N epsilonB29-(+)-biotinylinsulin and its complexes with avidin. Synthesis and biological activity

Insulin was modified with d-biotin-N-hydroxysuccinimide ester in dimethylformamide. Mono-, di-, and triacylated insulins were separated by preparative isoelectric focusing. Monoacylated derivatives (isoelectric point 5.1) were fractionated twice on DEAE-cellulose to yield pure N epsilonB29-biotinylinsulin. The structure of the product was established by amino acid analysis before and after deamination. N epsilonB29-biotinylinsulin had biological activity indistinguishable from insulin on glucose oxidation and lipid synthesis assays using isolated rat epididymal fat cells. Complexes of N epsilonB29-biotinylinsulin with avidin, having essentially all but one binding site filled with biotin, were prepared in order to obtain a 1:1 insulin:avidin ration. The elicited identical maximal biological responses, but showed a potency decreased to 5% of that of insulin. Such complexes conjugated with ferritin will provide a useful tool in the development of electron microscopic stains of insulin receptors.     

Synthesis and evaluation of photolabile insulin prodrugs

We have developed two photolabile insulin prodrugs, insulin-2P and insulin-3P. These prodrugs were synthesized by protecting GlyA1 (N(alphaA1)), and one or both of the PheB1 (N(alphaB1)) and LysB29 (N(epsilonB29)) amino groups in insulin using 5'-(alpha-methyl-nitro-piperonyl)oxy-carbonyl as the protecting group. These insulin prodrugs were efficiently activated by exposure to longwave UV light to produce insulin quantitatively. Using 2-deoxyglucose uptake assays, both di- and tri-protected compounds were less active than native insulin in the protected state, and showed comparable activity to native insulin upon photoactivation.     

Ligands for insulin receptor isolation

Biotinylated insulins are bivalent molecules having the ability to bind to insulin receptors on the one hand and to "avidins" on the other. In order to be useful as ligands for insulin receptor isolation, biotinylated insulins must be developed that have the capacity to bind simultaneously to both and insulin receptor. The present investigation addresses this problem. A series of biotinylated and dethiobiotinylated insulins has been prepared in which the distance between the biotin carboxyl group and the insulin varies from 7 to 20 atoms. These compounds form complexes with succinoylavidin. The dissociation rates (K-1) of these complexes have been determined from the [14C]biotin exchange assay. The dissociation kinetics of most of these complexes are biphasic, and the kinetic constants reported are those corresponding to the slow rate. Ligands containing dethiobiotin dissociate more rapidly than the corresponding biotin derivatives. The interposition of a spacer arm substantially decreases the rate of dissociation. The [14C]biotin exchange assay could not be used with streptavidin complexes of the above ligand since biotin dissociates more rapidly from streptavidin than from succinoylavidin. However, the relative dissociation rates of a series of ligands could be determined and were as follows: 6-(dethiobiotinylamido)-hexanoic acid greater than dethiobiotinyl-A1-insulin greater than biotinylinsulin greater than biotinyl-A1-insulin greater than biotinyl-A2-insulin. Dethiobiotin and its amide failed to form complexes with streptavidin. The affinity of the ligands for insulin receptors was determined by measuring their ability to stimulate 14CO2 formation from [1-14C]glucose in rat epididymal adipocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Homogeneous functional insulin receptor from 3T3-L1 adipocytes. Purification using N alpha B1-(biotinyl-epsilon-aminocaproyl)insulin and avidin-sepharose

Insulin receptor was purified 10,000-fold from cultured mouse 3T3-L1 adipocytes in 35% overall yield. The specific activities of 125I-insulin binding and autophosphorylation increased in parallel, following the initial Triton X-100 extraction of membranes. The isolation protocol, performed entirely at pH 8.45, entailed adsorption by avidin-Sepharose CL-4B of a complex formed between Triton X-100-solubilized insulin receptor and N alpha B1-(biotinyl-epsilon-aminocaproyl)insulin, and the specific elution of the complex with biotin. The avidin-Sepharose CL-4B was a partially denatured preparation, showing estimated dissociation constants of 0.2 microM for biotin and approximately 1 microM for the bifunctional ligand at, pH 7, 4 degrees C. The bifunctional ligand was characterized by 70% competency in binding to avidin, 100% competency in binding to solubilized insulin receptor, full stimulation of autophosphorylation of the isolated receptor, and maximal stimulation of hexose uptake by intact 3T3-L1 adipocytes. The insulin binding properties of the insulin receptor were uniform throughout this purification procedure. At pH 8.45, 4 degrees C, an average Kd = 0.72 nM was determined for a single class of noninteracting insulin binding sites. The apparent autophosphorylation of the beta-subunit was also unchanged following affinity chromatography. A single oligomeric structure was established for the purified receptor, composed only of 135,000- and 95,000-Da subunits, whose association was lost by denaturation in the presence of reducing agent. This single structure occurred in the initial Triton X-100 extract. The purified insulin receptor was capable of autophosphorylating the beta-subunit and catalyzed phosphorylation of protein substrates.     

