Insulin down-regulates insulin receptor number and up-regulates insulin receptor affinity in cells expressing a tyrosine kinase-defective insulin receptor

We examined the effect of insulin treatment on HTC cells transfected with large numbers of either normal insulin receptors (HTC-IR) or insulin receptors defective in tyrosine kinase (HTC-IR/M-1030). In both HTC-IR and HTC-IR/M-1030 cells, 20 h of insulin treatment (1 microM) at 37 degrees C resulted in a 65% decrease in the number of binding sites with a reciprocal 6-fold increase in affinity. In contrast, treatment with 10 nM insulin (20 h, 37 degrees C) also increased receptor affinity but had a smaller effect on the number of binding sites. 125I-Insulin binding to soluble receptors from HTC-IR and HTC-IR/M-1030 cells pretreated with insulin showed results similar to those obtained in intact cells. In both HTC-IR and HTC-IR/M-1030 cells, insulin enhanced insulin receptor degradation. In HTC-IR/M-1030 cells a 1-h incubation with insulin did not change receptor number and had only a small effect on receptor affinity; also there was no effect of insulin after a 20-h incubation at 15 degrees C. Inhibiting protein synthesis by pretreatment with cycloheximide (100 microM) did not block either the decrease in receptor number or the increase in receptor affinity. Both HTC-IR and HTC-IR/M-1030 cells exhibited a very slow rate of insulin and insulin receptor internalization and no differences were seen in this parameter when HTC-IR cells were compared to HTC-IR/M-1030 cells. These studies indicate, therefore, that in cells expressing kinase-defective insulin receptors, insulin down-regulates insulin receptor number via enhanced receptor degradation, and up-regulates receptor affinity. These effects were time- and temperature-dependent, but not dependent on new protein synthesis, and suggest that activation of tyrosine kinase may not be a prerequisite for certain mechanisms whereby insulin regulates its receptor.     

Intrinsic differences of insulin receptor kinase activity in red and white muscle

The sensitivity and responsiveness of glucose uptake and glycogen synthesis to insulin are 3-4-fold greater in red than in white skeletal muscle (James, D. E., Jenkins, A. B., and Kraegen, E. W. (1985) Am. J. Physiol. 248, E567-E574). In the present study, the insulin receptor tyrosine kinase activity has been examined in red and white muscle of rats. Partially purified insulin receptors were obtained from muscle following solubilization in detergent, ultracentrifugation, and lectin affinity chromatography. Total insulin receptor number per gram of tissue was slightly higher in red (30%) than in white muscle. In contrast, basal and insulin-stimulated autophosphorylation, normalized for receptor number, were 2.3-fold higher in red muscle. A similar difference was observed in the ability of partially purified receptors to phosphorylate the exogenous substrate polyglutamate/tyrosine. The integrity of the insulin receptor preparation in the two fiber types was identical as determined by affinity cross-linking of [125I-TyrB26]insulin to the receptor. Mixing partially purified receptors from red and white muscle resulted in an additive response for exogenous substrate phosphorylation, suggesting that the difference in tyrosine kinase activity was not due to the presence of an inhibitor or activator. The results suggest that there are differences in the insulin receptors of red and white muscles that lead to discordance in their basal and insulin-stimulated intrinsic tyrosine kinase activity. The correlation between these differences and insulin action in red and white muscle supports the concept that the insulin receptor tyrosine kinase activity is involved in the initiation of insulin action.     

Insulin receptors in developing rat liver: Acquisition of down regulation in the immediate postnatal period

