Effect of monoclonal antibodies on human insulin receptor autophosphorylation, negative cooperativity, and down-regulation

Three major functional characteristics of the insulin receptor are negative cooperativity, down-regulation, and beta-subunit tyrosine kinase activity. To investigate the inter-relationships among these functions we studied four antibodies to the insulin receptor alpha-subunit. These monoclonal antibodies competitively inhibited 125I-insulin binding to the insulin receptor of human IM-9 and HEP-G2 cells. When the antibodies were radiolabeled, insulin competed strongly with two antibodies (MA-10 and MA-51) for binding to the insulin receptor, but competed weakly with the two others (MA-5 and MA-20). Antibodies MA-10 and MA-51, like insulin, accelerated the dissociation of bound 125I-insulin from receptors; in contrast, MA-5 and MA-20 strongly inhibited 125I-insulin dissociation. Antibodies MA-10 and MA-51 induced down-regulation of insulin receptors with a potency similar to that of insulin. In contrast, MA-5 and MA-20 were more potent than insulin. None of the antibodies either alone or in combination influenced autophosphorylation of the insulin receptor beta-subunit. These data indicate, therefore, that two major epitopes can be identified on the alpha-subunit of the insulin receptor by the use of monoclonal antibodies. One epitope, recognized by antibodies MA-10 and MA-51, is close to or near the insulin-binding site and mimics insulin-induced negative cooperatively and down-regulation. The other epitope, recognized by antibodies MA-5 and MA-20, is at some distance from the insulin-binding site, and only mimics down-regulation. These data suggest, therefore, that: negative cooperativity and down-regulation may not be inter-related and both processes are independent of insulin receptor tyrosine kinase activity.     

Site-site interactions among insulin receptors. Characterization of the negative cooperativity.

By studying the dissociation of 125I-instulin from its receptors in the absence and phe negatively cooperative type for the insulin receptors. In the present study we extend oy purified mouse and rat liver membranes as well as in human circulating monocytes and human cultured lymphocytes demonstrated negative cooperativity that was extraordinarily simn membranes more slowly than it does from its receptors on whole cells. The dissociaty a small percentage of the receptor sites (1 to 5%), are sufficient to accelerate dissociation of hormone from receptor. At these insulin concentrations insulin is entirely monomeric, and in fact at higher concentrations of insulin (greater than 10(-7) M) where insulin dimers predominate, the cooperativity effect is progressively lost. The dissociation rate of 125I-insulin alone (that is at very low fractional saturation of receptors) was markedly accelerated by dripping the pH from 8.0 to 5.0, whereas the dissociation of 125I-insulin at high receptor occupancy was only slightly accelerated by the fall in pH. The dissociation rate was directly related to temperature, but the dissociation rate of 125I-insulin at low receptor occupancy was much more affected by reduction in temperature and showed a sharp transition at 21 degrees. Urea at concentrations as low as 1 M produced a marked acceleration of 125I-insulin dissociation. Divalent cations (calcium and magnesium) appear to stabilize the insulin-receptor interaction, since higher degrees of receptor occupancy were required to achieve a given rate of dissociation of 125I-insulin. These data make it likely that the insulin receptors exist as oligomeric structures or clusters in the plasma membrane. Insulin receptor sites appear to switch from a "slow dissociating" state to a "fast dissociating" state when their occupancy increases; the proportion of sites in each state is a function of occupancy of the receptor sites by the insulin monomer as well as of the physiochemical environment. Other models which could explain apparent negative cooperativity besides site-site interactions, i.e. polymerization of the hormone, steric or electrostatic hindrance due to ligand-ligand interactions, or unstirred (Noyes-Whitney) layers are considered unlikely in the case of insulin receptors on both experimental and theoretical grounds.     

Expression and purification of CB2 for NMR studies in micellar solution

We demonstrate feasibility of biophysical characterization of the peripheral cannabinoid receptor CB2 produced by heterologous expression in E. coli membranes. Recombinant receptor was purified by affinity chromatography, and NMR diffusion experiments performed on CB2 solubilized in dodecylphosphocholine (DPC) micelles. Circular dichroism spectroscopy indicated high alpha-helical content (49 %) of CB2.     

