Stimulation of Nipah Fusion: Small Intradomain Changes Trigger Extensive Interdomain Rearrangements

Biophys J. 2016 Oct 18;111(8):1621-1630. doi: 10.1016/j.bpj.2016.09.002.

Abstract

Nipah is an emerging paramyxovirus that is of serious concern to human health. It invades host cells using two of its membrane proteins-G and F. G binds to host ephrins and this stimulates G to activate F. Upon activation, F mediates virus-host membrane fusion. Here we focus on mechanisms that underlie the stimulation of G by ephrins. Experiments show that G interacts with ephrin and F through separate sites located on two different domains, the receptor binding domain (RBD) and the F activation domain (FAD). No models explain this allosteric coupling. In fact, the analogous mechanisms in other paramyxoviruses also remain undetermined. The structural organization of G is such that allosteric coupling must involve at least one of the two interfaces-the RBD-FAD interface and/or the RBD-RBD interface. Here we examine using molecular dynamics the effect of ephrin binding on the RBD-RBD interface. We find that despite inducing small changes in individual RBDs, ephrin reorients the RBD-RBD interface extensively, and in a manner that will enhance solvent exposure of the FAD. While this finding supports a proposed model of G stimulation, we also find from additional simulations that ephrin induces a similar RBD-RBD reorientation in a stimulation-deficient G mutant, V209 VG → AAA. Together, our simulations suggest that while inter-RBD reorientation may be important, it is not, by itself, a sufficient condition for G stimulation. Additionally, we find that the mutation affects the conformational ensemble of RBD globally, including the RBD-FAD interface, suggesting the latter's role in G stimulation. Because ephrin induces small changes in individual RBDs, a proper analysis of conformational ensembles required that they are compared directly-we employ a method we developed recently, which we now release at SimTK, and show that it also performs excellently for non-Gaussian distributions.

MeSH terms

  • Ephrins / metabolism
  • Models, Molecular*
  • Mutation
  • Nipah Virus / genetics
  • Nipah Virus / metabolism
  • Nipah Virus / physiology*
  • Protein Binding
  • Protein Domains
  • Viral Matrix Proteins / chemistry*
  • Viral Matrix Proteins / genetics
  • Viral Matrix Proteins / metabolism*
  • Virus Internalization*

Substances

  • Ephrins
  • Viral Matrix Proteins