Effect of insulin on glucose oxidation and amino isobutyric acid transport and binding of insulin in chicken thymocytes

In chicken thymocytes isolated from 15–40 day-old chickens, after a 2 h incubation at 37°C, insulin stimulated amino isobutyric acid uptake (maximal response: 40–50% of increase at 1 μg insulin/ml and half maximal response at 60 ng/ml) by specifically stimulating the influx without altering the efflux. Insulin also stimulated glucose oxidation (maximal response: 11% of increase at 1 μg insulin/ml). Binding of ¹²⁵I-labelled chicken insulin to thymocytes was rapid and higher at 15°C than at 37°C. At steady state, (90 min at 15°C), chicken, porcine and goose insulins were equipotent in inhibiting the binding of ¹²⁵I-labelled chicken insulin. Maximal binding capacity was estimated at 1250 pg insulin/10⁸ cells, i.e., 1250 binding sites/cell with an apparent dissociation constant of 200 ng insulin/ml at 15°C. Degradation of ¹²⁵I-labelled chicken insulin in the incubation medium was negligible at 15°C but very noticeable at 37°C. Therefore, the low level of insulin binding at 15°C reflects a true scarcity of insulin receptors in chicken thymocytes as compared to rat thymocytes.     

Binding and degradation of 125I-labeled insulin by a clonal line of rat pituitary tumor cells

Receptor sites for insulin on GH₃ cells were characterized. Uptake of ¹²⁵I-labeled insulin by the cells was dependent upon time and temperature, with apparent steady-states reached by 120, 20 and 10 min at 4, 23 and 37°C, respectively. The binding sites were sensitive to trypsin, suggesting that the receptors contain protein. Insulin competed with ¹²⁵I-labeled insulin for binding sites, with half-maximal competition observed at 5 nM insulin. Neither adrenocorticotropic hormone nor growth hormone competed for ¹²⁵I-labeled insulin binding sites. ¹²⁵I-labeled insulin binding was reversible, and saturable with respect to hormone concentration. ¹²⁵I-labeled insulin was degraded at both 4 and 37°C by GH₃ cells, but not by medium conditioned by these cells. After a 5 min incubation at 37°C, products of ¹²⁵I-labeled insulin degradation could be recovered from the cells but were not detected extracellularly. Extending the time of incubation resulted in the recovery of fragments of ¹²⁵I-labeled insulin from both cells and the medium. Native insulin inhibited most of the degradation of ¹²⁵I-labeled insulin suggesting that degradation resulted, in part, from a saturable process. At steady-state, degradation products of ¹²⁵I-labeled insulin, as well as intact hormone, were recovered from GH₃ cells. After 30 min incubation at 37°C, 80% of the cell-bound radioactivity was not extractable from GH₃ cells with acetic acid.     

Insulin binding in human skeletal muscle

Insulin binding to crude plasma membranes derived from human skeletal muscle was characterized. Incubations were performed for 22 h at 4°C. Typical insulin binding characteristics were found, i.e., (a) specificity for insulin, (b) pH sensitivity, (c) dissociation of insulin by the addition of excess insulin and (d) concave Scatchard curves. Half-maximal inhibition of ¹²⁵I-labeled-insulin binding occurred at 1 · 10^?8 M. Affinity constants were 0.76 · 10⁹ and 0.02 · 10⁹ M^?1 for the high- and low-affinity receptor (2-site model), respectively, and the corresponding receptor numbers were 89 and 1450 fmol/mg protein, respectively. The procedures employed permit the determination of insulin binding to small quantities of human muscle (approx. 250 mg).     

Studies on the inhibitory effect of bacitracin on 125I-labelled insulin internalization in the rat hepatocyte

