The cysteine-rich domains of the insulin and insulin-like growth factor I receptors are primary determinants of hormone binding specificity. Evidence from receptor chimeras

To delineate the structural determinants of the insulin receptor (IR) and insulin-like growth factor I receptor (IGFIR) which affect hormone binding specificity we have constructed seven chimeric receptor cDNAs and stably expressed them in Chinese hamster ovary cells. Clonal cell lines expressing high levels of each receptor chimera were analyzed for insulin and insulin-like growth factor I (IGFI) binding activity. Measurements of hormone binding and immunoprecipitation of metabolically labeled receptors showed that all chimeras were properly processed and expressed at the cell surface. The binding data indicate that 56 amino acids of the IR and 52 amino acids of the IGFIR located in corresponding regions of the cysteine-rich domains are the primary determinants of hormone binding specificity. These regions are located between amino acids Asn-230 and Ile-285 on the IR and between His-223 and Met-274 on the IGFIR. In addition, the alpha IR-3 antibody, which competes for IGFI binding, was found to interact with the same 52 amino acids of the IGFIR which determines hormone specificity. Other antibodies which interfere with insulin binding (5D9, MC51, and MA20) interact with epitopes in the COOH-terminal 288 amino acids of the alpha-subunit. We conclude that 56 and 52 amino acids of the cysteine-rich domains of the IR and IGFIR contain the major determinants of hormone binding specificity although other more COOH-terminal regions of both receptors contribute to hormone binding.     

Identification of determinants that confer ligand specificity on the insulin receptor.

We have previously shown, using truncated soluble recombinant receptors, that substituting the 62 N-terminal amino acids of the alpha subunit from the insulin-like growth factor I receptor (IGFIR) with the corresponding 68 amino acids from the insulin receptor (IR) results in a chimeric receptor with an approximately 200-fold increase in affinity for insulin and only a 5-fold decrease in insulin-like growth factor I (IGFI) affinity (Kjeldsen, T., Andersen, A. S., Wiberg, F. C., Rasmussen, J. S., Sch?ffer, L., Balschmidt, P., M?ller, K. B., and M?ller, N. P. H. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 4404-4408). We demonstrate that these 68 N-terminal amino acids of the IR also confer insulin affinity on the intact IGFI holoreceptor both in the membrane-bound state and when solubilized by Triton X-100. Furthermore, this domain can be subdivided into two regions (amino acids 1-27 and 28-68 of the IR alpha subunit) that, when replacing the corresponding IGFIR sequences, increases the insulin affinity of truncated soluble receptor chimeras 8- and 20-fold, respectively, with only minor effects on the IGFI affinity. Within the latter of these two regions, we found that amino acids 38-68 of the IR, representing 13 amino acid differences from IGFIR, confer the same 20-fold increase in insulin affinity on the IGFIR. Finally, the amino acids from position 42 to 50 are not responsible for this increase in insulin affinity. We thus propose that at least two determinants within the 68 N-terminal amino acids of the insulin receptor are involved in defining the ligand specificity of the insulin receptor, and that one or a combination of the remaining seven amino acid differences between position 38 and 68 are involved in conferring insulin affinity on the insulin receptor.     

Characterization of insulin/IGF hybrid receptors: contributions of the insulin receptor L2 and Fn1 domains and the alternatively spliced exon 11 sequence to ligand binding and receptor activation

The IR (insulin receptor) and IGFR (type I insulin-like growth factor receptor) are found as homodimers, but the respective pro-receptors can also heterodimerize to form insulin-IGF hybrid receptors. There are conflicting data on the ligand affinity of hybrids, and especially on the influence of different IR isoforms. To investigate further the contribution of individual ligand binding epitopes to affinity and specificity in the IR/IGFR family, we generated hybrids incorporating both IR isoforms (A and B) and IR/IGFR domain-swap chimaeras, by ectopic co-expression of receptor constructs in Chinese hamster ovary cells, and studied ligand binding using both radioligand competition and bioluminescence resonance energy transfer assays. We found that IR-A-IGFR and IR-B-IGFR hybrids bound insulin with similar relatively low affinity, which was intermediate between that of homodimeric IR and homodimeric IGFR. However, both IR-A-IGFR and IR-B-IGFR hybrids bound IGF-I and IGF-II with high affinity, at a level comparable with homodimeric IGFR. Incorporation of a significant fraction of either IR-A or IR-B into hybrids resulted in abrogation of insulin- but not IGF-I-stimulated autophosphorylation. We conclude that the sequence of 12 amino acids encoded by exon 11 of the IR gene has little or no effect on ligand binding and activation of IR-IGFR hybrids, and that hybrid receptors bind IGFs but not insulin at physiological concentrations regardless of the IR isoform they contained. To reconstitute high affinity insulin binding within a hybrid receptor, chimaeras in which the IGFR L1 or L2 domains had been replaced by equivalent IR domains were co-expressed with full-length IR-A or IR-B. In the context of an IR-A-IGFR hybrid, replacement of IR residues 325-524 (containing the L2 domain and part of the first fibronectin domain) with the corresponding IGFR sequence increased the affinity for insulin by 20-fold. We conclude that the L2 and/or first fibronectin domains of IR contribute in trans with the L1 domain to create a high affinity insulin-binding site within a dimeric receptor.     