Insulin receptors are bivalent as demonstrated by photoaffinity labeling.

Insulin receptors in human placental membranes were photoaffinity-labeled with a radioactive human insulin-like growth factor I (hIGF-I) photoprobe N epsilon B28-monoazidobenzoyl 125I-hIGF-I either alone or together with a non-radioactive insulin photoprobe N epsilon B29-monoazidobenzoyl insulin. Precipitation of the solubilized receptors with anti-insulin antibody showed that receptors labeled with the radioactive hIGF-I photoprobe were detected in the immunoprecipitate only when photolabeling was carried out in the presence of the non-radioactive insulin photoprobe. Comparable results were obtained in converse experiments using a radioactive insulin photoprobe N epsilon B29-monoazidobenzoyl 125I-insulin, a non-radioactive hIGF-I photoprobe N epsilon B28-monoazidobenzoyl hIGF-I, and an antibody to hIGF-I. The amount of radioactive receptors precipitated by either the anti-insulin antibody or the anti-hIGHF-I antibody was close to the expected amount. These observations demonstrate that the insulin receptor is bivalent being capable of binding two molecules of ligand.     

Peptide mapping of the insulin-binding site of the 130-kDa subunit of the insulin receptor by means of a novel cleavable radioactive photoprobe

A radioactive photoaffinity probe for the insulin receptor was prepared by derivatizing insulin at its B29 lysine with a novel crosslinking reagent having a cleavable azo linkage. Insulin receptors purified from human placental membranes were photoaffinity labeled with this probe. The photolabeled receptor was treated with dithionite to cleave the azo linkage, thereby removing the insulin ligand and transferring the radioactivity to the receptor protein. The radioactive labeled subunit was isolated and digested with elastase for peptide mapping and separation by high performance liquid chromatography. Results obtained indicated that it will be feasible to use this new photoaffinity probe to obtain radioactive peptides representing the insulin-binding site(s) on the receptor subunit.     

Hormone binding site of the insulin receptor: analysis using photoaffinity-mediated avidin complexing

A trifunctional reagent was designed which allows derivatization of ligands, particularly peptides and proteins, for subsequent photoaffinity labelling of receptors and specific isolation of the covalent complex or its fragments. B29-(2-nitro-4-azidophenyl)-biocytinyl-insulin (NB-insulin) was synthesized, radioiodinated, and the B26-mono-iodo derivative isolated by HPLC. It was used to photoaffinity label human placental membranes and the purified insulin receptor. Extensive digestion of the covalent insulin-receptor complex with trypsin (EC 3.4.21.4) led to the generation of a fragment of Mr 14,000. Specific complexing with avidin, derivatized avidin or streptavidin could be demonstrated for the photoaffinity labelled alpha-subunit and the 14,000 core fragment. The latter was isolated (approx. 100 pmol from 3-4 placentae) by streptavidin affinity chromatography and HPLC. According to microsequencing based on the known primary structure of the insulin receptor, the N-terminus of the core peptide appears to be Leu20-His21-Glu22-Leu23. We thus conclude: a part of the insulin-binding region of the receptor is located close to the N-terminus of its alpha-subunit in a remarkably stable domain of the sequence 20--(approx.) 120.     

Receptor-mediated endocytosis of insulin by cultured endothelial cells.

