Abstract

EphA1 is a receptor tyrosine kinase (RTK) that plays a key role in developmental processes, including guidance of the migration of axons and cells in the nervous system. EphA1, in common with other RTKs, contains an N-terminal extracellular domain, a single transmembrane (TM) α-helix, and a C-terminal intracellular kinase domain. The TM helix forms a dimer, as seen in recent NMR studies. We have modeled the EphA1 TM dimer using a multiscale approach combining coarse-grain (CG) and atomistic molecular dynamics (MD) simulations. The one-dimensional potential of mean force (PMF) for this system, based on interhelix separation, has been calculated using CG MD simulations. This provides a view of the free energy landscape for helix–helix interactions of the TM dimer in a lipid bilayer. The resulting PMF profiles suggest two states, consistent with a rotation-coupled activation mechanism. The more stable state corresponds to a right-handed helix dimer interacting via an N-terminal glycine zipper motif, consistent with a recent NMR structure (2K1K). A second metastable state corresponds to a structure in which the glycine zipper motif is not involved. Analysis of unrestrained CG MD simulations based on representative models from the PMF calculations or on the NMR structure reveals possible pathways of interconversion between these two states, involving helix rotations about their long axes. This suggests that the interaction of TM helices in EphA1 dimers may be intrinsically dynamic. This provides a potential mechanism for signaling whereby extracellular events drive a shift in the repopulation of the underlying TM helix dimer energy landscape.

Highlights

  • The Eph receptors play an important role in developmental processes including cell migration and axonal guidance.[1]

  • The results show that over 1 μs of CG molecular dynamics (MD) simulation the distribution of crossing angles exhibit a major population centered around −20° (Figure 3B), i.e., the same major population as that for the State 1 simulations

  • The State 1 configuration of the EphA1 dimer is in agreement both with the NMR structure[12] and with other theoretical studies.[46,64,66]

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Summary

Introduction

The Eph receptors play an important role in developmental processes including cell migration and axonal guidance.[1]. It has been postulated that Eph receptor dimers can switch between active and inactive configurations through a rotation coupling activation mechanism,[12,13] and recent mutational experiments highlighted more or less activated forms of the dimer compared to the wild-type EphA2 receptor in both ligand-dependent and -independent configurations.[14]. Taken together, these studies emphasize the importance of a better understanding of how EphA2 and related receptors may adopt alternative dimeric configurations and of how they may pass from one dimeric configuration to another

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