Alterations in the high and low affinity insulin receptor concentrations in developing rat liver were investigated. The number of high affinity receptors in partially purified plasma membranes from fetal rats increased from Days 19 through 22 of gestation, with no further increase in binding during the postnatal period. Fetuses of diabetic rats had approximately three times as many high affinity insulin receptors as age-matched fetuses of normal rats; however, by 1 day after birth the receptor number decreased to the normal level. Neither the number of low affinity receptors nor the affinity of insulin binding to high or low affinity receptors changed during development or between offspring of normal and diabetic rats. These changes in the number of high affinity hepatic insulin receptors from prenatal animals did not correlate with the concentration of plasma insulin. When suckling pups were rendered diabetic the changes in the number of high affinity insulin receptors correlated with alterations in plasma insulin concentrations. The number of high affinity sites/microgram DNA in hepatocytes from Day 18 fetal rats was not altered when cells were cultured for 48 h in medium containing 0, 250, or 5000 μU/ml of added insulin. When cultured hepatocytes derived from 1-day-old and adult rats were maintained in medium with added insulin concentrations of 250 or 5000 μU/ml the number of high affinity receptors/microgram DNA decreased as compared to the number of high affinity receptors in hepatocytes cultured in medium with no added insulin. This decrease in receptor number was accompanied by an increase in the affinity of insulin binding to its high affinity receptors. The data show that (i) only the high affinity insulin receptor number increases in rat liver during the prenatal period, (ii) fetuses of diabetic rats show a greater increase in high affinity receptors than do fetuses of normal animals, and (iii) the phenomenon of down regulation for high affinity insulin receptors is not observed in fetal rat liver, but is acquired in the immediate postnatal period.     

Effect of glucocorticoids and adrenaline on insulin receptors in plasma membranes and nuclear envelopes of the rat liver

To elucidate the course of regulation of insulin receptors in nuclear envelope and its relationship with insulin receptors in the plasma membrane a comparative study of these receptors in both subcellular fractions was conducted under the influence of the involved cell surface receptor factor. It is found that under adrenalectomy the number of nuclear envelope receptors and degree of their affinity did not increase as this occurs in plasma membrane receptors. Hydrocortisone replacement therapy in these animals lowers the receptor number in the both fractions. Hydrocortisone-induced hypercorticism does not change 125I-insulin binding by nuclear envelope but decreases its binding (accounted for the number of receptors and affinity) by the plasma membrane. Under hyperadrenalinemia the number of receptors decreases in the both subcellular fractions. The results suggest no independent regulation of insulin receptors on the surfaces of nuclei and cells.     

The Role of IGF-system in Vascular Insulin Resistance

Insulin and IGF-I are closely related peptides, which interact by several mechanisms. In high supraphysiological concentrations (>/=10 (-8) M), they cross-react with each other's receptors with 100- to 1000-fold lower affinity than with their cognate receptors. This can cause confusion, since in many in vitro studies, insulin has been used in high unphysiological concentrations, which activate IGF-I receptors. Due to the differences in affinity, insulin and IGF-I probably do not activate each other's receptors in vivo. IGF-I receptors are several-fold more abundant than insulin receptors in human micro- and macrovascular endothelial cells and in human vascular smooth muscle cells. Both insulin and IGF-I receptor protein can be demonstrated and they are activated by their cognate ligand at physiological concentrations of 10 (-9)-10 (-10) M. In vascular smooth muscle cells, IGF-I but not insulin stimulates metabolism and growth. IGF-I stimulates DNA-synthesis and growth in microvascular endothelial cells, but neither insulin nor IGF-I have any effect on macrovascular endothelial cells. Both insulin and IGF-I have been shown to stimulate nitric oxide production in endothelial cells, but only the effect of IGF-I was obtained at a physiological concentration. In both endothelial and vascular smooth muscle cells, insulin and IGF-I receptors occur as insulin/IGF-I hybrid receptors with high affinity to IGF-I and low for insulin. Due to the low number of insulin receptors and the presence of hybrid receptors the insulin receptor signal is probably too attenuated to elicit biological effects, explaining the insulin resistance of vascular cells in vitro. In vivo both insulin and IGF-I have been reported to increase muscle blood flow in physiological concentrations. Whether this is due to direct effects on endothelial cells or indirectly induced is not clear. The effect of insulin is attenuated by insulin resistance. In conclusion, the in vitro data suggest that endothelial cells and vascular smooth muscle cells are sensitive to IGF-I, but insensitive to insulin, and this is due to a preponderance of IGF-I receptors and the presence of insulin/IGF-I hybrid receptors.     

Reversible reduction of insulin receptor affinity by ATP depletion in rat adipocytes.

The effects of the metabolic inhibitor NaN3 on insulin receptors in isolated rat fat-cells were investigated. The agent reduced insulin binding in parallel to a decrease of the ATP content of cells. Both effects were observed in the same concentration range of NaN3, and were fully reversible. According to the binding curves the affinity rather than the number of receptors was reduced. Kinetic experiments revealed an increased dissociation rate of the insulin-receptor complex. The effects outlasted cell disruption, since the receptor affinity was still lowered in plasma membranes obtained from NaN3-treated cells. Thus an inhibition of insulin internalization could not account for the observed effects. It is suggested that the observed ATP-dependence of insulin receptor affinity reflects a reversible structural alteration of the receptor, or of some closely related membrane protein.     

