Marseilleviruses biological properties and viral translation-associated proteins based onin silicotertiary structure

Abstract

AbstractMarseilleviruses are a group of double-strand DNA viruses that infect amoeba within theNucleocytoviricotaphylum and are ubiquitous in water and soil globally. Here, we report four novel strains isolated from mangroves in Guangdong province, China, namely, futianmevirus, futianmfvirus, dashavirus str. E, and xiwanvirus. Viral particles presented about 220∼240 nm icosahedrally shaped capsids and were wrapped by membranes to form giant vesicles. Based on stability assays, viral particles were halotolerant and acid-tolerant, but sensitive to chloroform and high temperature, while giant vesicles conferred thermal and acid/alkaline resistance to particles. Genomics and phylogenetic analyses showed that the four strains formed divergent branches within different lineages of marseillevirus. Notably, to our knowledge, futianmevirus was the first reported marseillevirus lacking translation elongation factor EF-1alpha (EF1A). Ourin silicoanalysis of marseillevirus coded translation-associated homolgs suggested their conserved functions. Additionally, we predicted at least four novel proteins that were structurally similar to components of the protozoan ribosome. Overall, not only our data comprehensively described the diversity of marseillevirus biological properties, but also proposed a new perspective on the giant virus translation system.ImportanceThe familyMarseilleviridaewas the second reported family of giant viruses and distributed globally. In this work, we reported the four novel marseilleviruses isolated from saltwater samples of mangrove. Difference of biological properties between giant vesicles and viral particles revealed the environment fitness of marseillevirus.On the other hand, sensitivity to chloroform indicated the importance of lipid components for viral infection. Additionally, our comparative genomics, phylogenetic analysis, and protein structure comparison revealed the diverse translation-associated gene sets of marseilleviruses. The prediction of ribosome components expands the knowledge about the giant viral translation-associated proteins, and will be helpful in future to reveal how giant viruses hijack the amoeba translation system.