and hyperinsulinemia in obese mice increased translocation of the insulin receptor to the nucleus.     

低频脉冲电场对胰岛素介导的细胞增殖影响及其作用机理研究

本文以胞外信号分子胰岛素为研究对象,从细胞信号系统与电磁场相互耦合角度,通过MTT比色法和间接免疫荧光技术研究脉冲电场(f=50Hz,τ=20μS,Epp=1V/m)对人肝细胞(L-02细胞株)的增殖能力以及胰岛素与细胞表面受体的专一结合特性的影响。MTT比色分析结果发现在脉冲电场对细胞增殖的直接作用中,处理5、10、20分钟对细胞增殖的抑制百分率分别为10.13％、18.10％和11.85％;脉冲电场对细胞增殖的间接作用中,胰岛素经脉冲电场处理20、40分钟,对细胞增殖的抑制百分率分别为10.31％和14.12％;流式细胞术检测结果表明细胞悬液和胰岛素共同经脉冲电场处理20分钟组其平均荧光强度降低22.74％,仅胰岛素受电场处理组和仅细胞受电场处理组的平均荧光强度分别下降12.96％和10.51％。本实验结果显示 脉冲电场对人肝细胞的作用体现在两个方面:一是电场直接作用于细胞膜上的胰岛素受体及其他膜成分;二是脉冲电场还可通过改变培养基中的胰岛素分子的构像,影响胰岛素与受体的结合能力,进而影响细胞的增殖等活动。     

A case of insulin resistant diabetes with possible antibodies to insulin receptors.

A case of a 19-year-old, non-obese female with insulin resistant diabetes mellitus and polycystic ovary syndrome was reported. The maximal insulin requirement attained 360 units per day, but a satisfactory control of diabetes did not follow. The patient's serum contained not only anti-insulin antibodies, but also possible anti-insulin receptor antibodies which were demonstrated by the 125I-insulin binding test using insulin receptors derived from human placental plasma membrane. The insulin resistance in this case was assumed to be caused primarily by possible blocking antibodies to insulin receptors and partly by anti-insulin antibodies because of the following observations. First, high serum free insulin (165 microunits/ml) without hypoglycemia indicates the presence of insulin resistance due to other factors than antiinsulin antibodies. Second, the titer of 125I-insulin binding capacity of serum was not unusually higher than those seen in chronically insulin-treated diabetics. Third, immunologically heterospecies insulin (fish insulin) was also ineffective. The clinical features such as absence of ketoacidosis and association with polycystic ovary syndrome resemble those of an unique diabetic syndrome reported previously though acanthosis nigricans and endogenous hyperinsulinemia were not found in this case. Her insulin resistance remitted spontaneously and over the next 18 months' observation, her diabetes remained regulated without insulin therapy.     

Hormonal regulation of the synthesis of casein and alpha-lactalbumin in a primary mammary cell culture system

The addition of 5 micrograms/ml of both insulin and prolactin, 3 microM cortisol and 5% fetal bovine serum stimulated casein synthesis during a 5 day culture of mammary epithelium from lactating mice using a floating collagen gel as a culture substratum. Omission of any of the three hormones or serum decreased casein synthesis substantially. The use of 10% serum or the attached gel culture system also decreased casein synthesis. Cells cultured with the combination of the three hormones and 5% serum contained a low level of casein mRNA on day 2, but it increased to much higher levels on day 4 and 5, amounting to over 30% of total mRNA on day 5. In contrast to casein synthesis, the maximal increase in alpha-lactalbumin synthesis required the presence of 0.03 microM cortisol. The combination of insulin, prolactin and 3 microM cortisol or insulin and prolactin elicited smaller increases. The translatable mRNA for alpha-lactalbumin in cells cultured with insulin, cortisol and prolactin for 5 days was detected, but not in cells with insulin and cortisol. Both a high and low concentration of cortisol in combination with insulin increased prolactin binding capacity of cultured cells to the same extent, whereas cells cultured with insulin alone contained much lower levels of prolactin binding. The difference in the capacity of prolactin binding between cells cultured with insulin alone and those cultured with insulin and cortisol correlated well with their ability to synthesize casein in response to prolactin.     

Hormone receptors. 7. Characteristics of insulin receptors in a new line of cloned neonatal rat hepatocytes

1. A new line of cloned, differentiated rat hepatocytes (RL-PR-C) was evaluated for its usefulness as an in vitro system for studying the regulation of the insulin receptor. 2. Insulin rapidly reversibly and specifically bound to RL-PR-C hepatocytes. Binding of tracer 125I-labeled insulin, which was competitively inhibited by native insulin as well as by proinsulin and analogs of insulin and proinsulin in proportion to their biological activity, was not influenced by glucagon, corticotropin, or human growth hormone. Anti-insulin receptor serum from a patient with Acanthosis Nigricans Type B competed with 125I-labeled insulin for binding to cell surface sites. 3. Trypsinization destroyed insulin binding sites, but these were restored by incubation under growth conditions; a 75% restoration of binding sites was achieved by one cell population doubling. 4. RL-PR-C hepatocytes responded to insulin binding by an increase in glycogen synthesis from glucose. The insulin effect was maximal at 85 nM, but was detectable at lower, more physiological, concentrations. 5. Chronic exposure (for at least 3h) of hepatocytes to insulin (10(-10)--(10(-8) M) reduced by up to 60% the number of binding sites for insulin (down-regulation). Down-regulation was prevented by cycloheximide at concentration (10 micron) sufficient to inhibit markedly protein synthesis from tracer isoleucine. Recovery from down-regulation induced by native insulin at 10(-7 M or lower concentrations was complete by 18 h under growth conditions. 6. Although RL-PR-C hepatocytes spontaneously transform after about 90 population doublings, no significant differences between normal and transformed cells were observed in insulin binding characteristics and in interaction of cells with anti-insulin receptor serum. However, transformed cells exhibited a substantially reduced (maximum of 20%) down-regulation response to insulin. 7. RL-PR-C rat hepatocytes appear, for these reasons, to be a useful model system for studying the regulation of the insulin receptor.     