Insulin-like growth factor I binding and receptor kinase in red and white muscle

IGF-I receptors were partially purified from red and white skeletal muscle by lectin-affinity chromatography and the resultant fraction was depleted of insulin receptors by insulin affinity chromatography. Equilibrium binding of 125I-IGF-I to receptor preparations from red and white muscle yielded identical Scatchard plots. The integrity of the IGF-I receptor preparation in the two fiber types was identical as determined by affinity cross-linking. The tyrosine kinase activity of the receptor from red muscle was 2-3-fold more active towards exogenous substrates in both the basal and ligand-activated states as compared to white muscle. These data show that there is IGF-I-dependent kinase activity intrinsic to IGF-I receptors from skeletal muscle, and suggest that identical cellular factors may regulate the kinase activity of insulin and IGF-I receptors in a parallel manner in vivo.     

Characterization of insulin receptors in human promyelocytic leukemia cell HL60

Highly specific insulin receptors have been identified on human promyelocytic leukemia cells HL60. Insulin binding increased progressively with time to reach a maximum at 2 h at 22° and was proportional to the number of cells in the incubation mixture. Insulin degradation as assessed by TCA precipitation and reincubation studies was negligible. Scatchard analysis of the binding data was curvilinear and the total number of insulin receptor sites per cell was around 45,000. The average affinity profile gave an “unoccupied site” affinity constant of 3.5 × 10⁸ M^?1. The promyelocytic cells HL60, thus, have specific binding sites and binding characteristics similar to more mature human myeloid cells.     

Insulin activation of insulin receptor tyrosine kinase in intact rat adipocytes. An in vitro system to measure histone kinase activity of insulin receptors activated in vivo

We have studied the effect of incubation of intact cells with insulin on insulin receptor kinase activity. Following exposure of rat adipocytes to insulin, cells were solubilized and insulin receptors purified by specific immunoprecipitation or by insulin affinity chromatography. Kinase activity of the receptors, as measured by phosphorylation of histone 2B, was then determined. Insulin treatment of the cells resulted in a 10-20-fold increase in histone kinase activity of the subsequently isolated insulin receptors. The insulin effect was half-maximal at 3 s and maximal within 15 s of exposure, was dose-dependent (EC50 = 21 ng/ml), and was rapidly reversible following dissociation of insulin from the cells. The insulin effect in intact cells on insulin receptor kinase activity could be partially reversed in vitro by dephosphorylation of the isolated receptors by alkaline phosphatase. It is proposed that: in intact cells, insulin causes alterations in insulin receptors, such that their kinase activity toward non-receptor substrates increases; increased insulin receptor kinase activity following insulin stimulation in intact cells is, at least in part, the result of an increased phosphate content of the receptors; and effects of insulin on insulin receptors in intact cells can be preserved during receptor isolation and thus can be measured in a cell-free system.     

Ontogenesis of the insulin receptor in the rabbit brain

We delineated the ontogeny of the brain insulin binding, insulin receptor number and affinity using plasma membranes isolated from the rabbit. Specific 125I-insulin binding and receptor number expressed per milligram of protein increased from the 20 day gestation fetus to the 1-day-old newborn, declining thereafter to attain adult values by day 6 of postnatal life. Specific 125I-insulin binding and the receptor number in the adult brain was less than the fetal and neonatal (1 day) brain receptors. Although a similar trend was observed specifically during fetal development, the changes in receptor number expressed per microgram DNA were not significant in the neonatal period. The adult brain insulin receptor number was higher than the 20- to 27-day fetus and similar to that of the 30-day fetus and the 1- to 5-day newborns. The total receptor number correlated linearly with the brain plasma membrane protein increment velocity. The affinity of the receptors increased during early fetal development (20-27 days) and remained constant thereafter in the postnatal period. We conclude that the ontogenic changes of the brain insulin receptors are similar to the ontogenic changes of brain plasma membrane protein. The developmental changes are more pronounced when the receptor number is expressed per milligram protein versus microgram DNA.     

