Compositional analysis of yellow fever virus induced stress granules reveals a functional connection to mitochondrial homeostasis
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The phase separation of biomolecules into so-called stress granules (SGs) allows the cell to tightly regulate translation activity in response to different stimuli, such as oxidative stress, starvation, or the recognition of non-cellular RNA. Recent reports suggest SGs induced during viral infection, may act as a crossroad between the cellular stress response and the activation of the innate immune response.
Here, we aimed to dissect the role of SGs in the context of yellow fever virus (YFV) infection. We found that YFV infection resulted in translational shut-off from 24 hpi on followed by the formation of SGs at 48 hpi, a delay potentially associated with the ability of the YFV capsid to inhibit SG formation, through an interaction with the major SG scaffolding protein G3BP1. To elucidate the role of YFV-induced SGs during infection, we inhibited SG assembly using a small-molecule inhibitor and find that SG formation does not influence viral replication. Uncovering the first proteome of virus-induced SGs, our compositional analysis revealed a specific enrichment of proteins associated with mitochondrial processes in YFV-induced SGs. Indeed, we show that YFV infection results in mitochondrial damage and dysfunction. Together, we propose that YFV-induced SGs may be involved not only in the modulation of cellular homeostasis but also in influencing mitochondrial functions.
Author Summary
Viruses impose a major burden on the infected host – from structural rearrangements needed to assemble replication complexes, to exploiting cellular energy resources and genetic rewiring associated with antiviral responses. The assembly of membrane-less organelles such as stress granules (SGs) enable cells to rapidly tune cellular processes upon sensing of stresses such as viruses. Moreover, the cell’s innate immune response is proposed to be regulated by SGs and in turn many viruses disrupt or highjack their components. Yet, the molecular basis for SG functions during infection remain ambiguous.
Here we investigated the interplay between yellow fever virus (YFV) infection and SGs. We demonstrate that infection with attenuated or pathogenic viruses result in the formation of SGs. Their compositional analysis reveal that they sequester mitochondrial proteins, correlating with altered mitochondrial functions during infection. This highlights a novel complex interplay between membrane-bound and membrane-less organelles which could present novel opportunities for antiviral therapies.