Label-fracture immunochemistry and pre-embedding indirect immunocytochemistry were applied to investigate insulin uptake by endothelial cells. Freeze fracture replicas showed that a small percentage of native insulin receptors are associated with non-coated pits (4%) and coated pits (2%). After warming, receptor bound insulin became increasingly associated with such endocytotic vesicles. After 2 min the percentage of detectable insulin associated with non-coated and coated pits increased to 16% and 8%, respectively. Pre-embedding immunocytochemical localization of insulin gave results consistent with those obtained from the label-fracture studies. Both non-coated and coated vesicles appeared labelled after 5 min of warming. Non-coated vesicles contained 25% of the cell associated insulin while 9% was associated with coated pits and vesicles. After 10 min of warming, 9% of label was located in non-coated vesicles and 7% in coated vesicles. A large proportion (29%) of the label was found in tubular-vesicular endosomes at this time. After 15 min of warming, 30% of the remaining cell-associated gold label was found in multivesicular bodies. These experiments demonstrate that insulin uptake by endothelium is mediated by both coated and non-coated vesicles and that, once internalized, insulin is routed through endosomal pathways that primarily result in transcytosis.     

Polylysine increases the number of insulin binding sites in soluble insulin receptor preparations

The effects of cationic polyamino acids on insulin binding to soluble insulin receptor preparations were studied. Incubation of partially or fully purified receptor preparations with polylysine (pLys) increased by several-fold the amount of [125I]insulin that remained associated with the receptor, as determined both by precipitation of receptor-insulin complexes by polyethylene glycol or by separation of the complexes from the free hormone by gel filtration. This elevation in the amount of bound insulin resulted from increased number of insulin binding sites, and could not be attributed to an increased affinity of the receptors to insulin. In fact, pLys reduced 2-3-fold the affinity of insulin binding to its receptor as determined by equilibrium binding studies, and by monitoring the rate of exchange of bound [125I]insulin with unlabeled hormone. pLys induced specific interactions between insulin and its native receptor since other basic compounds such as histone, spermidine, polymixin B, compound 48/80, lysine, and arginine failed to reproduce its effects. pLys did not interact with the free ligand, nor did it promote interactions between insulin and denatured receptor forms. Furthermore, pLys did not induce binding of insulin to other proteins present in the partially purified receptor preparations. The effects of pLys were time and dose-dependent and were proportional to the pLys chain length. The longer the chain, the greater was the effect. Enhanced insulin binding and receptor beta-subunit autophosphorylation (in the presence of insulin) exhibited a similar dependency on the chain length of pLys. pLys effects on insulin binding were associated with formation of large protein aggregates that remained trapped at the top of Sephacryl S-300 columns. These aggregates contained substantial amounts of receptor-insulin complexes. Our results suggest that pLys induces formation of receptor clusters that create de novo insulin binding sites among adjacent receptor tetramers. Alternatively, formation of receptor aggregates might facilitate insulin binding to a soluble receptor subfraction that otherwise fails to bind the hormone.     

Biotinylated granulocyte/macrophage colony-stimulating factor analogues: effect of linkage chemistry on activity and binding.

Biotinylated granulocyte/macrophage colony-stimulating factor (GM-CSF) analogues with different linkage chemistries and levels of conjugated biotin were synthesized by reacting recombinant human GM-CSF with sulfosuccinimidyl 6-biotinamidohexanoate or biotin hydrazide/1-[3-(dimethylamino)-propyl]-3-ethylcarbodiimide. These chemically reactive forms of biotin produced derivatives biotinylated at amine or carboxyl groups, respectively. Amine-derivatized analogues of 1.2 and 3.8 mol of biotin/mol of protein (N1-bGM-CSF and N4-bGM-CSF) and a carboxyl-modified analogue of 4.6 mol of biotin/mol of protein (C5-bGM-CSF) were synthesized. These analogues were compared to determine the effect of biotinylation on biological activity and GM-CSF receptor binding characteristics. The biotinylated proteins migrated with the same molecular weight as the native, unmodified protein as determined by SDS-PAGE and could be detected by Western blotting with alkaline phosphatase conjugated streptavidin, thus demonstrating the biotin linkage. All three analogues retained full agonist activity relative to the native protein (EC50 = 10-15 pM) when assayed for the stimulation of human bone marrow progenitor cell growth. Cell surface GM-CSF receptor binding was characterized by the binding of the analogues to human neutrophils, with detection by fluorescein-conjugated avidin and fluorescence-activated cell sorting. The N-bGM-CSFs demonstrated GM-CSF receptor specific binding that was displaceable by excess underivatized protein, with the detected fluorescence signal decreasing with increasing biotin to protein molar ratio. In contrast, C5-bGM-CSF binding above background fluorescence could not be detected using this system, suggesting that this derivative could bind to and activate the receptor, but not simultaneously bind fluorescein-conjugated avidin. The amine-derivatized biotinylated GM-CSF analogues retained biological activity, could specifically label cell surface receptors, and may be useful nonradioactive probes with which to study GM-CSF receptor cytochemistry and receptor modulation by flow cytometry.     