Structural determinants for high-affinity binding of insulin-like growth factor II to insulin receptor (IR)-A, the exon 11 minus isoform of the IR

The insulin receptor (IR) lacking the alternatively spliced exon 11 (IR-A) is preferentially expressed in fetal and cancer cells. The IR-A has been identified as a high-affinity receptor for insulin and IGF-II but not IGF-I, which it binds with substantially lower affinity. Several cancer cell types that express the IR-A also overexpress IGF-II, suggesting a possible autocrine proliferative loop. To determine the regions of IGF-I and IGF-II responsible for this differential affinity, chimeras were made where the C and D domains were exchanged between IGF-I and IGF-II either singly or together. The abilities of these chimeras to bind to, and activate, the IR-A were investigated. We also investigated the ability of these chimeras to bind and activate the IR exon 11+ isoform (IR-B) and as a positive control, the IGF-I receptor (IGF-1R). We show that the C domain and, to a lesser extent, the D domains represent the principal determinants of the binding differences between IGF-I and IGF-II to IR-A. The C and D domains of IGF-II promote higher affinity binding to the IR-A than the equivalent domains of IGF-I, resulting in an affinity close to that of insulin for the IR-A. The C and D domains also regulate the IR-B binding specificity of the IGFs in a similar manner, although the level of binding for all IGF ligands to IR-B is lower than to IR-A. In contrast, the C and D domains of IGF-I allow higher affinity binding to the IGF-1R than the analogous domains of IGF-II. Activation of IGF-1R by the chimeras reflected their binding affinities whereas the phosphorylation of the two IR isoforms was more complex.     

Dimeric fragment of the insulin receptor alpha-subunit binds insulin with full holoreceptor affinity

The insulin receptor (IR) is a dimeric receptor, and its activation is thought to involve cross-linking between monomers initiated by binding of a single insulin molecule to separate epitopes on each monomer. We have previously shown that a minimized insulin receptor consisting of the first three domains of the human IR fused to 16 amino acids from the C-terminal of the alpha-subunit was monomeric and bound insulin with nanomolar affinity (Kristensen, C., Wiberg, F. C., Sch?ffer, L., and Andersen, A. S. (1998) J. Biol. Chem. 273, 17780-17786). To investigate the insulin binding properties of dimerized alpha-subunits, we have reintroduced the domains containing alpha-alpha disulfide bonds into this minireceptor. When inserting either the first fibronectin type III domain or the full-length sequence of exon 10, the receptor fragments were predominantly secreted as disulfide-linked dimers that both had nanomolar affinity for insulin, similar to the affinity found for the minireceptor. However, when both these domains were included we obtained a soluble dimeric receptor that bound insulin with 1000-fold higher affinity (4-8 pm) similar to what was obtained for the solubilized holoreceptor (14-24 pm). Moreover, dissociation of labeled insulin from this receptor was accelerated in the presence of unlabeled insulin, demonstrating another characteristic feature of the holoreceptor. This is the first direct demonstration showing that the alpha-subunit of IR contains all the epitopes required for binding insulin with full holoreceptor affinity.     