Previous studies have suggested that transglutaminase has a role in the internalization of some polypeptide hormones and is inhibited by the antibiotic, bacitracin. Bacitracin has been used in insulin-receptor studies to inhibit extracellular degradation of ¹²⁵I-labelled insulin. The aim of this study was to investigate bacitracin's effect on ¹²⁵I-labelled insulin-receptor interactions in isolated rat hepatocytes. 1 g/l bacitracin increased cell-associated ¹²⁵I-labelled insulin at 20, 30 and 37°C (P < 0.001, 0.0005 and 0.0005, respectively). At 5 and 15°C (internalization does not occur), bacitracin did not affect cell-associated ¹²⁵I-labelled insulin. The bacitracin effect was concentration dependent, increasing to 2 g/l. Scatchard analysis showed that bacitracin did not alter insulin receptor affinity or number. 1 g/l bacitracin abolished the effect of chloroquine. The increased cell-associated radioactivity with bacitracin was surface-bound in nature. 0.5 g/l bacitracin decreased ¹²⁵I-labelled insulin degradation in hepatocyte suspensions (P < 0.001) and in buffer previously incubated with hepatocytes (P < 0.0005). More ¹²⁵I-labelled insulin remained associated with cells during dissociation studies at 37°C when the buffer contained 1 g/l bacitracin. Label that appeared in the buffer after 60 min was significantly more intact in the presence of bacitracin (P < 0.025). These results suggest that bacitracin retards the internalization of ¹²⁵I-labelled insulin in isolated rat hepatocytes.     

Properties of human growth hormone binding sites solubilized from female rabbit kidney

Human growth hormone binding sites from female rabbit kidney microsomes were solubilized by treatment with the nonionic detergent Triton X-100. The binding of ¹²⁵I-labelled human growth hormone to the solubilized sites retains many of the properties observed in the particulate fraction, such as saturability, reversibility, high affinity and structural specificity. The association and the dissociation process are time- and temperature-dependent. The association rate constant, k₁, is 1.6·10⁷ mol^?1·l·min^?1 at 25°C, and the dissociation rate constant, k_?1, is 2.8·10^?4 min^?1 at 25°C. Solubilization causes an increase in affinity as well as in binding capacity. Scatchard plots from saturation curves suggest the presence of a single class of binding site with a dissociation equilibrium constant, K_d, of 1.3·10^?11 M and a binding capacity of 133 fmol/mg of protein. Similar results were obtained from competition experiments. Specificity studies revealed the lactogenic characteristics of the solubilized sites. The Stokes radii of the free binding sites and of the ¹²⁵I-labelled human growth hormone-binding site complex, determined on a Sepharose CL-6B column, are 57 and 53 Å, respectively.     

Internalization of insulin and its receptor in the isolated rat adipose cell: Time-course and insulin concentration dependency

The time-course and insulin concentration dependency of internalization of insulin and its receptor have been examined in isolated rat adipose cells at 37°C. The internalization of insulin was assessed by examining the subcellular distribution of cell-associated [¹²⁵I]insulin among plasma membrane, and high-density (endoplasmic reticulum-enriched) and low-density (Golgi-enriched) microsomal membrane fractions prepared by differential ultracentrifugation. The distribution of receptors was measured by the steady-state exchange binding of fresh [¹²⁵I]insulin to these same membrane fractions. At 37°C, insulin binding to intact cells is accompanied initially by the rapid appearance of intact insulin in the plasma membrane fraction, and subsequently, by its rapid appearance in both the high-density and low-density microsomal membrane fractions. An apparent steady-state distribution of insulin per mg of membrane protein among these subcellular fractions is achieved within 30 min in a ratio of 1:1.54:0.80, respectively. Concomitantly, insulin binding to intact cells is associated with the rapid disappearance of approx. 30% of the insulin receptors initially present in the plasma membrane fraction and appearance of 20–30% of those lost in the low-density microsomal membrane fraction. However, the number of receptors in the high-density microsomal membrane fraction does not change. This redistribution of receptors also appears to reach a steady-state within 30 min. Both processes are insulin concentration-dependent, correlating with receptor occupancy in the intact cell, and are partially inhibited at 16°C. While the steady-state subcellular distributions of insulin and its receptor do not correlate with that of acid phosphatase, chloroquine markedly increases the levels of insulin associated with all three membrane fractions in apparent proportion to the distribution of this lysosomal marker enzyme activity, without more than marginally potentiating insulin's effects on the distribution of receptors. These results demonstrate that insulin, initially bound to the plasma membrane of the isolated rat adipose cell, is rapidly translocated by a receptor-mediated process into at least two intracellular compartments associated with the cell's high- and low-density microsomes. Furthermore, insulin simultaneously induces the translocation of its own receptor from the plasma membrane into the latter compartment. These translocations appear to represent the internalization and partial dissociation of the insulin-receptor complex through insulin-induced receptor cycling.     