Reversal of insulin-induced negative cooperativity by monoclonal antibodies that stabilize the slowly dissociating ("Ksuper") state of the insulin receptor

Two monoclonal antibodies to the insulin receptor, MA-5 and MA-20, unlike other monoclonal antibodies, do not mimick the accelerating effect of insulin on the dissociation of 125I-insulin from the receptors (negative cooperativity). On the contrary, MA-5 and MA-20 markedly slow down the dissociation rate. We show now that MA-5 and MA-20 are potent antagonists of the negative cooperativity induced by insulin, and reverse the insulin-induced acceleration whether added simultaneously with insulin or after insulin. The reversal of the insulin-induced acceleration is almost immediate. These data strengthen the concept therefore that the insulin-receptor complex has access to alternative conformational states that can be stabilized by ligand-induced site-site interactions.     

Glycoprotein hormone receptors: link between receptor homodimerization and negative cooperativity

The monomeric model of rhodopsin-like G protein-coupled receptors (GPCRs) has progressively yielded the floor to the concept of GPCRs being oligo(di)mers, but the functional correlates of dimerization remain unclear. In this report, dimers of glycoprotein hormone receptors were demonstrated in living cells, with a combination of biophysical (bioluminescence resonance energy transfer and homogenous time resolved fluorescence/fluorescence resonance energy transfer), functional and biochemical approaches. Thyrotropin (TSHr) and lutropin (LH/CGr) receptors form homo- and heterodimers, via interactions involving primarily their heptahelical domains. The large hormone-binding ectodomains were dispensable for dimerization but modulated protomer interaction. Dimerization was not affected by agonist binding. Observed functional complementation indicates that TSHr dimers may function as a single functional unit. Finally, heterologous binding-competition studies, performed with heterodimers between TSHr and LH/CG-TSHr chimeras, demonstrated the unsuspected existence of strong negative cooperativity of hormone binding. Tracer desorption experiments indicated an allosteric behavior in TSHr and, to a lesser extent, in LH/CGr and FSHr homodimers. This study is the first report of homodimerization associated with negative cooperativity in rhodopsin-like GPCRs. As such, it may warrant revisitation of allosterism in the whole GPCR family.     

A short incubation time in insulin binding experiments leads to disappearance of negative cooperativity in H35 hepatoma cells

The effects of different periods of incubation (8 min vs 20 min) on insulin binding kinetics were examined in a H35 hepatoma cell line. Scatchard plots from cells incubated for 8 min were linear (r = 0.987 +/- 0.006), in contrast to curvilinear Scatchard plots from cells incubated for 20 min. Hill plots showed a slope of 1.006 +/- 0.024 for the 8 min incubation, whereas the slope was 0.827 +/- 0.0026 (p less than 0.0005) for the 20 min incubation. TCA precipitation of the medium showed minimal insulin degradation products at 8 min with a significant increase at 20 min (1.38 +/- 0.11% vs. 3.06 +/- 0.37%, p less than 0.0005). Internalized insulin was also significantly increased at 20 min as compared to 8 min incubation (48.9 +/- 5.6% vs. 32.4 +/- 3.0%, p less than 0.0005) These data indicate that after 8 min of incubation no appreciable cooperativity of insulin binding was present, while negative cooperativity was present after 20 min of incubation. As significantly more insulin degradation has taken place after prolonged incubation these data support the hypothesis that insulin degradation leads to negative cooperativity of insulin receptors.     

The tethering arm of the EGF receptor is required for negative cooperativity and signal transduction

The EGF receptor is a classical receptor-tyrosine kinase. In the absence of ligand, the receptor adopts a closed conformation in which the dimerization arm of subdomain II interacts with the tethering arm in subdomain IV. Following the binding of EGF, the receptor opens to form a symmetric, back-to-back dimer. Although it is clear that the dimerization arm of subdomain II is central to the formation of receptor dimers, the role of the tethering arm of subdomain IV (residues 561-585) in this configuration is not known. Here we use (125)I-EGF binding studies to assess the functional role of the tethering arm in the EGF receptor dimer. Mutation of the three major residues that contribute to tethering (D563A,H566A,K585A-EGF receptor) did not significantly alter either the ligand binding properties or the signaling properties of the EGF receptor. By contrast, breaking the Cys(558)-Cys(567) disulfide bond through double alanine replacements or deleting the loop entirely led to a decrease in the negative cooperativity in EGF binding and was associated with small changes in downstream signaling. Deletion of the Cys(571)-Cys(593) disulfide bond abrogated cooperativity, resulting in a high affinity receptor and increased sensitivity of downstream signaling pathways to EGF. Releasing the Cys(571)-Cys(593) disulfide bond resulted in extreme negative cooperativity, ligand-independent kinase activity, and impaired downstream signaling. These data demonstrate that the tethering arm plays an important role in supporting cooperativity in ligand binding. Because cooperativity implies subunit-subunit interactions, these results also suggest that the tethering arm contributes to intersubunit interactions within the EGF receptor dimer.     

