Mapping glycoprotein structure reveals Flaviviridae evolutionary history

• Published in: Nature (London) Vol. 633; no. 8030; pp. 695 - 703
• Main Authors: Mifsud, Jonathon C. O., Lytras, Spyros, Oliver, Michael R., Toon, Kamilla, Costa, Vincenzo A., Holmes, Edward C., Grove, Joe
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 19.09.2024; Nature Publishing Group
• Subjects: 631/114/2411; 631/326/596/2116; 631/326/596/2554; Animal human relations; Animals; Dengue fever; Evolution, Molecular; Evolutionary genetics; Flaviviridae; Flaviviridae - classification; Flaviviridae - genetics; Fusion protein; Gene mapping; Genomes; Glycoproteins; Glycoproteins - chemistry; Glycoproteins - genetics; Glycoproteins - metabolism; Hepatitis; Hepatitis C; Host range; Humanities and Social Sciences; Humans; Machine learning; Mapping; Membrane fusion; Membranes; Models, Molecular; Molecular modelling; Molecular structure; multidisciplinary; Pathogens; Peptide mapping; Phylogenetics; Phylogeny; Protein structure; Proteins; Science; Science (multidisciplinary); Tropism; Vector-borne diseases; Vertebrates; Viral Envelope Proteins - chemistry; Viral Envelope Proteins - genetics; Viral Envelope Proteins - metabolism; Virology; Viruses; West Nile virus; Zika virus
• ISSN: 0028-0836; 1476-4687; 1476-4687
• DOI: 10.1038/s41586-024-07899-8

Viral glycoproteins drive membrane fusion in enveloped viruses and determine host range, tissue tropism and pathogenesis 1 . Despite their importance, there is a fragmentary understanding of glycoproteins within the Flaviviridae 2 , a large virus family that include pathogens such as hepatitis C, dengue and Zika viruses, and numerous other human, animal and emergent viruses. For many flaviviruses the glycoproteins have not yet been identified, for others, such as the hepaciviruses, the molecular mechanisms of membrane fusion remain uncharacterized 3 . Here we combine phylogenetic analyses with protein structure prediction to survey glycoproteins across the entire Flaviviridae . We find class II fusion systems, homologous to the Orthoflavivirus E glycoprotein in most species, including highly divergent jingmenviruses and large genome flaviviruses. However, the E1E2 glycoproteins of the hepaciviruses, pegiviruses and pestiviruses are structurally distinct, may represent a novel class of fusion mechanism, and are strictly associated with infection of vertebrate hosts. By mapping glycoprotein distribution onto the underlying phylogeny, we reveal a complex evolutionary history marked by the capture of bacterial genes and potentially inter-genus recombination. These insights, made possible through protein structure prediction, refine our understanding of viral fusion mechanisms and reveal the events that have shaped the diverse virology and ecology of the Flaviviridae . Combined phylogenetic analyses and glycoprotein structure prediction across the Flaviviridae reveals divergent membrane fusion systems and provides insights into the complex evolutionary history within this family of viruses.