Insulin receptors in the mammalian central nervous system: binding characteristics and subunit structure

Insulin receptors in rat and human central nervous system have been identified by binding of 125I-insulin on purified synaptic plasma membranes; affinity labelling of receptors by chemical cross-linking 125I-insulin; or phosphorylation of receptors with [gamma-32P]ATP. Brain insulin receptors showed significant differences in their binding characteristics and subunit structure when compared with receptors in other tissues like adipose and liver cells: absence of negatively cooperative interactions; a distinct binding specificity i.e. porcine proinsulin, coypu insulin and insulin-like growth factor I and II showed 2-5 times higher binding affinity in brain than in other cell types; a smaller molecular size of the brain receptor alpha-subunit than in other tissues (Mr approximately 115,000 instead of 130,000). In contrast, the size (Mr approximately 94,000) and function of the insulin receptor beta-subunit kinase was identical with that described in other cells. We conclude, that insulin receptors in mammalian brain represent a receptor subtype which may mediate growth rather than metabolic activity of insulin.     

Mutation of the high cysteine region of the human insulin receptor alpha-subunit increases insulin receptor binding affinity and transmembrane signaling

Our previous studies indicated that amino acid residues 240-250 in the cysteine-rich region of the human insulin receptor alpha-subunit constitute a site in which insulin binds (Yip, C. C., Hsu, H., Patel, R. G., Hawley, D. M., Maddux, B. A., and Goldfine, I. D. (1988) Biochem. Biophys. Res. Commun. 157, 321-329). We have now constructed a human insulin receptor mutant in which 3 residues in this sequence were altered (Thr-Cys-Pro-Pro-Pro-Tyr-Tyr-His-Phe-Gln-Asp to Thr-Cys-Pro-Arg-Arg-Tyr-Tyr-Asp-Phe-Gln-Asp) and have expressed this mutant in rat hepatoma (HTC) cells. When compared with cells transfected with normal insulin receptors, cells transfected with mutant receptors had an increase in insulin-binding affinity and a decrease in the dissociation of bound 125I-insulin. Studies using solubilized receptors also demonstrated that mutant receptors had a higher binding affinity than normal receptors. In contrast, cells transfected with either mutant or normal receptors bound monoclonal antibodies against the receptor alpha-subunit with equal affinity. When receptor tyrosine kinase activity and alpha-aminoisobutyric acid uptake were measured, cells transfected with mutant insulin receptors were more sensitive to insulin than cells transfected with normal receptors. These findings lend further support therefore to the hypothesis that amino acid sequence 240-250 of the human insulin receptor alpha-subunit constitutes one site that interacts with insulin, and they indicate that mutations in this site can influence insulin receptor binding and transmembrane signaling.     

Insulin regulation of insulin-like growth factor action in rat hepatoma cells

We have reported previously that insulin causes a complete but reversible desensitization to insulin action in rat hepatoma HTC cells in tissue culture, and that this insulin resistance is mediated by postbinding mechanisms rather than receptor down-regulation (Heaton, J. H., and Gelehrter, T. D. (1981) J. Biol. Chem. 256, 12257-12262). We report here that insulin causes a similar desensitization to the induction of tyrosine aminotransferase by the insulin-like growth factors IGF-I and IGF-II isolated from human plasma, and by multiplication-stimulating activity, the rat homologue of IGF-II. The results of both competition-binding studies and affinity cross-linking experiments indicate that insulin-like growth factors (IGFs) bind primarily to IGF receptors rather than to insulin receptors. The low concentrations at which these factors induce transaminase is consistent with their acting primarily via IGF receptors. This is confirmed by experiments utilizing anti-insulin receptor antibody which both inhibits 125I-insulin binding and shifts the concentration dependence of insulin induction of tyrosine aminotransferase to the right. This same immunoglobulin does not inhibit 125I-multiplication-stimulating activity binding and only minimally inhibits 125I-IGF-I binding. Anti-insulin receptor antibody also does not significantly shift the concentration dependence for the IGFs, suggesting that IGFs induce transaminase by acting via IGF receptors. Although insulin down regulates insulin receptors, it does not decrease IGF-I or IGF-II binding. We conclude that insulin causes desensitization of HTC cells to IGFs by affecting a postbinding step in IGF action, which may be common to the actions of both insulin and insulin-like growth factors.     