Characterization of the Ligand Binding Functionality of the Extracellular Domain of Activin Receptor Type IIB

The single transmembrane domain serine/threonine kinase activin receptor type IIB (ActRIIB) has been proposed to bind key regulators of skeletal muscle mass development, including the ligands GDF-8 (myostatin) and GDF-11 (BMP-11). Here we provide a detailed kinetic characterization of ActRIIB binding to several low and high affinity ligands using a soluble activin receptor type IIB-Fc chimera (ActRIIB.Fc). We show that both GDF-8 and GDF-11 bind the extracellular domain of ActRIIB with affinities comparable with those of activin A, a known high affinity ActRIIB ligand, whereas BMP-2 and BMP-7 affinities for ActRIIB are at least 100-fold lower. Using site-directed mutagenesis, we demonstrate that ActRIIB binds GDF-11 and activin A in different ways such as, for example, substitutions in ActRIIB Leu⁷⁹ effectively abolish ActRIIB binding to activin A yet not to GDF-11. Native ActRIIB has four isoforms that differ in the length of the C-terminal portion of their extracellular domains. We demonstrate that the C terminus of the ActRIIB extracellular domain is crucial for maintaining biological activity of the ActRIIB.Fc receptor chimera. In addition, we show that glycosylation of ActRIIB is not required for binding to activin A or GDF-11. Together, our findings reveal binding specificity and activity determinants of the ActRIIB receptor that combine to effect specificity in the activation of distinct signaling pathways.     

Characterization of a second ligand binding site of the insulin receptor

Insulin binding to its receptor is characterized by high affinity, curvilinear Scatchard plots, and negative cooperativity. These properties may be the consequence of binding of insulin to two receptor binding sites. The N-terminal L1 domain and the C-terminus of the alpha subunit contain one binding site. To locate a second site, we examined the binding properties of chimeric receptors in which the L1 and L2 domains and the first Fibronectin Type III repeat of the insulin-like growth factor-I receptor were replaced by corresponding regions of the insulin receptor. Substitutions of the L2 domain and the first Fibronectin Type III repeat together with the L1 domain produced 80- and 300-fold increases in affinity for insulin. Fusion of these domains to human immunoglobulin Fc fragment produced a protein which bound insulin with a K(d) of 2.9 nM. These data strongly suggest that these domains contain an insulin binding site.     

Dissection of RAP-LRP interactions: binding of RAP and RAP fragments to complement-like repeats 7 and 8 from ligand binding cluster II of LRP

The receptor associated protein (RAP) is a three domain 38kDa ER-resident chaperone that helps folding of LRP and other LDL receptor family members and prevents premature binding of protein ligands. It competes strongly with all known LRP ligands. To further understanding of the specificity of RAP-LRP interactions, the binding of RAP and RAP fragments to two domains (CR7-CR8) from one of the main ligand-binding regions of LRP has been examined by 2D HSQC NMR spectroscopy and isothermal titration calorimetry. We found that RAP contains two binding sites for CR7-CR8, with the higher affinity site (K(d) approximately 1microM) located in the C-terminal two-thirds and the weaker site (K(d) approximately 5microM) in the N-terminal third of RAP. Residues from both CR7 and CR8 are involved in binding at each RAP site. The presence of more than one binding site on RAP for CR domains from LRP, together with the previous demonstration by others that RAP can bind to CR5-CR6 with comparably low affinities suggest an explanation for the dual roles of RAP as a folding chaperone and a tight competitive inhibitor of ligand binding.     

Functional reconstitution of insulin receptor binding site from non-binding receptor fragments

We have previously shown that a minimized insulin receptor (IR) consisting of the first 468 amino acids of the insulin receptor fused to 16 amino acids from the C terminus of the alpha-subunit (CT domain) bound insulin with nanomolar affinity (Kristensen, C., Wiberg, F. C., Sch?ffer, L., and Andersen, A. S. (1998) J. Biol. Chem. 273, 17780-17786). In the present study, we show that a smaller construct that has the first 308 residues fused to the CT domain also binds insulin. Insulin receptor fragments consisting of the first 468 or 308 residues did not bind insulin. However, when these fragments were mixed with a synthetic peptide corresponding to the CT domain, insulin binding was detectable. At concentrations of 10 microm CT peptide, insulin binding was fully reconstituted yielding apparent affinities of 9-11 nm. To further investigate the minimum requirement for the length of the N terminus of IR, we tested smaller receptor fragments for insulin binding in the presence of the CT peptide and found that a fragment consisting of the first 255 amino acids of IR was able to fully reconstitute the insulin binding site, yielding an apparent affinity of 11 +/- 4 nm for insulin.     

