Cryo-EM inspired NMR analysis reveals a pH-induced conformational switching mechanism for imparting dynamics to Betanodavirus protrusions

Abstract

AbstractNervous necrosis virus (NNV), a non-enveloped betanodavirus, causes neuropathies and retinopathies in farmed fish, damaging aquaculture worldwide. NNV has 60 conspicuous surface protrusions comprising the protrusion domain (P-domain) of its capsid protein. Although NNV protrusions play critical roles in infectivity, the underlying dynamics remain unclear. Our cryogenic electron microscopy (cryo-EM)-derived structures of Dragon grouper (Epinephelus lanceolatus) NNV reveal that the protrusions undergo low-pH-induced compaction and movement. We show that the P-domain is monomeric in solution at a pH germane to infection (7.0). Moreover, nuclear magnetic resonance (NMR) structures reveal a peptide (amino acids 311-330) that adopts a flexible loop to form an open pocket. NMR spectral analysis at pH 5.0 aided by molecular dynamics (MD) simulations show that this loop switches to a β-strand under acidic conditions, eliciting pocket closure and P-domain trimerization, highlighting a unique pH-sensing feature. Our docking analysis revealed the N-terminal moiety of sialic acid inserted into and interacting with conserved residues in the pocket. Additionally, a low-pH-induced conformational change in the linker region via peptide bond isomerization conferred malleability on the protrusions. Our work uncovers the protrusion dynamics of a betanodavirus governing its infectivity through a pH-dependent conformational switching mechanism, providing insights into complex virus-host interactions.