Receptors for insulin and insulin-like growth factor-I can form hybrid dimers. Characterisation of hybrid receptors in transfected cells.

We have demonstrated the formation of hybrid insulin/insulin-like growth factor-I(IGF-I) receptors in transfected rodent fibroblasts, which overexpress human receptors, by examining reactivity with species- and receptor-specific monoclonal antibodies. In NIH 3T3 and Rat 1 fibroblasts, endogenous IGF-I receptors were unreactive with anti-(human insulin receptor)monoclonal antibodies (47-9, 25-49, 83-14, 83-7, 18-44). However, in transfected cells expressing high levels of insulin receptors, 60-80% of high-affinity IGF-I receptors reacted with these antibodies, as assessed either by inhibition of ligand binding in intact cells or by precipitation of solubilized receptors. Conversely, endogenous insulin receptors in NIH 3T3 cells were unreactive with anti-(IGF-I receptor) antibodies alpha IR-3 and 16-13. However, approx. 50% of high-affinity insulin receptors reacted with these antibodies in cells expressing high levels of human IGF-I receptors. The hybrid receptors in transfected cells bound insulin or IGF-I with high affinity. However, responses to these ligands were asymmetrical, in that binding of IGF-I inhibited subsequent binding of insulin, but prior binding of insulin did not affect the affinity for IGF-I. The existence of hybrid receptors in normal tissues could have important implications for metabolic regulation by insulin and IGF-I.     

Low number of insulin receptors but high receptor protein content in adipose tissue of rats with monosodium glutamate-induced obesity

In order to better understand the mechanisms leading to insulin resistance, the number of fat tissue insulin receptors, their affinity and insulin receptor protein in rats with monosodium glutamate-induced obesity were studied. Obese rats displayed significantly lower number of insulin receptors with high affinity. Surprisingly, the amount of insulin receptor protein was significantly elevated in these animals. The same relations have been already reported for angiotensin II binding and AT1 receptor protein in the same model of obesity. Therefore we suggest an existence of general defect of adipocyte cell membrane in monosodium glutamate-induced obesity characterized by the presence of high quantity of impaired receptor protein.     

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.     

Time dependent effects of dexamethasone on serum insulin level and insulin receptors in rat liver and erythrocytes

The effects of glucocorticoid excess on regulation of insulin receptors were investigated in dexamethasone-treated rats. Glucocorticoid excess was produced by administration of dexamethasone (0.5 mg/100 g b.w.) 30 min, 4, 12, 18, 24, 42 or 70 h before experiments. This treatment caused time-dependent changes of glucose and insulin concentration in blood, as well as in amounts of specific insulin binding and insulin receptors of liver cells and erythrocytes. The time intervals in which dexamethasone produced the increase in insulin concentration were accompanied with decrease in insulin binding to receptors in membranes of liver cells, while significant changes in insulin binding to receptors of erythrocytes were not observed under the same experimental conditions. The effect is maximal 18 and 42 h after dexamethasone treatment that increase insulin blood level by about 85% and 60%, respectively. Receptor analysis revealed that changes in specific binding of insulin could be due to significant changes in amount of binding sites on cell surface rather than to mild alteration in receptor affinity. These findings suggest that besides the changes in insulin level, the alterations in insulin receptor number and affinity may play a major role in the states of altered insulin sensitivity which accompany glucocorticoid excess.     

Effects of growth and insulin treatment on the levels of insulin receptors and their mRNA in Hep G2 cells

