Abstract
Coronavirus particles assemble at endoplasmic reticulum Golgi intermediate compartment (ERGIC) membranes and exit from host cells via secretory organelles that are not well defined. The interplay between viral components and intracellular transport pathways that facilitate assembly and egress are not fully understood and recent studies suggest that multiple pathways maybe involved. Reverse genetics was used to develop a model system to further understand the assembly and egress processes. Mouse hepatitis coronavirus (MHV-A59) was genetically engineered to express the membrane (M) protein fused to green fluorescent protein (M-GFP), with the chimeric gene cloned in place of the open reading frame (ORF) 4 coding region in the RNA genome. The recovered M-GFP virus also expresses wild-type (WT) M protein (M WT) from its native ORF. The M-GFP virus exhibited morphology and growth properties like WT virus. M-GFP and WT M proteins colocalized early in infection, but less M-GFP trafficked toward the cell surface at later times, suggesting that the fusion protein is incorporated less efficiently into virus particles. M-GFP was stably expressed through at least four virus passages. Early passage virus M-GFP virus particles were visualized by confocal and Total Internal Reflection Fluorescence (TIRF) microscopy in live cells. The fluorescently labeled virus particles represent a new tool for coronavirus intracellular trafficking and egress studies. Such studies can also help provide a more detailed understanding of infection and disease processes to provide new insight for development of new therapeutic strategies.