Quantification of PDZ domain specificity, prediction of ligand affinity and rational design of super-binding peptides

Transient macromolecular complexes are often formed by protein-protein interaction domains (e.g. PDZ, SH2, SH3, WW) which recognize linear sequence motifs with in vitro affinities typically in the micromolar range. The analysis of the resulting interaction networks requires a quantification of domain specificity and selectivity towards all possible ligands with physiologically relevant affinity. As representative examples, we determined specificity as a function of ligand sequence-dependent affinity contributions by statistical analysis of peptide library screens for the AF6, ERBIN and SNA1 (alpha-1-syntrophin) PDZ domains. For this purpose, the three PDZ domains were first screened for binding with a peptide library comprising 6223 human C termini created by SPOT synthesis. Based on the detected ligand preferences, we designed focused peptide libraries (profile libraries). These libraries were used to quantify the affinity contributions of the four C-terminal ligand residues by means of ANOVA models (analysis of variance) relating the C-terminal ligand sequences to the corresponding dissociation constants. Our models agreed well with experimentally determined dissociation constants and allowed us to design super binding peptides. The latter were shown experimentally to bind to their cognate PDZ domains with the highest affinity. In addition, we determined structure-activity relationships and thereby rationalized the position-specific affinity contributions. Furthermore, we used the statistical models to predict the dissociation constants for the complete ligand sequence space and thus determined the specificity overlap for the three investigated PDZ domains (). Altogether, we present an efficient method for profiling protein-protein interaction domains that provides a biophysical picture of specificity and selectivity. This approach allows the rational design of functional experiments and provides a basis for simulating interaction networks in the field of systems biology.     

Localization of the carbohydrate recognition sites of the insulin-like growth factor II/mannose 6-phosphate receptor to domains 3 and 9 of the extracytoplasmic region

The insulin-like growth factor II/mannose 6-phosphate receptor is a multifunctional receptor that binds to a diverse array of mannose 6-phosphate (Man-6-P) modified proteins as well as nonglycosylated ligands. Previous studies have mapped its two Man-6-P binding sites to a minimum of three domains, 1-3 and 7-9, within its 15-domain extracytoplasmic region. Since the primary amino acid determinants of carbohydrate recognition by the insulin-like growth factor II/mannose 6-phosphate receptor are predicted by sequence alignment to the cation-dependent mannose 6-phosphate receptor to reside within domains 3 and 9, constructs encoding either domain 3 alone or domain 9 alone were expressed in a Pichia pastoris expression system and tested for their ability to bind several carbohydrate ligands, including Man-6-P, pentamannosyl phosphate, the lysosomal enzyme, beta-glucuronidase, and the carbohydrate modifications (mannose 6-sulfate and Man-6-P methyl ester) found on Dictyostelium discoideum lysosomal enzymes. Although both constructs were functional in ligand binding and dissociation, these studies demonstrate the ability of domain 9 alone to fold into a high affinity (K(d) = 0.3 +/- 0.1 nm) carbohydrate-recognition domain whereas the domain 3 alone construct is capable of only low affinity binding (K(d) approximately 500 nm) toward beta-glucuronidase, suggesting that residues in adjacent domains (domains 1 and/or 2) are important, either directly or indirectly, for optimal binding by domain 3.     

Insulin and insulin-like growth factor-1 binding specificity is determined by distinct regions of their cognate receptors.

Chimeric insulin/insulin-like growth factor-1 receptors and insulin receptor alpha-subunit point mutants were characterized with respect to their binding properties for insulin and insulin-like growth factor-1 (IGF-1) and their ability to translate ligand interaction into tyrosine kinase activation in intact cells. We found that replacement of the amino-terminal 137 amino acids of the insulin receptor (IR) with the corresponding 131 amino acids of the IGF-1 receptor (IGF-1R) resulted in loss of affinity for both ligands. Further replacement of the adjacent cysteine region with IGF-1R sequences fully reconstituted affinity for IGF-1, but only marginally for insulin. Unexpectedly, replacement of the IR cysteine-rich domain alone by IGF-1R sequences created a high affinity receptor for both insulin and IGF-1. The binding characteristics of all receptor chimeras reflected the potential of both ligands to regulate the receptor tyrosine kinase activity in intact cells. Our chimeric receptor data, in conjunction with IR amino-terminal domain point mutants, strongly suggest major contributions of structural determinants in both amino- and carboxyl-terminal IR alpha-subunit regions for the formation of the insulin-binding pocket, whereas, surprisingly, the residues defining IGF-1 binding are present predominantly in the cysteine-rich domain of the IGF-1R.     