Muscarinic receptors in pancreatic islets of the rat: Demonstration and dependence on long-term glucose environment

The presence of muscarinic receptors in islets of Langerhans was assessed by measurement of specific binding of [³H]methylscopolamine. Specific binding was defined as total binding minus binding obtained in the presence of 1000-fold or higher excess of unlabeled methylscopolamine. At 37°C specific binding was significant after 1 min and plateaued after 10 min of incubation. Displacement of label by increasing concentrations of unlabeled methylscopolamine indicated a dissociation constant of 1.5·10^?12 M. Effects of methylscopolamine on insulin release were evaluated from the inhibitions of cholinergic-induced insulin release. 4·10^?10 M methylscopolamine inhibited acetylcholine (20 μM)-induced insuliln release more than 60%. Binding was not influenced by the following variations during binding incubations: changing the glucose concentration from 0 to 83 mM, adding rotenon (1 μM) or omitting calcium from the incubation medium. Islets kept in tissue culture exhibited higher binding when cultured at 11.1 than at 3.3 mM glucose for 96 h. It is concluded that islets contain muscarinic receptors, the binding to which can be subject to alteration by the long-term glucose environment.     

Vicia graminea lectin binding to human M and N erythrocytes

The mode of binding of Vicia graminea¹²⁵I-labelled lectin to human M and N erythrocytes at 4°C has been investigated. The labelled lectin retained the full activity of native lectin. Lectin association at 4°C was characterized by a $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ of 3 to 5 min, reaching steady-state within 15 min. Incubation of cells for 15 min at 4°C with increasing concentrations of Vicia graminea¹²⁵I-labelled lectin showed that saturation binding occurred. Scatchard analysis of equilibrium data determined over a wide range of lectin concentrations yielded a curvilinear plot with an upward concave slope; this representation indicated that there was not a single homogeneous class of noninteracting binding sites. This result could indicate two or more independent classes of binding sites or one class of interacting sites exhibiting negative cooperativity. Since unlabelled lectin, which at the concentration used, rapidly binds to available receptors, did not affect the dissociation rate of the labelled lectin and since identical Scatchard plots were found using native and formaldehyde-fixed erythrocytes we conclude that there are two classes of independent Vicia graminea binding sites on human erythrocytes. Computer analysis of the Scatchard plots gave high- and low-affinity constant (7.07±1.1) · 10⁷ M^?1 and (0.2±0.01) · 10⁷ M^?1, respectively, for N erythrocytes and (1.13±0.18) · 10⁷ M^?1 and (0.24±0.01) · 10⁷ M^?1, respectively for the M cells. N erythrocytes were estimated to have 0.085 · 10⁵ high-affinity and 2.1 · 10⁵ low-affinity sites and M erythrocytes, 0.011 · 10⁵ high affinity and 0.13 · 10⁵ low-affinity sites. N cells therefore have 10-times as many sites as M cells. Studies of the dissociation of ¹²⁵I-labelled lectin from N and M cells in the presence of unlabelled lectin gave dissociation rate constants of 51 · 10^?4 s^?1 and 1.97 · 10^?4 s^?1 for the high- and low-affinity sites of N cells and 13 · 10^?4 s^?1 and 1.6 · 10^?4 s^?1 for the high- and low-affinitym sites of M cells, indicating that the binding of Vicia graminea lectin to human erythrocytes is reversible.     

Characterization of the parathyrin receptor in renal plasma membranes by labelled hormones and labelled antibody binding techniques

The parathyrin receptor in renal cortex has been investigated by studying the binding of ¹²⁵I-labelled parathyrin, or of unlabelled parathyrin detected with ¹²⁵I-labelled antibodies, to a partially purified plasma membrane fraction. The kinetics of hormone uptake demonstrated a biphasic response in both systems at 22 °C but this phenomenon was not detectable at 37 °C. Specific displacement of lactoperoxidase labelled ¹²⁵I-labelled parathyrin occurred with 8 ng unlabelled bovine parathyrin. The apparent affinity constant was $\text{2.3 · 10}{}^8\text{M}{}^{\mathrm{?1}}$ and the apparent binding capacity of the membranes 1.25 pmol/mg protein. Using the labelled antibody technique the receptor showed maximal binding at pH 7.0–7.5. As little as 80 pg bovine parathyrin produced a significant increase in binding of labelled anti-bovine parathyrin antibody and saturation of binding sites was demonstrated at 2.5 pmol/mg protein. Oxidized hormone showed undetectable binding. Treatment of membranes with phospholipases A or D, or Trypsin greatly reduced subsequent hormone binding. Prior incubation of membranes with 1–34 synthetic parathyrin decreased the binding of intact hormone whereas gastrin, insulin and glueagon had no effect. Growth hormone and calcitonin slightly increased parathyrin binding.     

