Marseilleviridae is a family of the new order of giant viruses, which exhibit a characteristic inner membrane. Here, we investigated the entire structure of tokyovirus, a species of Marseillevirus at 7.7 Å resolution using 1 MV high-voltage cryo-EM and single particle analysis. The minor capsid lattice formed by five proteins, shows a novel structure compared to other icosahedral giant viruses. Under the minor capsid proteins, scaffold proteins connect two five-fold vertices and interact with the inner membrane. Previously reported giant viruses utilise ″tape measure″ proteins, proposed to control its capsid size, which could not be identified in tokyovirus, but scaffold proteins appear to perform a similar role. A density on top of the major capsid protein was identified, which suggested to be a 14kDa glycoprotein. Our observations suggest that the icosahedral particle of Marseilleviridae is constructed with a novel capsid protein network, which allows the characteristic inner membrane structure.
Members of Marseilleviridae, one family of icosahedral giant viruses classified in 2012 have been identified worldwide in all types of environments. The virion shows a characteristic internal membrane extrusion at the five-fold vertices of the capsid, but its structural details need to be elucidated. We now report the 4.4 Å cryo-electron microscopy structure of the Melbournevirus capsid. An atomic model of the major capsid protein (MCP) shows a unique cup structure on the trimer that accommodates additional proteins. A polyalanine model of the penton base protein shows internally extended N- and C-terminals, which indirectly connect to the internal membrane extrusion. The Marseilleviruses share the same orientational organisation of the MCPs as PBCV-1 and CroV, but do not appear to possess a protein akin to the ″tape measure″ of these viruses. Minor capsid proteins named PC-β, zipper, and scaffold are proposed to control the dimensions of the capsid during assembly.
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