Investigation of Interactions of the Rubella Virus P150 Replicase Protein with Host Cell Proteins in Infected Cells

Suppiah, Suganthi

15 April 2009

Due to their simplicity, viruses require the assistance of host factors for various aspects of their replication cycle. This study investigated the interaction of one of the two non-structural replicase proteins of rubella virus (RUBV), P150, with cell proteins. RUBV forms replication complexes for replicating its RNA in association with membranes of endosomes and lysosomes; the thusly modified endosomes/lysosomes are termed cytopathic vacuoles or CPVs. In the first study, a RUBV expressing a FLAG epitope-tagged P150 was used to co-immunoprecipitate putative interacting cell proteins from an infected cell lysate fraction enriched for CPVs using differential centrifugation. However, the only interacting protein identified was the companion RUBV replicase protein P90. Thus, cell proteins do not bind with either sufficient affinity or in stoichiometric amounts to be detected by this method and may not be a component of the virus holoenzyme. In the second study, a proline-rich region within P150 with three PxxPxR consensus SH3 domain-binding motifs was investigated for its ability to bind cell proteins. Substitution mutations (to alanine) of the two prolines were made in each of these motifs with the finding that mutations in the first two motifs led to lower viral titers and a small plaque phenotype with reversion to the wt sequence within one passage. Mutations in the third motif had a wt phenotype and did not revert. However, these mutations did not affect viral RNA synthesis, suggesting that the importance of these motifs is in a later stage of viral life cycle, e.g. virion assembly and release. To extend these findings, the proline hinge region with either the wt or mutant sequence was expressed as a GST-fusion in human cells. Pulldown experiments revealed specific binding with human p32 protein (gC1qR), which was previously shown to interact with the RUBV capsid protein. Binding of p32 with P150 was confirmed. The function of p32 in the RUBV replication cycle is unclear, but could involve virion assembly and release or induction of apoptosis.

Rubella virus

p32

Cytopathic vacuole

SH3 domain

Proteomics

Biology, general

Three-dimensional ultrastructural analysis of coronavirus and alphavirus rearrangements of host cell organelle membranes

Elaine M. Mihelc (5930042)

25 June 2020

Single-stranded positive-sense RNA viruses commonly rearrange host cell organelle membranes into neo-organelles which are involved in virus replication and assembly. These organelles serve to concentrate viral and host factors as well as to conceal viral RNA replication activities from host cell surveillance. To date, many virus-induced membrane rearrangements have been studied by targeted electron tomographic (ET) imaging of specific viral structures at timepoints of known interest. However, the broad cellular context within which these membrane modifications occur and how they change over time are not well understood. A question spanning many virus families is the morphological mechanism of formation of membrane rearrangements. Additionally, it is largely unknown how the membrane modifications affect the morphology of the organelle of origin. In this study, we address specific questions about virus-derived organelles induced by two positive-sense RNA viruses: the coronavirus mouse hepatitis virus (MHV) and the alphavirus Venezuelan equine encephalitis virus (VEEV). Utilizing serial sectioning and montage imaging for ET, volumes representing approximately 10% of virus-infected cells were imaged and detailed organelle analysis was performed. Using MHV-infected cells, we demonstrate that coronavirus-induced double-membrane vesicles (DMVs) are formed by budding from the endoplasmic reticulum (ER) and are trafficked to lysosomes for degradation. The ER remains largely morphologically normal early in infection despite the presence of hundreds of DMVs; however, late in infection, virus envelopment in the ER lumen leads to loss of cisternal morphology. For the alphavirus VEEV, we analyze the structure and origin of virus-derived cytopathic vacuoles II (CPVII). We identify four distinct morphological forms of CPVII and provide evidence that all four forms are derived from the Golgi apparatus. Additionally, a protocol is outlined for a newly-developed method for improved cell ultrastructure during genetically-encoded peroxidase tagging of membrane-proteins. This method is also amenable to ET. Overall, this work provides morphological cellular context for virus-induced membrane rearrangements from two families of positive-sense RNA viruses. Analysis of virus-host cell interactions from this large-scale ultrastructural perspective has the potential to lead to new approaches and strategies to combat current and future viral diseases.<br>

Cell Biology

Virology

electron microscopy

electron tomography

coronavirus

alphavirus

endoplasmic reticulum

Golgi

double membrane vesicle

cytopathic vacuole

membrane rearrangement