Insulin receptors in rat brain cortex. Kinetic evidence for a receptor subtype in the central nervous system

Binding kinetics of porcine ¹²⁵I-insulin were studied in synaptosomal and microsomal fractions of rat brain cortex. Receptor binding was temperature- and pH-dependent with optimum at 4°C and pH 8.0–8.3. At 15°C, steady state binding was heterogenous, and Scatchard analysis revealed two classes of receptors with K_d of 2 nmol/l and 40 nmol/l in amounts of 50 pmol/g and 200 pmol/g of membrane protein. Dissociation kinetics were biexponential with $\text{T}\text{1}\text{2}$ of about 5 min and 180 min, and in contrast to other cell-types, not influenced by negative cooperativity. No receptor-mediated insulin degradation was detectable at 37°C in the presence of bacitracin. Insulin analogues inhibited ¹²⁵I-insulin binding with potencies relative to porcine insulin (%): human insulin 100, rat insulin (I+II) 71, coypu insulin 47, rat multiplication stimulating activity 8, porcine proinsulin 5, among which the three last values were significantly higher than in rat liver and fat cells. No competition was observed with porcine relaxin and mouse nerve growth factor up to about 1 μmol/l. Receptors were present in all regions of central nervous system with highest concentrations in the cerebral cortex, cerebellum and olfactory bulb, and lowest in the pons, medulla oblongata and spinal cord. In conclusion, insulin receptors in rat brain cortex are functionally different from other tissues regarding the insulin specificity and the absence of negative cooperativity. It is suggested that an insulin receptor subtype in rat brain mediates the growth activity of insulin on nerve cells.     

Distribution of insulin receptors among mouse liver endomembranes

Specific binding of insulin to highly purified preparations of rough endoplasmic reticulum, Golgi apparatus, and plasma membrane of mouse liver was determined. ¹²⁵I-labeled insulin bound maximally to the plasma membrane in radio-receptor assays. Golgi apparatus fractions exhibited binding 10–20% that of plasma membrane and rough endoplasmic reticulum exhibited only 1–2% of plasma membrane binding. Binding was proportional to membrane concentration and dose vs. response curves were very similar for the different fractions. Scatchard analysis of the insulin binding data for the plasma membrane and Golgi apparatus fractions showed curvilinear plots yielding similar apparent binding affinities (0.9 and 3.0 · 10⁸ M^?1, respectively). Purity of the isolated endomembranes was analyzed by morphometry and (Na⁺ + K⁺ + Mg²⁺)-ATPase and these preparations displayed less than 1% contamination by plasma membrane. These findings provide important confirmation of the presence of insulin receptors in Golgi apparatus membranes comparable to those located on the plasma membrane. Finally, the present study did not allow us to verify the existence of insulin receptors in the endoplasmic reticulum.     

Effect of vinblastine on the insulin-receptor interaction in mammalian heart muscle

Isolated muscle cells from adult rat heart were used to investigate the effect of microtubule modifiers on the insulin-receptor interaction in mammalian heart muscle. Preincubation of freshly isolated cells with increasing concentrations of vinblastine resulted in a dose-related inhibition of specific binding of ¹²⁵I-labelled insulin, whereas colchicine did not affect the binding reaction. Analysis of equilibrium binding data demonstrated a reduction of receptor number after treatment of cells with vinblastine. The dissociable fraction of ¹²⁵I-labelled insulin specifically bound at equilibrium was significantly reduced by preincubation with vinblastine. The results suggest involvement of microtubules in the insulin-receptor interaction in cardiac muscle.     

Effect of temperature on insulin binding and action in cultured human fibroblasts

Insulin stimulation of glycogen synthase activity and insulin binding were measured in fibroblast monolayers at 24, 32, and 37°C. Insulin stimulation of %$\text{I}$ glycogen activity increased with increasing temperature. Maximum response was greater at 37°C than at 32°C, and half maximal stimulation required at 2.0 nM insulin at 37°C vs. 10nM at 32°C. Insulin stimulation of glycogen synthase was greater and somewhat faster at 37°C than at 32°C. No insulin effect was observed at 24°C. ¹²⁵I-insulin binding to monolayers became maximal in 15 min at 37°C, 60 min at 32°C, and 120 min at 24°C. However, insulin binding decreased with increasing temperature, and this decline was due to decreased numbers of receptors. Insulin binding and stimulation of glycogen synthase were comparable at 32°C, with half maxima at 10 nM, indicating no evidence of “spare” receptors. The data indicate that temperature effects on insulin binding and action in fibroblasts are not directly related. The results also suggest that a rate limiting step(s) of insulin action is temperature sensitive, and that this step is not insulin binding.     