Kinetics of insulin receptor transit to and removal from the plasma membrane

The heavy isotope density shift method, in combination with a procedure for labeling cell surface insulin receptors, was used to determine the rate of transit of receptor to the cell surface from their site of synthesis and to follow the net rate of receptor removal from the plasma membrane in 3T3-L1 adipocytes. To label surface receptors, 125I-insulin was bound to cells at 4 degrees C and then covalently cross-linked to the receptors with disuccinimidyl suberate. The identity of the surface-labeled product as insulin receptor was established by immunoprecipitation with antireceptor antibody and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Fully differentiated 3T3-L1 adipocytes were shifted to medium containing heavy (greater than 95% 15N, 13C and 2H) amino acids. The rates of appearance of newly synthesized heavy receptor at the cell surface and the loss of previously synthesized light receptor from the cell surface were followed by resolving labeled heavy and light surface receptors in CsCl density gradients and quantitating labeled receptor subunits by gel electrophoresis. It was shown that 2.5-3.0 h are required for newly synthesized insulin receptor to reach and become functional in the plasma membrane. Insulin-induced down-regulation of cellular insulin receptor level had no effect on the time required for the newly synthesized receptors to reach the cell surface. Down-regulation, however, increased the first order rate constants for the inactivation of cell surface insulin receptors from 0.046 to 0.10 h-1. The fact that the rate constants for inactivation of cell surface and total cellular insulin receptors were identical in the up-regulated state (0.046 and 0.044 h-1, respectively) or in the down-regulated state (0.10 and 0.096 h-1, respectively) suggests that the rate-limiting step in the receptor inactivation pathway occurs at the cell surface.     

Metabolism of covalent receptor-insulin complexes by 3T3-L1 adipocytes. Synthesis and use of photosensitive insulin analogs to study insulin receptor metabolism in cell culture

To facilitate labeling cell surface insulin receptors and analyzing their metabolism by 3T3-L1 adipocytes, a characterization of both the interaction of photosensitive insulin analogs with 3T3-L1 adipocytes and the conditions for photocross-linking these derivatives to the insulin receptor are described. The synthesis and purification of two photoaffinity analogs of insulin are presented. Both B29-lysine- and A1-glycine-substituted N-(2-nitro-4-azidophenyl)glycyl insulin compete with 125I-insulin for binding to 3T3-L1 adipocytes, and the B29-derivative retains a biological activity similar to that for native insulin. An apparatus developed for these studies permits photolysis of cells in monolayer culture using the visible region of the lamp emission spectrum. Activation of the photoderivative by this apparatus occurs with a half-life of approximately 15 s and permits rapid photolabeling of a single species of receptor of 300,000 Da. The conditions for photolabeling permit a measurement of the turnover of covalent receptor-insulin complexes by 3T3-L1 adipocytes in monolayer culture. Degradation of this complex occurs as an apparent first order process with a half-life of 7 h. A comparison with previous studies (Reed, B. C., Ronnett, G. V., Clements, P. R., and Lane, M. D. (1981) J. Biol. Chem 256, 3917-3925; Ronnett, G. V., Knutson, V. P., and Lane, M. D. (1982) J. Biol. Chem. 257, 4285-4291) indicates that in a "down-regulated" state, 3T3-L1 adipocytes degrade covalent receptor-hormone complexes with kinetics similar to those for the degradation of dissociable receptor-hormone complexes.     

