Characterization of the Functional Insulin Binding Epitopes of the Full-length Insulin Receptor

Whittaker, Jonathan; Whittaker, Linda

doi:10.1074/jbc.m411320200

Cited by 48 publications

(90 citation statements)

References 36 publications

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“…This observation rationalizes (i) the high activity of an Ala B26 analog (36), (ii) the dispensability of Tyr B26 in truncated analogs (37), and (iii) that whereas holoreceptor substitution Arg14Ala (near both Tyr B26 and the B25 main chain) impairs insulin binding >10 3 -fold, Ala substitution of Asp12 (in contact only with Tyr B26 ) impairs hormone binding by only 6-fold (33). We suggest that the conservation of Tyr B26 (2) arises not from its role in receptor binding but instead from its contribution to proinsulin folding (38) and insulin self-assembly (2,39).…”

Section: Discussionsupporting

confidence: 56%

“…Lined by Pro716 and Pro718 in IR-A (Pro716 and Lys718 in IR-B) and multiple main-chain atoms, this open surface presumably contributes to the rigid requirement for an aromatic side chain at B25 (2,4,35). In the holoreceptor, substitution of Val715 by Ala eliminates detectable hormone binding (33). It is unclear, however, why substitution of Phe B25 by Ala, deleterious in full-length insulin (13), is by contrast well tolerated in truncated analog des-pentapeptide[B26-B30]-insulin-amide (see below) (35).…”

Section: Discussionmentioning

confidence: 99%

“…Relative activities of insulin analogs were evaluated in an in vitro assay of hormone-stimulated receptor autophosphorylation (33).…”

Section: Methodsmentioning

confidence: 99%

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Protective hinge in insulin opens to enable its receptor engagement

Menting

Yang

Chan

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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147

257

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Insulin provides a classical model of a globular protein, yet how the hormone changes conformation to engage its receptor has long been enigmatic. Interest has focused on the C-terminal Bchain segment, critical for protective self-assembly in β cells and receptor binding at target tissues. Insight may be obtained from truncated "microreceptors" that reconstitute the primary hormone-binding site (α-subunit domains L1 and αCT). We demonstrate that, on microreceptor binding, this segment undergoes concerted hinge-like rotation at its B20-B23 β-turn, coupling reorientation of Phe B24 to a 60°rotation of the B25-B28 β-strand away from the hormone core to lie antiparallel to the receptor's L1-β 2 sheet. Opening of this hinge enables conserved nonpolar side chains (Ile A2 , Val A3 , Val B12 , Phe B24 , and Phe B25 ) to engage the receptor. Restraining the hinge by nonstandard mutagenesis preserves native folding but blocks receptor binding, whereas its engineered opening maintains activity at the price of protein instability and nonnative aggregation. Our findings rationalize properties of clinical mutations in the insulin family and provide a previously unidentified foundation for designing therapeutic analogs. We envisage that a switch between free and receptorbound conformations of insulin evolved as a solution to conflicting structural determinants of biosynthesis and function.diabetes mellitus | signal transduction | receptor tyrosine kinase | metabolism | protein structure H ow insulin engages the insulin receptor has inspired speculation ever since the structure of the free hormone was determined by Hodgkin and colleagues in 1969 (1, 2). Over the ensuing decades, anomalies encountered in studies of analogs have suggested that the hormone undergoes a conformational change on receptor binding: in particular, that the C-terminal β-strand of the B chain (residues B24-B30) releases from the helical core to expose otherwise-buried nonpolar surfaces (the detachment model) (3-6). Interest in the B-chain β-strand was further motivated by the discovery of clinical mutations within it associated with diabetes mellitus (DM) (7). Analysis of residuespecific photo-cross-linking provided evidence that both the detached strand and underlying nonpolar surfaces engage the receptor (8).The relevant structural biology is as follows. The insulin receptor is a disulfide-linked (αβ) 2 receptor tyrosine kinase (Fig. 1A), the extracellular α-subunits together binding a single insulin molecule with high affinity (9). Involvement of the two α-subunits is asymmetric: the primary insulin-binding site (site 1*) comprises the central β-sheet (L1-β 2 ) of the first leucine-rich repeat domain (L1) of one α-subunit and the partially helical Cterminal segment (αCT) of the other α-subunit (Fig. 1A) (10). Such binding initiates conformational changes leading to transphosphorylation of the β-subunits' intracellular tyrosine kinase (TK) domains. Structures of wild-type (WT) insulin (or analogs) bound to extracellular receptor fragments were recently...

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Section: Discussionsupporting

confidence: 56%

Section: Discussionmentioning

confidence: 99%

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Protective hinge in insulin opens to enable its receptor engagement

Menting

Yang

Chan

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

147

257

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“…Receptor Binding Assays-Binding assays employ a FLAG epitope-tagged holoreceptor (either IR isoform B or IGFR) transiently expressed in human 293 PEAK cells (CRL-2828, American Tissue Culture Collection) (35,36). The receptors were partially purified by wheat germ agglutinin (WGA) chromatography and further fractionated on binding to polystyrene 96-well plates (Nunc Maxisorb) coated with an anti-FLAG monoclonal antibody (FLAG M2 immunoglobulin G; Sigma).…”