Characterization and partial purification of the Drosophila Kc cell ecdysteroid receptor

The molting hormones of insects, the ecdysteroids, are steroids whose action is mediated by an intracellular receptor. The Kc cell line of Drosophila melanogaster possesses ecdysteroid receptors and exhibits characteristic, receptor-dependent morphological and biochemical responses to the application of ecdysteroids. This paper describes the interaction of muristerone A (2 beta, 3 beta, 5 beta, 11 alpha, 14 alpha(20R,22R)- heptahydroxycholest-7-en-6-one), a phytoecdysteroid, with the Kc cell ecdysteroid receptor. Muristerone A-receptor complexes are not as sensitive to dissociation in high salt buffers as other ecdysteroid-receptor complexes we have examined. This has enabled us to use [3H]muristerone A to follow the Kc cell ecdysteroid receptor during heparin-agarose, DNA-cellulose, and hydroxylapatite chromatography, as well as gel filtration and ion exchange high pressure liquid chromatography. The Drosophila Kc cell ecdysteroid receptor has a Stokes radius of 4.6 nm, a frictional coefficient of 1.4, and a molecular weight of 120,000. A procedure is presented that results in a 750-fold enrichment of the receptor.     

A system for the partial purification of the human androgen receptor following reversible denaturation

Androgen receptors from normal human foreskins were partially purified by sequential phosphocellulose chromatography and affinity chromatography resulting in a 28,000-fold purification and an 81% recovery. SDS-electrophoresis of the partially purified receptor preparation demonstrated that binding activity could be recovered and showed two peaks of specific binding mol. wt 35,000–55,000 and 85,000–105,000). This method demonstrates that androgen receptors can withstand harsh denaturation conditions and should prove to be a valuable tool for purifying the human androgen receptor.     

Structural basis of negative cooperativity in transthyretin

A comparison of the AC and BD binding sites of transthyretin (TTR) was made in terms of the interatomic distances between the Ca atoms of equivalent amino acids, measured across the tetramer channel in each binding site. The comparison of the channel diameter for apo TTR from different sources revealed that in the unliganded transthyretin tetramers the distances between the A, D and H beta-strands are consistently larger, while the distances between the G beta-strands are smaller in one site than in the other. These differences might be described to have a 'wave' character. An analogous analysis performed for transthyretin complexes reveals that the shape of the plot is similar, although the amplitudes of the changes are smaller. The analysis leads us to a model of the changes in the binding sites caused by ligand binding. The sequence of events includes ligand binding in the first site, followed by a slight collapse of this site and concomitant opening of the second site, binding of the second molecule and collapse of the second site. The following opening of the first, already occupied site upon ligand binding in the second site is smaller because of the bridging interactions already formed by the first ligand. This explains the negative cooperativity (NC) effect observed for many ligands in transthyretin.     

Transformation of the rat uterine estrogen receptor after partial purification

Warming crude rat uterine cytosol after the addition of [³H] estradiol accelerates the association of the 4-S estrogen-binding protein with a second macromolecule, resulting in the formation of the 5-S estrogen-binding protein. To determine whether the 5-S estrogen-binding protein consists of two similar or dissimilar subunits, uterine cytosol was subjected to a number of fractionation procedures that separate macromolecules by solubility, molecular gel sieving, sedimentation rate, ionic charge, and heat lability. Following each of these methods, the fraction containing the 4-S estrogen-binding protein was incubated at 28°C; each of these 4-S estrogen-binding protein-containing fractions retained its capacity to completely transform to the 5-S estrogen-binding protein. In samples subjected to partial purification procedures, it was necessary that the buffer contain 40 mM Tris, 60 mM KCI, 1–10 mM dithiothreitol, and 1 M urea at pH 7.4, in order to accomplish the 4-S to 5-S estrogen-binding protein transformation at 28°C. Formation of the 5-S estrogen-binding protein requires association of the 4-S estrogen-binding protein with a molecule identical to or very similar to itself.     