Binding of Doxorubicin-Conjugated Transferrin to U937 Cells

Abstract

Binding of transferrin (Trf) and its doxorubicin-conjugated forms (Conj) to U937 cells at 0°C were compared using ¹²⁵I-labelled Trf or Conj. The apparent binding affinity (K_a) of Conj to the surface of U937 cells was (1.9±0.4)·10⁸ 1/mol; it is about 40% of that of Trf [(5.0±1.2)· 10⁸ 1/mol]. Binding of ¹²⁵I-labelled ligands was blocked by the unlabelled ligands to the same degree, however, it was not blocked by a great excess of doxorubicin (Dox). N-ethylmaleimide caused about 10% inhibition while dithiothreitol was without effect. Dissociation of ¹²⁵I-labelled ligands in the presence of different concentrations of unlabelled ligands (Trf and Conj in the all 4 variations) resulted in different R₅₀ values (the concentration of the unlabelled ligand where 50% of the radiolabelled ligand was released). While Trf displaced Trf with an R₅₀ value close to the binding affinity, Conj displacement by Conj occurred with much lower efficiency. The heterolog displacement experiments yielded R₅₀ values inbetween the two extrema. These results suggest that 1) binding of Conj to the surface of cells is     

Characterization of specific binding sites for vasoactive intestinal peptide in rat intestinal epithelial cell membranes

Specific binding sites for vasoactive intestinal peptide were characterized in plasma membranes from rat intestinal epithelial cells. At 30°C, the interaction of ¹²⁵I-labelled peptide with intestinal membranes was rapid, reversible, specific and saturable. At equilibrium, the binding of ¹²⁵I-labelled peptide was competitively inhibited by native peptide in the 3 · 10^?11?3 · 10^?7 M range concentration. Scatchard analysis of binding data suggested the presence of two distinct classes of vasoactive intestinal peptide binding sites: a class with a high affinity K_d = 0.28 nM) and a low capacity (0.8 pmol peptide/mg membrane protein) and a class with a low affinity (K_d = 152 nM) and a high capacity (161 pmol peptide/mg membrane protein). Secretin competitively inhibited binding of ¹²⁵I-labelled peptide but its potency was 1/1000 that of native peptide. Glucagon and the gastric inhibitory peptide were ineffective. The guanine nucleotides, GTP and Gpp(NH)p inhibited markedly the interaction of ¹²⁵I-labelled peptide with its binding sites, by increasing the rate of dissociation of peptide bound to membranes. The other nucleotides triphosphate tested (ATP, ITP, UTP, CTP) were also effective in inhibiting binding of ¹²⁵I-labelled peptide to membranes but their potencies were 1/100-1/1000 that of guanine nucleotides.The specificity and affinity of the vasoactive intestinal peptide-binding sites in plasma membranes prepared from rat intestinal epithelial cells, which is in agreement with an adenylate cyclase highly sensitive to the peptide recently characterized in these membranes (Amiranoff, B., Laburthe, M., Dupont, C. and Rosselin, G. (1978) Biochim. Biophys. Acta 544, 474–481) further argue for a physiological role of the peptide in the regulation of intestinal epithelial function.     

Characterization of insulin binding sites in cultured smooth muscle cells of rat aorta

Insulin receptors could be demonstrated in cultured smooth muscle cells of rat aorta. The specific binding of 125I-insulin was time-, temperature- and pH-dependent. The optimal temperature for our studies was 12 degrees C. At this temperature maximal specific binding was 0.5% of total counts at 120 min incubation. The pH-optimum for the binding process was between 7.5 and 8. Degradation of 125I-insulin at 12 degrees C was 14%, no degradation of binding sites could be measured at this temperature. Dissociation of 125I-insulin was rapid. 50% of the labeled hormone remained associated with the cells. Half-maximal inhibition of 125I-insulin binding was produced by insulin at 4 X 10(-11) mol/l. Scatchard-analysis gave curvilinear plots, that may suggest negative cooperativity. Specificity of binding was studied in competition experiments between 125I-insulin, insulin, proinsulin, insulin-like growth factors and human growth hormone. Half-maximal inhibition of 125I-insulin binding was produced by proinsulin at 2 X 10(-9) mol/l and by insulin-like growth factors at 9 X 10(-9) mol/l. Human growth hormone had no significant effect on the insulin binding.     