Localization of the insulin-binding site to the cysteine-rich region of the insulin receptor alpha-subunit

Affinity-purified insulin receptor was photoaffinity labeled with a cleavable radioactive insulin photoprobe. Exhaustive digestion of the labeled alpha-subunit with endoproteinase Glu-C produced a major radioactive fragment of 23 kDa as a part of the putative insulin-binding domain. This fragment could contain either residues 205-316 or 518-633 of the alpha-subunit. Rat hepatoma cells and Chinese hamster ovary cells were transfected with cDNA encoding a human insulin receptor mutant with a deletion of the cysteine-rich region spanning amino acid residues 124-319. Insulin binding by these cells was not increased in spite of high numbers of the mutant insulin receptors being expressed. A panel of monoclonal antibodies which was specific for the receptor alpha-subunit and inhibited insulin binding immunoprecipitated the photolabeled 23-kDa receptor fragment but not the receptor mutant. A synthetic peptide containing residues 243-251 was specifically bound by agarose-insulin beads. We therefore suggest that the 23-kDa fragment contains residues 205-316, and that insulin binding occurs, in part, in the cysteine-rich region of the alpha-subunit.     

High molecular weight forms of the insulin receptor

The insulin receptor of liver, adipose, and placental plasma membranes was photoaffinity labeled with radioiodinated N epsilon B29-(monoazidobenzoyl)insulin. Three specifically labeled bands of 450, 360, and 260 kilodaltons (kDa) were identified in each tissue by polyacrylamide gel electrophoresis of the membranes solubilized in sodium dodecyl sulfate (SDS). The 360- and 260-kDa bands corresponded to partially reduced forms of the 450-kDa band. The distribution of radioactivity between the three insulin receptor bands was dependent on the tissue, the purity of the receptor preparation, and the conditions of solubilization in SDS. The 360- and 260-kDa bands became more prominent in each tissue with an increasing time of solubilization in SDS. However, with a short solubilization time in SDS, the 450-, 360-, and 260-kDa bands of the receptor were distributed approximately in a ratio of 85:15:0 in all three tissues. Inclusion of sulfhydryl alkylating reagents during solubilization in SDS altered this ratio to about 95:5:0. We conclude that the 450-kDa band represents the predominant form of the photolabeled insulin receptor and that the 260-kDa and probably the 360-kDa form as well were generated during the experimental manipulations preceding identification of the receptor. However, the appearance of the 360- and 260-kDa bands was not due to reductant present in SDS or buffer solutions and could not be accounted for by proteolytic degradation of the receptor. Furthermore, purification of the receptor over 2000-fold did not prevent the appearance of the 360- and 260-kDa bands.(ABSTRACT TRUNCATED AT 250 WORDS)     

Demonstration that the insulin receptor undergoes an early structural modification following insulin binding

Processing of the insulin receptor by hepatocytes was studied using a 125I-labelled photoreactive insulin derivative which could be covalently attached to the receptor and facilitate the analysis of receptor structure in isolated subcellular fractions by SDS-polyacrylamide gel electrophoresis. Following binding at the cell surface, the label was rapidly internalised and located in a low-density subcellular fraction ('endosomes'). The intact receptor (350 000 molecular weight) and binding (alpha) subunit (135 000), produced by in vitro disulphide reduction of the samples, were found in the plasma membrane fraction but not in endosomes. In endosomes, the label was concentrated in a band at 140 000 (non-reduced) which on reduction generated species of 100 000 and 68 000 predominantly. The insulin receptor therefore undergoes an early structural change during endocytosis. This modification does not involve complete disulphide reduction and may be due to a proteolytic event.     

Importance of aliphatic side-chain structure at positions 2 and 3 of the insulin A chain in insulin-receptor interactions.

In order to evaluate the cause of the greatly decreased receptor-binding potency of the naturally occurring mutant human insulin Insulin Wakayama ([LeuA3]insulin, 0.2% relative potency), we examined (by the semisynthesis of insulin analogues based on N alpha-PheB1,N epsilon-LysB29-bisacetyl-insulin) the importance of aliphatic side chain structure at positions A2 and A3 (Ile and Val, respectively) in directing the interaction of insulin with its receptor. Analogues bearing glycine, alanine, alpha-amino-n-butyric acid, norvaline, norleucine, valine, isoleucine, allo-isoleucine, threonine, tert-leucine, or leucine at positions A2 or A3 were assayed for their potencies in competing for the binding of 125I-labeled insulin to isolated canine hepatocytes, as were analogues bearing deletions from the A-chain amino terminus or the B-chain carboxyl terminus. Selected analogues were also analyzed by far-UV CD and absorption spectroscopy of Co2+ complexes. Our results identify that (a) Ile and Val serve well at position A2, whereas residues with other side chains (including those with straight chains, alternatively configured beta-branches, or a gamma-branch) exhibit relative receptor-binding potencies in the range 1-5%; (b) greater flexibility is allowed side-chain structure at position A3, with Ile, allo-Ile, alpha-amino-n-butyric acid, and tert-Leu exhibiting relative receptor-binding potencies in the range 11-36%; and (c) simultaneous replacements at positions A2 and A3, and deletions of the COOH-terminal domain of the insulin B chain in related analogues, yield cumulative effects. These findings are discussed with respect to a model for insulin-receptor interactions that involves a structure-orienting role for residue A2, the direct interaction of residue A3 with receptor, and multiple separately defined elements of structure and of conformational adjustment.     