The membrane-proximal intracellular domain of the epidermal growth factor receptor underlies negative cooperativity in ligand binding

The binding of EGF induces dimerization of its receptor, leading to the stimulation of its intracellular tyrosine kinase activity. Kinase activation occurs within the context of an asymmetric dimer in which one kinase domain serves as the activator for the other kinase domain but is not itself activated. How ligand binding is related to the formation and dynamics of this asymmetric dimer is not known. The binding of EGF to its receptor is negatively cooperative--that is, EGF binds with lower affinity to the second site on the dimer than to the first site on the dimer. In this study, we analyzed the binding of (125)I-EGF to a series of EGF receptor mutants in the intracellular juxtamembrane domain and demonstrate that the most membrane-proximal portion of this region plays a significant role in the genesis of negative cooperativity in the EGF receptor. The data are consistent with a model in which the binding of EGF to the first site on the dimer induces the formation of one asymmetric kinase dimer. The binding of EGF to the second site is required to disrupt the initial asymmetric dimer and allow the formation of the reciprocal asymmetric dimer. Thus, some of the energy of binding to the second site is used to reorient the first asymmetric dimer, leading to a lower binding affinity and the observed negative cooperativity.     

Solubilization and partial purification of GABAB receptor from bovine brain

gamma-Aminobutyric acid (GABA)B receptor has been solubilized and partially purified by an affinity column chromatography. GABAB receptor was solubilized by 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS) in the presence of asolectin. The solubilized GABAB receptor was adsorbed on baclofen-coupled epoxy-activated Sepharose 6B. The affinity matrix adsorbed 80% of the solubilized [3H]GABA binding activity to GABAB receptor, and approximately 75% of the adsorbed activity could be eluted with 1 M KC1. GABAB receptor binding in the fraction eluted from affinity column was displaced by GABA, baclofen and 2-hydroxy saclofen in a dose-dependent manner. Furthermore, the purified GABAB receptor showed approximately 2800-fold purification as compared with the original solubilized fraction and possessed the specific binding activity of 17.68 p mol/mg of protein. This binding consisted of a single binding site with a dissociation constant of 64.4 nM. The present results indicate that affinity column chromatographic procedures using baclofen-coupled epoxy-activated Sepharose 6B are suitable for the partial purification of GABAB receptor from cerebral tissues.     

Properties and partial purification of sialate-O-acetyltransferase from bovine submandibular glands

The O-acetylation of sialic acids in various positions is a frequent modification of these residues in glycoproteins and glycolipids of higher animals and some bacteria. Sialic acid O-acetylation is involved in the regulation of many cell biological and pathophysiological events. Since the properties and the structural and molecular genetic aspects of the eukaryotic sialate O-acetyltransferases are not yet known, we attempted to isolate the enzyme from bovine submandibular glands. O-Acetyltransferase was solubilised from its microsomal location with a zwitterionic detergent and enriched by approximately 50-fold in three steps, including affinity chromatography on coenzyme A. It exhibits a molecular mass of 150-160 kDa. Evidence was obtained for the putative existence of a low-molecular-mass, dialysable enzyme activator. The enzyme showed best activity with CMP-N-acetylneuraminic acid (CMP-Neu5Ac), followed by N-acetylneuraminic acid (Neu5Ac). These compounds, as well as AcCoA, have high affinity for both the microsome-bound and the partially purified O-acetyltransferase. CoA is a strong inhibitor. N-Acetyl-9-O-acetylneuraminic acid was found to be the main reaction product. No evidence was obtained for the involvement of an isomerase that might be responsible for the migration of O-acetyl groups within the sialic acid side chain.     

Insulin-induced dissociation of its receptor into subunits: possible molecular concomitant of negative cooperativity

The detergent-solubilized avian insulin receptor retains negative cooperativity and other binding properties of the membrane bound form. On gel filtration the receptor elutes as a single peak with a Stokes radius of 72 A. Preincubation of the receptor with low levels of insulin leads to the formation of a second, smaller form with a Stokes radius of 40 A. The percent of receptor in this second peak is proportional to the insulin concentration and correlates well with the insulin-induced increase in dissociation rate (negative cooperativity). Both the isolated high molecular weight and the isolated low-molecular-weight forms of the receptor re-equilibrate in the presence of insulin and, upon refiltration of either isolated peak, both forms of the receptor are obtained. These results are compatible with a model of the insulin receptor in which a tetrameric form can dissociate to a monomeric form as a concomitant of negative cooperativity.