Studies on the regulation of insulin receptors in cultured BALB/3T3 fibroblasts

The level of [¹²⁵I]insulin binding to BALB/ 3T3 fibroblasts was low in growing cells and high in stationary cells. Since frequent changes of medium (every 2 h) did not modify the hormone binding of the stationary cells, it is unlikely that serum factors directly regulate the number of insulin receptors. Cells were grown to different densities by plating them in different concentrations of serum. Insulin binding was low in dense cultures maintained actively growing by high serum concentration, while binding was high in sparse cultures which were growth-arrested due to serum depletion. Thus, cell density does not directly regulate the insulin receptors. The growth status of the cells is the only factor that explains consistently the variations of insulin binding in these and previous [1, 2] experiments. Synchronization of the cells by two different methods did not show a reproducible cellcycle dependence for the insulin receptors.     

Reduced insulin endocytosis in serum-transformed fibroblasts demonstrated by flow cytometry

Neoplastic transformation often results in the loss of growth control and concomitant changes in cell surface properties. The changes in endocytosis of a variety of probes after serum or anchorage transformation were measured for mouse fibroblasts by flow cytofluorometry. No major differences in dextran (fluid phase) or histone (nonspecific-adsorptive) endocytosis were observed among four cell lines with different growth properties. However, decreased receptor-mediated internalization of alpha 2-macroglobulin was observed for cell lines transformed to either serum or anchorage independence. Furthermore, increased wheat germ agglutinin and decreased insulin endocytosis were observed, but only in serum transformants. The changes specific to serum transformants were not accounted for by changes in binding of wheat germ agglutinin or insulin. The possible implications of these observations regarding serum transformation and the insulin requirement for growth in serum-free medium are discussed.     

Insulin binding in cultured Chinese hamster kidney epithelial cells: The effect of serum in the medium

Summary [¹²⁵I]Insulin (porcine) binding to an epithelial cell line established from a Chinese hamster kidney, CHK-AC_E−100, showed an optimum at pH 8.0 and reached a maximum after 2.5 h incubation at 25°C. Dissociation of bound [¹²⁵I]insulin was facilitated by the addition of unlabeled insulin in the dilution buffer. Porcine insulin effectively competed for [¹²⁵I]insulin binding to the cultured cells and was 30 and 90 times as potent as guinea pig insulin and porcine proinsulin in causing 50% inhibition of [¹²⁵I]insulin binding; glucagon was completely ineffective. Scatchard analysis of the binding data yielded a curvilinear plot and a capacity of 0.6 ng/10⁶ cells; the average affinity of the empty receptor, , was calculated to be 1.78×10⁸ M ⁻¹ and that of the filled receptor, , 0.57×10⁸ M ⁻¹. Substitution of fetal bovine serum (FBS) in the culture medium with bovine calf, bovine newborn, or bobby calf serum altered insulin binding characteristics in the cells and reduced cell growth. Insulin binding characteristics of cells grown in hormone-supplemented medium containing 0 to 0.1% FBS were similar to those of cells grown in minimum essential medium (MEM) containing 2 to 5% FBS. The data indicated that the established Chinese hamster kidney epithelial cell line CHK-AC_E−100 possessed specific insulin receptors and the characteristics of the receptors could be manipulated by changing the serum in culture medium.     

Effects of a long-lasting hyperinsulinemia induced by insulin infusion on the subcellular distribution of liver insulin receptors in the rat

Acute hyperinsulinemia in rats have been shown to cause enhanced endocytosis of liver insulin receptors with little or no change in the total receptor number. To determine whether a similar phenomenon occurs in long-lasting hyperinsulinemia, the subcellular distribution of liver insulin receptors has been studied in rats infused continuously with insulin (0.4 and 0.2 U/h) for 4 days. In rats in which plasma insulin concentration was maintained at 15-20 ng/ml, there was, from 3 to 24 h, a 2-fold decrease in insulin binding to plasma membranes (PM), along with 2 to 4-fold increase in insulin binding to the light (GEI), intermediate (GEi) and heavy (GEh) Golgi-endosomal fractions; concomitantly, there was a 10-fold increase in the insulin content of Golgi-endosomal fractions. After 24 h, the changes in insulin binding to PM and GEI were maintained, but the increase in both insulin binding activity and insulin content of GEi and GEh became progressively less marked, although plasma insulin concentration remained elevated. Throughout infusion, insulin binding to the total particulate fraction was unchanged. In rats, in which plasma insulin was maintained at 6-8 ng/ml, insulin binding to PM was decreased to a lesser degree and insulin binding to Golgi-endosomal fractions was unchanged (GEh) or decreased (GEI and GEi), although the insulin content of these fractions remained high. These results suggest that, while an enhanced receptor endocytosis accounts for the decrease in cell surface receptors observed at an early stage of the hyperinsulinemia, additional regulatory mechanisms are probably involved at a later stage.