Structural Asymmetry of Flaviviruses
Abstract
Flaviviruses are enveloped, positive-strand RNA viruses that are spread by mosquitoes and ticks and can cause serious disease in humans. Flavivirus virions undergo extensive structural changes during their life cycle, including during maturation and fusion. Flaviviruses are initially assembled at the endoplasmic reticulum in a non-infectious, immature state, and then traffic to the trans-Golgi network, where a pH drop triggers a structural rearrangement of glycoproteins prM and E on the virus surface from 60 trimers to 90 dimers. A host protease, furin, then cleaves prM which makes the transition irreversible. Upon exiting the host cell, pr disassociates from the virus and the infectious, mature virus is able to enter a new cell. In Chapter 1, an overview of flaviviruses is presented, including a brief history of their discovery and interaction with humans, followed by what is known about their life cycle and the maturation process. The structure of a mature flavivirus is then described, including the symmetrical arrangement of glycoproteins on the virion surface, the lipid membrane, and the nucleocapsid core, followed by an introduction of the structural proteins that assemble into the virion. The structure of the immature flavivirus is then described. The chapter concludes with a description of the dynamics and heterogeneity observed for flaviviruses. The conformational rearrangementsthat occur during flavivirus maturation remain unclear. The structures of immature and mature flaviviruses determined with cryo-electron microscopy (cryo-EM) demonstrated that flaviviruses are icosahedral particles with 180 copies of glycoproteins on their surface. Icosahedral viruses typically have a quasi-equivalent arrangement of glycoproteins, but flaviviruses lack quasi-equivalence and instead the three subunits within an asymmetric unit occupy different chemical environments. Although the subunits are the same proteins, the unique environment of each subunit can be exploited for tracking subunits during conformational rearrangements. For example, the unique labeling of a subunit can be used to identify it in the immature and mature virion In Chapter 2, the maturation process was studied by developing tools to differentially label protein subunits and trap potential intermediates of maturation. The tools included heavy-atom compounds and antibody Fabs, which were used to probe Kunjin virus (KUNV), an Australian subtype of West Nile virus (WNV). One heavy-atom compound, potassium tetranitroplatinate(II), was found to derivatize immature KUNV, likely at sites on both E and prM. Higher-resolution studies will be required to determine if the compound differentially labeled the three subunits. The other tool developed was the E16 Fab. E16 Fab, originally isolated from a mouse immunized with WNV E and found to bind to two out of three subunits on mature WNV, was used to differentially label subunits in immature KUNV. Based on poor epitope accessibility on immature KUNV, E16 Fab was hypothesized to trap an intermediate state of maturation. In the cryo-EM reconstruction of E16 Fab bound to immature KUNV it was found that the virion had localized distorted density and apparent non-uniform binding of the E16 Fab. Based on this result it was proposed that flaviviruses had imperfect icosahedral symmetry. The structural asymmetry of immature and mature flaviviruses was investigated in Chapter 3. Icosahedral symmetry has always been imposed during cryo-EM reconstructions of flaviviruses, as it led to stable convergence of orientations.
Degree
Ph.D.
Advisors
Kuhn, Purdue University.
Subject Area
Pathology|Virology
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