We have studied the variations in the number of insulin receptor and insulin receptor mRNA levels in (Hep G2) cells in response to growth and insulin treatment. The levels of insulin receptors are relatively low in growing cells. After approximately 5 days in culture, if cells are not refed they cease to divide and the number of receptors/cell increases, reaching 4 times the initial values by the 9th day. Refeeding the cells completely prevented both growth arrest and the increase in insulin receptor number. Insulin added daily to cells at 0.33 microM caused receptor down-regulation but did not prevent a 3-fold increase in binding with growth arrest. Pulse-chase studies of metabolically labeled ([35S]methionine) cells showed that the receptor degradation rate (apparent t 1/2, 18-20 h) was comparable in rapidly growing versus growth-arrested cells. The increased receptor level in non-refed cells is not due to generation of a soluble factor by confluent cells, nor is it caused by depletion of insulin, glucose, or insulin-like growth factor I from the culture medium. The levels of insulin receptor mRNA measured on Northern blots increased in growth-arrested cells in parallel to the increase in receptor number. The mRNA value begins to increase from the 3rd day in culture and by the 9th day reaches a level 6.0 times that on the 3rd day. Chronic insulin-induced receptor down-regulation did not alter insulin receptor mRNA levels at any time point studied. These data demonstrate that the increase in insulin receptor number/cell in growth-arrested cells is paralleled by an increase in insulin receptor mRNA content with no change in the receptor degradation rates. This suggests that the increase in the number of insulin receptors is due to enhanced receptor synthesis due to increased receptor mRNA content. Conversely, down-regulation of the insulin receptor does not affect the level of insulin receptor mRNA and thus must be due to increased receptor degradation.     

Stoichiometric translocation of adipocyte insulin receptors from the cell-surface to the cell-interior. Studies using a novel method to rapidly remove detergent and concentrate soluble receptors

A rapid one-step method was developed for harvesting and concentrating insulin receptors from solubilized adipocytes, which entails precipitating soluble receptors with polyethylene glycol and resuspending the receptor-containing pellet in a reduced volume of binding buffer. With this procedure 90-100% of receptors were recovered, while 80% of cellular protein was removed, thus resulting in a marked reduction of both ligand and receptor proteases and about a 5-fold purification of the receptor. More importantly, greater than 98% of the Triton X-100 detergent was removed during this procedure so that the reduced receptor affinity observed in solubilized extracts (due to detergent) was restored to normal. Reconstituted receptors exhibited normal binding characteristics similar to those observed for plasma membrane receptors. The general utility of our receptor precipitation-reconstitution method is highlighted by studies on insulin-induced translocation of receptors from the cell-surface to the cell-interior of adipocytes and studies on the assessment of the binding affinity of nascent intracellular receptors. The results of these studies are consistent with the following. 1) Insulin initiates endocytotic uptake of insulin receptors, which then recycle back to the cell-surface. 2) Chloroquine impairs the recycling of internalized receptors while preventing receptor degradation, resulting in the progressive trapping and accumulation of receptors within cells during insulin treatment. 3) Receptor translocation during acute insulin-induced down-regulation is stoichiometric in that receptors lost from the cell-surface can be quantitatively recovered within the cell-interior. 4) In the absence of ligand, these receptors within adipocytes are mainly newly synthesized receptors enroute to the cell-surface, and they possess an affinity similar, if not identical, to mature receptors on the plasma membrane.     

Changes in glycosylation alter the affinity of the human transferrin receptor for its ligand

When transferrin receptors of human erythroleukemic cells were pulse-labeled with [35S]methionine and then chased in the absence of radioactive precursor, the first detectable immunoprecipitable form of the receptor had a molecular mass of 85 kDa. This form of the receptor was converted to the mature form of 93 kDa with a half-time of about 40-60 min. Both the immature (85 kDa) and mature (93 kDa) receptors associated as dimers, the native form of the receptor. The 85-kDa, as well as the 93-kDa, receptors bound to a monoclonal antibody raised against the transferrin receptor or to transferrin-Sepharose. In order to determine whether glycosylation was necessary for ligand binding, purified receptors were isolated from cells grown in the presence of tunicamycin. When K562 cells were grown in the presence of tunicamycin, an 80-kDa nonglycosylated form of the receptor was synthesized. This nonglycosylated receptor was also capable of dimer formation; however, much less of it reached the cell surface than the fully glycosylated form, although both untreated and tunicamycin-grown cells appeared to synthesize transferrin receptors at similar rates. Although the number of receptor molecules/cell was similar in control and tunicamycin-treated cells, the nonglycosylated receptors exhibited a much lower affinity for transferrin than those of untreated cells; in contrast, when receptors were purified by immunoprecipitation and digested with bacterial alkaline phosphatase, no difference was observed between the affinity of these receptors and undigested immunoprecipitated receptors. These results suggest that glycosylation is not necessary for specific binding of transferrin to its receptor, but the affinity of this binding can be influenced greatly by the presence or absence of carbohydrate residues.