Budded baculovirus particle structure revisited

Highlights • Baculovirus budded virion ultrastructure has been revisited using cryo-electron microscopy. • The now well-preserved virions have a remarkable elongated, ovoid shape and large lateral space between nucleocapsid and the intact envelope. • Consistent with previous findings using classical electron microscopy the nucleocapsid has a distinctive cap and base structure interacting tightly with the envelope. • Most spikes are densely clustered at the two apical ends of the virion. Using cryo-electron microscopy the viral envelope appeared to contain two layers with a total thickness of ≈6–7 nm, which is significantly thicker than a usual biological membrane (
Baculoviruses are a group of enveloped, double-stranded DNA insect viruses with budded (BV) and occlusion-derived (ODV) virions produced during their infection cycle. BVs are commonly described as rod shaped particles with a high apical density of protein extensions (spikes) on the lipid envelope surface. However, due to the fragility of BVs the conventional purification and electron microscopy (EM) staining methods considerably distort the native viral structure. Here, we use cryo-EM analysis to reveal the near-native morphology of two intensively studied baculoviruses, Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) and Spodoptera exigua MNPV (SeMNPV), as models for BVs carrying GP64 and F as envelope fusion protein on the surface. The now well-preserved AcMNPV and SeMNPV BV particles have a remarkable elongated, ovoid shape leaving a large, lateral space between nucleocapsid (NC) and envelope. Consistent with previous findings the NC has a distinctive cap and base structure interacting tightly with the envelope. This tight interaction may explain the partial retaining of the envelope on both ends of the NC and the disappearance of the remainder of the BV envelope in the negative-staining EM images. Cryo-EM also reveals that the viral envelope contains two layers with a total thickness of ≈6–7 nm, which is significantly thicker than a usual biological membrane (