Docking of insulin to a structurally equilibrated insulin receptor ectodomain

Harish Vashisth; Cameron F Abrams

doi:10.1002/prot.22670

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Docking of insulin to a structurally equilibrated insulin receptor ectodomain

Journal article

Peer reviewed

Docking of insulin to a structurally equilibrated insulin receptor ectodomain

Harish Vashisth and Cameron F Abrams

Proteins, structure, function, and bioinformatics, v 78(6), pp 1531-1543

01 May 2010

DOI: https://doi.org/10.1002/prot.22670

PMID: 20112420

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Abstract

Apoproteins - chemistry

Protein Structure, Tertiary

Pliability

Protein Structure, Secondary

Humans

Protein Multimerization

Models, Molecular

Mutant Proteins - metabolism

Protein Subunits - metabolism

Amino Acids - metabolism

Insulin - metabolism

Receptor, Insulin - chemistry

Mutant Proteins - chemistry

Protein Binding

Receptor, Insulin - metabolism

Protein Subunits - chemistry

Apoproteins - metabolism

The insulin receptor (IR) is a homo-dimeric, disulfide-linked, membrane-spanning tyrosine kinase. IR displays negative cooperativity in insulin binding to its two pockets, suggesting "see-sawing" between symmetry-inverted conformations. The crystal structure of the dimeric IR ectodomain, IRDeltabeta [PDB code 2DTG (McKern et al., Nature 2006 443:218-221)], provides structural bases for this speculation. Unfortunately, neither binding pocket of the crystallographic IRDeltabeta structure allows steric accommodation of insulin. During almost 70-ns of all-atom, explicit-water MD simulation ( approximately 0.5 million atoms), IRDeltabeta undergoes significant asymmetric interdomain and intersubunit conformational fluctuations that do not alter its quaternary structure. Subtle variations in intersubunit buried surface area coincide with these conformational fluctuations, resulting in one easily-accessible insulin binding pocket with the other blocked. We use a combination of Metropolis Monte-Carlo and MD simulations to dock both T- and R-state insulin into the open binding pocket. Both complexes remain stable during 30-ns of MD simulation. In these complexes, "hexamer interface" residues on insulin directly contact the "site-2" epitope on the first type-III fibronectin domain (F1) of IR. Our results support the hypothesis that intersubunit flexibility of IR, governed by alternating modulation of buried intersubunit surface area, is the physical mechanism underlying a "see-saw" model of negative cooperativity.

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21 citations in Web of Science

19 citations in Scopus

Details

Title: Docking of insulin to a structurally equilibrated insulin receptor ectodomain
Creators: Harish Vashisth - Department of Chemical and Biological Engineering, Drexel University, Philadelphia, Pennsylvania 19104, USA
Cameron F Abrams
Publication Details: Proteins, structure, function, and bioinformatics, v 78(6), pp 1531-1543
Publisher: Wiley; United States
Resource Type: Journal article
Language: English
Academic Unit: Chemical and Biological Engineering
Web of Science ID: WOS:000276369700015
Scopus ID: 2-s2.0-77951214213
Other Identifier: 991014878001104721

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Web of Science research areas: Biochemistry & Molecular Biology; Biophysics

Docking of insulin to a structurally equilibrated insulin receptor ectodomain

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