The structure of the hepatic insulin receptor and insulin binding.

Hepatocytes or hepatic plasma membranes were photoaffinity-labelled with radioiodinated N epsilon B29-monoazidobenzoyl-insulin. Analysis of the samples by SDS/polyacrylamide-gel electrophoresis and autoradiography revealed the insulin receptor as a predominant band of 450 kDa. When hepatic plasma membranes were first treated with clostridial collagenase and then photolabelled, the insulin receptor appeared as a predominant band of 360 kDa. This effect of collagenase treatment on the insulin receptor was due to Ca2+-dependent heat-labile proteinases contaminating the preparation of collagenase, and it could be mimicked by elastase. The decrease in size of the insulin receptor to 360 kDa resulted from the loss of a receptor component that was inaccessible to photolabelling. In contrast, the size of the insulin receptor of intact cells was not affected by collagenase treatment. This suggests that the site sensitive to proteolysis was located on the cytoplasmic side of the plasma membrane. In hepatic plasma membranes that were treated with collagenase or elastase, and contained the 360 kDa form of the insulin receptor, the binding affinity for insulin was increased by up to 2-fold. These findings support the concept that a component which is either a part of, or closely associated with, the insulin receptor may regulate its affinity for insulin.     

Ligand-induced conformational change in the minimized insulin receptor

Within the class of insulin and insulin-like growth factor receptors, detailed information about the molecular recognition event at the hormone-receptor interface is limited by the absence of suitable co-crystals. We describe the use of a biologically active insulin derivative labeled with the NBD fluorophore (B29NBD-insulin) to characterize the mechanism of reversible 1:1 complex formation with a fragment of the insulin receptor ectodomain. The accompanying 40 % increase in the fluorescence quantum yield of the label provides the basis for a dynamic study of the hormone-receptor binding event. Stopped-flow fluorescence experiments show that the kinetics of complex formation are biphasic comprising a bimolecular binding event followed by a conformational change. Displacement with excess unlabeled insulin gave monophasic kinetics of dissociation. The rate data are rationalized in terms of available experiments on mutant receptors and the X-ray structure of a non-binding fragment of the receptor of the homologous insulin-like growth factor (IGF-1).     

Preparation and characterization of a colloidal gold-insulin complex with binding and biological activities identical to native insulin

We studied the binding and biological activities of gold-insulin complexes to develop a complex with properties identical to native insulin. Stabilizing amounts of insulin absorbed to 5-, 10-, or 15-nm gold particles resulted in complexes with 40-327 insulin molecules per gold particle and 4-111 times the biological activity of unlabeled insulin, based on the molar concentration of gold complex. These data suggested that these complexes behaved as multivalent ligands. Gold-insulin complexes were prepared with 5% of the stabilizing insulin concentration and were stabilized with bovine serum albumin. This resulted in a complex with 5-7 insulin molecules per 10-nm gold particle, which stimulated glucose oxidation in rat adipocytes and competed with [125I]-insulin for binding to the insulin receptor identically to unlabeled insulin on an equimolar basis. The organization and distribution of insulin receptors occupied by this monovalent-behaving gold-insulin complex were virtually identical to previous observations using monomeric ferritin-insulin. Since multivalent ligands may affect receptor binding, re-distribution, and intracellular processing, the use of electron-dense probes that resemble the unlabeled ligand in biological and binding properties is appropriate when studying receptor dynamics of in vivo or in vitro biological systems. The gold-insulin complex developed in this study should serve this function.