Solution structure of the orphan PABC domain from Saccharomyces cerevisiae poly(A)-binding protein

We have determined the solution structure of the PABC domain from Saccharomyces cerevisiae Pab1p and mapped its peptide-binding site. PABC domains are peptide binding domains found in poly(A)-binding proteins (PABP) and are a subset of HECT-family E3 ubiquitin ligases (also known as hyperplastic discs proteins (HYDs)). In mammals, the PABC domain of PABP functions to recruit several different translation factors to the mRNA poly(A) tail. PABC domains are highly conserved, with high specificity for peptide sequences of roughly 12 residues with conserved alanine, phenylalanine, and proline residues at positions 7, 10, and 12. Compared with human PABP, the yeast PABC domain is missing the first alpha helix, contains two extra amino acids between helices 2 and 3, and has a strongly bent C-terminal helix. These give rise to unique peptide binding specificity wherein yeast PABC binds peptides from Paip2 and RF3 but not Paip1. Mapping of the peptide-binding site reveals that the bend in the C-terminal helix disrupts binding interactions with the N terminus of peptide ligands and leads to greatly reduced binding affinity for the peptides tested. No high affinity or natural binding partners from S. cerevisiae could be identified by sequence analysis of known PABC ligands. Comparison of the three known PABC structures shows that the features responsible for peptide binding are highly conserved and responsible for the distinct but overlapping binding specificities.     

Role of insulin receptor dimerization domains in ligand binding, cooperativity, and modulation by anti-receptor antibodies

To define the structures within the insulin receptor (IR) that are required for high affinity ligand binding, we have used IR fragments consisting of four amino-terminal domains (L1, cysteine-rich, L2, first fibronectin type III domain) fused to sequences encoded by exon 10 (including the carboxyl terminus of the alpha-subunit). The fragments contained one or both cysteine residues (amino acids 524 and 682) that form disulfides between alpha-subunits in native IR. A dimeric fragment designated IR593.CT (amino acids 1-593 and 704-719) bound (125)I-insulin with high affinity comparable to detergent-solubilized wild type IR and mIR.Fn0/Ex10 (amino acids 1-601 and 650-719) and greater than that of dimeric mIR.Fn0 (amino acids 1-601 and 704-719) and monomeric IR473.CT (amino acids 1-473 and 704-719). However, neither IR593.CT nor mIR.Fn0 exhibited negative cooperativity (a feature characteristic of the native insulin receptor and mIR.Fn0/Ex10), as shown by failure of unlabeled insulin to accelerate dissociation of bound (125)I-insulin. Anti-receptor monoclonal antibodies that recognize epitopes in the first fibronectin type III domain (amino acids 471-593) and inhibit insulin binding to wild type IR inhibited insulin binding to mIR.Fn0/Ex10 but not IR593.CT or mIR.Fn0. We conclude the following: 1) precise positioning of the carboxyl-terminal sequence can be a critical determinant of binding affinity; 2) dimerization via the first fibronectin domain alone can contribute to high affinity ligand binding; and 3) the second dimerization domain encoded by exon 10 is required for ligand cooperativity and modulation by antibodies.     

Prediction of a novel internal rearrangement of the insulin receptor

The insulin receptor (IR) plays critical roles in metabolism and growth, directed by the binding of insulin. Decades of research to understand the mechanism of insulin binding and activation of the IR have identified a region of the receptor, the C-terminal (CT) peptide, to be crucial for insulin binding. In particular, a truncated IR consisting of the first three domains fused to the CT peptide was found to bind insulin with nanomolar affinity, with undetectable binding in the absence of fused or soluble CT peptide. Problematically, all current crystal structures of the IR indicate the fusion point of the CT peptide to the three domains is located far from the position of the CT peptide as resolved in such structures. We have attempted to address this problem using molecular modelling and dynamics simulations. The results led to the identification of a potential inter-domain interaction between the L2 domain and the CT peptide that is not observed in any of the crystal structures of the IR. Investigations into this new interaction found a conformational change that could potentially be in response to insulin binding. Additionally, further simulation work with the new conformation demonstrated its compatibility with the position and orientation of insulin from the latest insulin-bound IR crystal structure.     

Binding of the Grb2 SH2 domain to phosphotyrosine motifs does not change the affinity of its SH3 domains for Sos proline-rich motifs.