Insulin degradation by human skeletal muscle

Although previous studies from this and other laboratories have extensively characterized insulin degrading activity in animal tissues, little information has been available on insulin responsive human tissues. The present study describes the insulin degrading activity in skeletal muscle from normal human subjects. Fractionation of a sucrose homogenate of skeletal muscle demonstrated that 97% of the total neutral insulin degrading activity was in the 100 000 × g supernatant with no detectable glutathione-insulin transhydrogenase activity. The 100 000×g pellet contained 85% of the total acid protease activity and all the glutathione-insulin transhydrogenase activity. The soluble insulin degrading activity was purified 1400-fold by ammonium sulfate fractionation, molecular exclusion, ion-exchange and affinity chromatography. Enzymatic activity was determined by measuring an increase in trichloroacetic acid-soluble products of the ¹²⁵I-labeled hormone substrates. The purified enzyme showed marked proteolytic specificity for insulin with a K_m of 1.63·10^?7 M (±0.32) and was competitively inhibited by proinsulin and glucagon with K_i values of 2.1 · 10?⁶ M and 4.0 · 10^?6 M, respectively. This insulin protease exhibited a pH optimum between 7 and 8, a molecular weight of 120 000 and was capable of degrading glucagon. Inhibition studies demonstrated that a sulfhydryl group is essential for activity. Molecular exclusion chromatography of [¹²⁵I]insulin degraded products revealed a time-dependent increase in degradation products with molecular weights intermediate between intact insulin and iodotyrosine. These studies demonstrate that the major enzymatic system responsible for insulin degrading activity is a soluble cysteine protease capable of rapidly metabolizing insulin under physiologic conditions.     

Effect of acute zinc deficiency on insulin receptor binding in rat adipocytes

Considerable data have been reported on the relationship between insulin resistance and zinc deficiency. In this study, insulin receptor binding was measured in isolated rat adipocytes. Two assays were carried out at 37°C (binding and internalization) and 16°C (binding) using¹²⁵I insulin 0.05–20 nM. A decreased insulin receptor binding was observed in zinc-deficient rat adipocytes, but we could not make any distinction between the specific zinc depletion effects and the effects of the caloric restriction induced by zinc deficiency.     

Evidence for reutilization of surface receptors for alpha-macroglobulin.protease complexes in rabbit alveolar macrophages

Rabbit alveolar macrophages internalize α-macroglobulin ¹²⁵I-trypsin complexes subsequent to binding of complexes to high affinity surface receptors. Cells were capable of accumulating a 5–10 fold greater amount of αM · ¹²⁵I-T at 37°C than at 0°C. At 0°C cell-bound αM · ¹²⁵I-T was bound solely to surface receptors, whereas at 37°C the majority (85%) of cell-bound radioactivity was intracellular. The temperature-dependent accumulation of αM · ¹²⁵I-T did not reflect a change in surface receptor number or ligand-receptor affinity. Rather, the greater rate of uptake reflected continued internalization of αM · ¹²⁵I-T complexes. At 37°C cells took up 5–9 fmole αMT per μg cell protein per hr, whereas binding to surface receptors accounted for 0.5–0.7 fmole per μg cell protein. Once bound to surface receptors internalized αM · ¹²⁵I-T was localized in lysosomes, where it was degraded at a rate of 35–45% per hr. Following binding of αM · T to receptors at 37°C, but not at 0°C, unoccupied receptors could be found on the cell surface. Using cycloheximide to probe receptor turnover, I calculated that receptors were replenished at a rate of 15% per hr. Cells incubated in the presence of cycloheximide exhibited unaltered ligand uptake and catabolism for hours. Thus the reappearance of receptor activity during ligand uptake was not primarily due to de novo receptor synthesis. The rate of ligand uptake was a function of the number of surface receptors. Measurement of αM¹²⁵I-T binding to subcellular fractions did not reveal the presence of any intracellular reservoir of receptors. These observations are consistent with the hypothesis that continued ligand uptake reflects receptor reutilization.