Non-equivalent Role of Inter- and Intramolecular Hydrogen Bonds in the Insulin Dimer Interface

Antolíková, E.; Žáková, Lenka; Turkenburg, J.P.; Watson, Christopher J.; Hančlová, Ivona; Šanda, Miloslav; Cooper, Alan; Kraus, Tomáš; Brzozowski, A.M.; Jiráček, Jiřı́

doi:10.1074/jbc.m111.265249

Cited by 36 publications

(48 citation statements)

References 57 publications

(77 reference statements)

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“…Investigations of the dimerization abilities of selected insulin analogues were performed as described in detail previously (Antolikova et al, 2011).…”

Section: Isothermal Microcalorimetry (Itc) Measurementsmentioning

confidence: 99%

Human insulin analogues modified at the B26 site reveal a hormone conformation that is undetected in the receptor complex

Žáková

Kletvíková

Lepšı́k

et al. 2014

Acta Cryst D Biol Crystallogr

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The structural characterization of the insulin-insulin receptor (IR) interaction still lacks the conformation of the crucial B21-B30 insulin region, which must be different from that in its storage forms to ensure effective receptor binding. Here, it is shown that insulin analogues modified by natural amino acids at the TyrB26 site can represent an active form of this hormone. In particular, [AsnB26]-insulin and [GlyB26]-insulin attain a B26-turn-like conformation that differs from that in all known structures of the native hormone. It also matches the receptor interface, avoiding substantial steric clashes. This indicates that insulin may attain a B26-turn-like conformation upon IR binding. Moreover, there is an unexpected, but significant, binding specificity of the AsnB26 mutant for predominantly the metabolic B isoform of the receptor. As it is correlated with the B26 bend of the B-chain of the hormone, the structures of AsnB26 analogues may provide the first structural insight into the structural origins of differential insulin signalling through insulin receptor A and B isoforms.

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“…Investigations of the dimerization abilities of selected insulin analogues were performed as described in detail previously (Antolikova et al, 2011).…”

Section: Isothermal Microcalorimetry (Itc) Measurementsmentioning

confidence: 99%

Human insulin analogues modified at the B26 site reveal a hormone conformation that is undetected in the receptor complex

Žáková

Kletvíková

Lepšı́k

et al. 2014

Acta Cryst D Biol Crystallogr

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“…In addition, the A chain includes an intrachain Cys A6 -Cys A11 disulfide bond. Insulin is capable of dimerization at low micromolar concentrations (3), and the presence of divalent metal ions leads to the formation of insulin hexamers that represent the storage form of this hormone (2). There is overwhelming evidence that monomeric insulin, which dissociates from its storage forms, must undergo structural changes upon binding to IR.…”

mentioning

confidence: 99%

Structural Integrity of the B24 Site in Human Insulin Is Important for Hormone Functionality

Žáková

Kletvíková

Veverka

et al. 2013

Journal of Biological Chemistry

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Background:The structure of the C-terminal B21-B30 chain of insulin bound to the insulin receptor remains undetermined. Results: The structures of B24-modified insulins were determined. Conclusion: The structural integrity of Phe B24 but flexibility of B25-B30 insulin residues are important for receptor binding. Significance: The knowledge of the receptor-bound structure of insulin is important for the design of new insulin receptor agonists.

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“…Data collected to 1.35 A resolution and the structure was solved by molecular replacement. [16] A cartoon representation of the crystal structure of the final model is shown in Figure 7.…”

Section: Resultsmentioning

confidence: 99%

Scope and Limitations of Fmoc Chemistry SPPS‐Based Approaches to the Total Synthesis of Insulin Lispro via Ester Insulin

Dhayalan

Mandal

Rege

et al. 2017

Chemistry A European J

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We have systematically explored three approaches based on Fmoc chemistry SPPS for the total chemical synthesis of the key depsipeptide intermediate for the efficient total chemical synthesis of insulin. The approaches used were: stepwise Fmoc chemistry SPPS; the ‘hybrid method’, in which maximally-protected peptide segments made by Fmoc chemistry SPPS are condensed in solution; and, native chemical ligation using peptide-thioester segments generated by Fmoc chemistry SPPS. A key building block in all three approaches was a Glu[Oβ(Thr)] ester-linked dipeptide equipped with a set of orthogonal protecting groups compatible with Fmoc chemistry SPPS. The most effective method for the preparation of the 51 residue ester-linked polypeptide chain of ester insulin was the use of unprotected peptide-thioester segments, prepared from peptide-hydrazides synthesized by Fmoc chemistry SPPS, and condensed by native chemical ligation. High resolution X-ray crystallography confirmed the disulfide pairings and three-dimensional structure of synthetic insulin lispro prepared from ester insulin lispro by this route. Further optimization of these pilot studies should yield an effective total chemical synthesis of insulin lispro (Humalog) based on peptide synthesis by Fmoc chemistry SPPS.

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Non-equivalent Role of Inter- and Intramolecular Hydrogen Bonds in the Insulin Dimer Interface

Cited by 36 publications

References 57 publications

Human insulin analogues modified at the B26 site reveal a hormone conformation that is undetected in the receptor complex

Human insulin analogues modified at the B26 site reveal a hormone conformation that is undetected in the receptor complex

Structural Integrity of the B24 Site in Human Insulin Is Important for Hormone Functionality

Scope and Limitations of Fmoc Chemistry SPPS‐Based Approaches to the Total Synthesis of Insulin Lispro via Ester Insulin

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