Phosphotyrosine peptide binding to Grb2 induces tryptophan fluorescence changes in the Src homology 2 (SH2) domain. Affinities are in the nanomolar range, the Shc peptide having the highest affinity, followed by peptides mimicking Grb2 binding sites on EGF and HGF receptors, the putative sites on insulin and IGF-1 receptors having much lower affinities. Proline-rich peptide binding to the SH3 domains induces fluorescence changes mainly in the C-terminal SH3. Affinities are in the micromolar range, the highest affinity peptides mimicking the first proline-rich motif of the Sos C-terminus. Additional residues before this PVPPPVPP motif provide a minor contribution to the binding, but the two residues after this motif are important and may contribute to specificity. The affinity of each SH3 for each proline-rich motif is too low to account for the high stability of the Grb2-Sos complex, suggesting that Grb2 recognizes other structural features in the Sos C-terminus. Binding of a phosphotyrosine peptide to the SH2 has no effect on the SH3s. Thus the binding of Grb2 to a receptor or to an associated protein phosphorylated on tyrosines is unlikely to activate the exchange factor activity of Sos through a conformational change transmitted from the SH2 to the SH3 domains.     

Structural requirements for ligand binding by a probable plant vacuolar sorting receptor

How sorting receptors recognize amino acid determinants on polypeptide ligands and respond to pH changes for ligand binding or release is unknown. The plant vacuolar sorting receptor BP-80 binds polypeptide ligands with a central Asn-Pro-Ile-Arg (NPIR) motif. tBP-80, a soluble form of the receptor lacking transmembrane and cytoplasmic sequences, binds the peptide SSSFADSNPIRPVTDRAASTYC as a monomer with a specificity indistinguishable from that of BP-80. tBP-80 contains an N-terminal region homologous to ReMembR-H2 (RMR) protein lumenal domains, a unique central region, and three C-terminal epidermal growth factor (EGF) repeats. By protease digestion of purified secreted tBP-80, and from ligand binding studies with a secreted protein lacking the EGF repeats, we defined three protease-resistant structural domains: an N-terminal/RMR homology domain connected to a central domain, which together determine the NPIR-specific ligand binding site, and a C-terminal EGF repeat domain that alters the conformation of the other two domains to enhance ligand binding. A fragment representing the central domain plus the C-terminal domain could bind ligand but was not specific for NPIR. These results indicate that two tBP-80 binding sites recognize two separate ligand determinants: a non-NPIR site defined by the central domain-EGF repeat domain structure and an NPIR-specific site contributed by the interaction of the N-terminal/RMR homology domain and the central domain.     

Differential responsiveness of CRF receptor subtypes to N-terminal truncation of peptidic ligands

The role of the N-terminal domains of corticotropin-releasing factor (CRF) and CRF-like peptides in receptor subtype selectivity, ligand affinity and biological potency was investigated. Therefore, human CRF(12-41), human URP(12-38) and antisauvagine-30 (aSvg) were N-terminally prolonged by consecutive addition of one or two amino acids. The peptides obtained were tested for their binding affinities to rat CRF1 and murine CRF(2beta) receptor, and their capability to stimulate cAMP-release by HEK cells producing either receptor.It was observed that human CRF N-terminally truncated by eight residues was bound with high affinity to CRF2 receptor (Ki=5.4nM), whereas affinity for CRF1 receptor was decreased (Ki=250 nM). A similar shift of affinity was found with sauvagine (Svg) analogs. Truncation of human URP analogs did not affect their preference for CRF(2beta) receptor, but reduced their affinity. Changes in affinity were positively correlated with changes in potency. These results indicated that CRF1 receptor was more stringent in its structural requirements for ligands to exhibit high affinity binding than CRF(2beta) receptor.     

Structural Investigations of Full-Length Insulin Receptor Dynamics and Signalling

Insulin regulates glucose homeostasis via binding and activation of the insulin receptor dimer at two distinct pairs of binding sites 1 and 2. Here, we present cryo-EM studies of full-length human insulin receptor (hIR) in an active state obtained at non-saturating, physiologically relevant insulin conditions. Insulin binds asymmetrically to the receptor under these conditions, occupying up to three of the four possible binding sites. Deletion analysis of the receptor together with site specific peptides and insulin analogs used in binding studies show that both sites 1 and 2 are required for high insulin affinity. We identify a homotypic interaction of the fibronectin type III domain (FnIII-3) of IR resulting in tight interaction of membrane proximal domains of the active, asymmetric receptor dimer. Our results show how insulin binding at two distinct types of sites disrupts the autoinhibited apo-IR dimer and stabilizes the active dimer. We propose an insulin binding and activation mechanism, which is sequential, exhibits negative cooperativity, and is based on asymmetry at physiological insulin concentrations with one to three insulin molecules activating IR.