Section: Synthesis Of Insulin Analogs-mentioning

confidence: 99%

Design of an Insulin Analog with Enhanced Receptor Binding Selectivity

Zhao

Wan

Whittaker

et al. 2009

Journal of Biological Chemistry

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Insulin binds with high affinity to the insulin receptor (IR) and with low affinity to the type 1 insulin-like growth factor (IGF) receptor (IGFR). Such cross-binding, which reflects homologies within the insulin-IGF signaling system, is of clinical interest in relation to the association between hyperinsulinemia and colorectal cancer. Here, we employ nonstandard mutagenesis to design an insulin analog with enhanced affinity for the IR but reduced affinity for the IGFR. Unnatural amino acids were introduced by chemical synthesis at the N-and C-capping positions of a recognition ␣-helix (residues A1 and A8). These sites adjoin the hormone-receptor interface as indicated by photocross-linking studies. Specificity is enhanced more than 3-fold on the following: Epidemiological studies have demonstrated an association between the metabolic syndrome and type 2 diabetes mellitus (DM) 4 with enhanced risk of colorectal cancer (CRC) (1-3). Animal models suggest that this risk is due to hyperinsulinemia (4, 5). An increased risk of CRC is conferred by treated-derived hyperinsulinemia, either as a direct consequence of insulin replacement therapy or as an indirect response to sulfonylurea secretagogues (6 -9). A reduced CRC risk is by contrast associated with metformin treatment, which results in lower circulating insulin concentrations (7). Because of the global epidemic of type 2 DM (10, 11), it would be of interest to develop a form of insulin therapy that does not elevate CRC risk in this clinical setting.A variety of evidence suggests that the association between hyperinsulinemia and CRC is due to aberrant activation of the type 1 IGF receptor (IGFR) (for review see Refs. 5,12). Although underlying molecular mechanisms are incompletely understood, two models have been proposed (5, 12). The first posits cross-binding of insulin to IGFR in colonic epithelia and neoplastic clones, driving proliferation and tumorigenesis; the second proposes indirect IGFR activation through perturbation of the IGF-I axis (including expression of the IGF-binding proteins) (13,14). Whereas consistent changes in bioactive IGF-I have been difficult to document (4), evidence favoring the direct model is provided by studies of epithelial proliferation in rats (15). Exogenous administration of insulin with a euglycemic clamp causes an acute dose-dependent increase in the proliferation rate of colonic epithelia despite decreased IGF-I expression. Such increased proliferation was not observed as a consequence of hyperglycemia or following infusion of a triglyceride emulsion (15).Insulin binds with high affinity (K d ϳ0.05 nM) to the insulin receptor (IR) and with low but significant affinity (K d Ј ϳ9.0 nM) to IGFR (16). Such cross-binding reflects the structural homology between insulin and IGF-I (17) and between IR and IGFR (18). The structural basis for receptor discrimination by insulin and IGF-I has been described recently (19). As a first step toward dissecting the molecular mechanism of insulin-dependent proliferation of colonic epithelia c...

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“…Each insulin is located between the L1 domain of one IR-monomer, the FnIII-1 domain of the other IR-monomer, and the α-CT helix (Figure 1c). Residues of the L1 subdomain and the α-CT helix, previously identified as essential for insulin binding by a variety of biochemical approaches 13 , have been proposed to represent the IR S1 site 18 . Structures of “S1 microreceptors” (containing L1, CR and a portion of the α-CT) in complex with insulin and insulin mimetics 7 provided the first atomic details of some IR-insulin key interactions (Extended Data Table 1).…”

mentioning

confidence: 99%

Structure of the insulin receptor–insulin complex by single-particle cryo-EM analysis

Scapin

Dandey

Zhang

et al. 2018

Nature

199

243

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Summary The insulin receptor (IR) is a dimeric protein that plays a crucial role in controlling glucose homeostasis, regulating lipid, protein and carbohydrate metabolism, and modulating brain neurotransmitter levels1,2. IR dysfunctions have been associated with many diseases, including diabetes, cancer, and Alzheimer’s1,3,4. The primary sequence has been known since the 1980s5, and is composed of an extracellular portion (ectodomain, ECD), a single transmembrane helix and an intracellular tyrosine kinase domain. Insulin binding to the dimeric ECD triggers kinase domain auto-phosphorylation and subsequent activation of downstream signaling molecules. Biochemical and mutagenesis data have identified two putative insulin binding sites (S1 and S2)6. While insulin bound to an ECD fragment containing S1 and the apo ectodomain have been characterized structurally7,8, details of insulin binding to the full receptor and the signal propagation mechanism are still not understood. Here we report single particle cryoEM reconstructions for the 1:2 (4.3 Å) and 1:1 (7.4 Å) IR ECD dimer:Insulin complexes. The symmetric 4.3 Å structure shows two insulin molecules per dimer, each bound between the Leucine-rich sub domain L1 of one monomer and the first fibronectin-like domain (FnIII-1) of the other monomer, and making extensive interactions with the α subunit C-terminal helix (α-CT helix). The 7.4 Å structure has only one similarly bound insulin per receptor dimer. The structures confirm the S1 binding interactions and define the full S2 binding site. These insulin receptor states suggest that recruitment of the α-CT helix upon binding of the first insulin changes the relative sub domain orientations and triggers downstream signal propagation.

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Characterization of the Functional Insulin Binding Epitopes of the Full-length Insulin Receptor

Cited by 48 publications

References 36 publications

Protective hinge in insulin opens to enable its receptor engagement

Protective hinge in insulin opens to enable its receptor engagement

Design of an Insulin Analog with Enhanced Receptor Binding Selectivity

Structure of the insulin receptor–insulin complex by single-particle cryo-EM analysis

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