Abstract
The epidermal growth factor receptor (EGFR) is a member of the receptor tyrosine kinase family that plays a role in multiple cellular processes. Activation of EGFR requires binding of a ligand on the extracellular domain to promote conformational changes leading to dimerization and transphosphorylation of intracellular kinase domains. Seven ligands are known to bind EGFR with affinities ranging from sub-nanomolar to near micromolar dissociation constants. In the case of EGFR, distinct conformational states assumed upon binding a ligand is thought to be a determining factor in activation of a downstream signaling network. Previous biochemical studies suggest the existence of both low affinity and high affinity EGFR ligands. While these studies have identified functional effects of ligand binding, high-resolution structural data are lacking. To gain a better understanding of the molecular basis of EGFR binding affinities, we docked each EGFR ligand to the putative active state extracellular domain dimer and 25.0 ns molecular dynamics simulations were performed. MM-PBSA/GBSA are efficient computational approaches to approximate free energies of protein-protein interactions and decompose the free energy at the amino acid level. We applied these methods to the last 6.0 ns of each ligand-receptor simulation. MM-PBSA calculations were able to successfully rank all seven of the EGFR ligands based on the two affinity classes: EGF>HB-EGF>TGF-α>BTC>EPR>EPG>AR. Results from energy decomposition identified several interactions that are common among binding ligands. These findings reveal that while several residues are conserved among the EGFR ligand family, no single set of residues determines the affinity class. Instead we found heterogeneous sets of interactions that were driven primarily by electrostatic and Van der Waals forces. These results not only illustrate the complexity of EGFR dynamics but also pave the way for structure-based design of therapeutics targeting EGF ligands or the receptor itself.
Highlights
Receptor tyrosine kinases (RTK) play essential roles in numerous cellular processes
To explore the differences in binding affinity of an epidermal growth factor receptor (EGFR) ligand to the receptor, we chose to use computational methods to dock each ligand to the extracellular domain of EGFR and compute the relative free energies
Due to high computational costs, accuracy of force field parameters, and complexity of large solvated systems, computational free energy studies can be time consuming and may only yield approximate binding affinities. With these limitations in mind, we chose to simulate the sEGFR dimer bound to each ligand and compute only relative free energy differences
Summary
Receptor tyrosine kinases (RTK) play essential roles in numerous cellular processes. Activation of an RTK by a particular ligand(s) enables transduction of a biological signal from the membrane surface to intracellular signaling pathways [1]. Ligand binding to the extracellular domain of an RTK promotes dimerization, leading to auto-phosphorylation by the intracellular kinase domain [2]. One subgroup of the RTK family, the ErbB or Her family, includes the epidermal growth factor receptor (EGFR, ErbB1, Her). EGFR is necessary for cell proliferation and survival. Misregulation of the ErbB family, either through ErbB ligands or the receptors themselves, has been implicated in several diseases including glioblastoma, breast, skin, and lung cancer [3]
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