Origins of Enterovirus Replication Organelles Established by Whole-Cell Electron Microscopy.

Charlotte E Melia,Frank J M Van Kuppeveld,Hilde M Van Der Schaar,Eric J Snijder,Abraham J Koster,Christopher J Peddie,Montserrat Bárcena,Anja W M De Jong,Lucy M Collinson,Michael J Buchmeier

doi:10.1128/mbio.00951-19

Abstract

Enterovirus genome replication occurs at virus-induced structures derived from cellular membranes and lipids. However, the origin of these replication organelles (ROs) remains uncertain. Ultrastructural evidence of the membrane donor is lacking, suggesting that the sites of its transition into ROs are rare or fleeting. To overcome this challenge, we combined live-cell imaging and serial block-face scanning electron microscopy of whole cells to capture emerging enterovirus ROs. The first foci of fluorescently labeled viral protein correlated with ROs connected to the endoplasmic reticulum (ER) and preceded the appearance of ROs stemming from the trans-Golgi network. Whole-cell data sets further revealed striking contact regions between ROs and lipid droplets that may represent a route for lipid shuttling to facilitate RO proliferation and genome replication. Our data provide direct evidence that enteroviruses use ER and then Golgi membranes to initiate RO formation, demonstrating the remarkable flexibility with which enteroviruses usurp cellular organelles.IMPORTANCE Enteroviruses are causative agents of a range of human diseases. The replication of these viruses within cells relies on specialized membranous structures termed replication organelles (ROs) that form during infection but whose origin remains elusive. To capture the emergence of enterovirus ROs, we use correlative light and serial block-face scanning electron microscopy, a powerful method to pinpoint rare events in their whole-cell ultrastructural context. RO biogenesis was found to occur first at ER and then at Golgi membranes. Extensive contacts were found between early ROs and lipid droplets (LDs), which likely serve to provide LD-derived lipids required for replication. Together, these data establish the dual origin of enterovirus ROs and the chronology of their biogenesis at different supporting cellular membranes.

Highlights

Enterovirus genome replication occurs at virus-induced structures derived from cellular membranes and lipids
To assess the resolving power of serial block-face scanning electron microscopy (SBF-SEM) on enterovirus-infected cell ultrastructure, Vero E6 cells were infected with coxsackie B virus 3 (CVB3) and fixed at 6 h postinfection
SBF-SEM images were compared with higher-resolution transmission electron microscopy (TEM) images collected from the same type of samples (Fig. S1A and B), confirming that enterovirus replication organelles (ROs) were discernible in the SBF-SEM data

Summary

Introduction

Enterovirus genome replication occurs at virus-induced structures derived from cellular membranes and lipids. IMPORTANCE Enteroviruses are causative agents of a range of human diseases The replication of these viruses within cells relies on specialized membranous structures termed replication organelles (ROs) that form during infection but whose origin remains elusive. Extensive contacts were found between early ROs and lipid droplets (LDs), which likely serve to provide LD-derived lipids required for replication Together, these data establish the dual origin of enterovirus ROs and the chronology of their biogenesis at different supporting cellular membranes. The production of novel membrane structures is an intriguing and highly conserved feature of positive-sense RNA (ϩRNA) virus infections These modified host cell membranes are increasingly referred to as viral replication organelles (ROs), distinct membrane structures that have been suggested to serve as platforms for viral RNA synthesis by coordinating different stages of the viral replicative cycle and/or shielding viral products from innate immune sensors [1,2,3].

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