A Poxvirus Decapping Enzyme Colocalizes with Mitochondria To Regulate RNA Metabolism and Translation and Promote Viral Replication.

Decapping enzymes remove the 5' cap of eukaryotic mRNA, leading to accelerated RNA decay. They are critical in regulating RNA homeostasis and play essential roles in many cellular and life processes. They are encoded in many organisms and viruses, including vaccinia virus, which was used as the vaccine to eradicate smallpox. Vaccinia virus encodes two decapping enzymes, D9 and D10, that are necessary for efficient viral replication and pathogenesis. However, the underlying molecular mechanisms regulating vaccinia decapping enzymes' functions are still largely elusive. Here, we demonstrated that vaccinia D10 almost exclusively colocalized with mitochondria. As mitochondria are highly mobile cellular organelles, colocalization of D10 with mitochondria can concentrate D10 locally and mobilize it to efficiently decap mRNAs. Mitochondria were barely observed in "viral factories," where viral transcripts are produced, suggesting that mitochondrial colocalization provides a spatial mechanism to preferentially decap cellular mRNAs over viral mRNAs. We identified three amino acids at the N terminus of D10 that are required for D10's mitochondrial colocalization. Loss of mitochondrial colocalization significantly impaired viral replication, reduced D10's ability to remove the RNA 5' cap during infection, and diminished D10's gene expression shutoff and mRNA translation promotion abilities. Decapping enzymes comprise many members from various organisms, ranging from plants, animals, and viruses. The mechanisms regulating their functions vary and are still largely unknown. Our study provides evidence that a vaccinia virus-encoded decapping enzyme, D10, colocalizes with mitochondria. Loss of mitochondrial colocalization significantly impairs viral replication, D10's gene expression shutoff, and mRNA translation promotion ability. Overall, our results suggest that mitochondrial colocalization is a spatial mechanism to concentrate D10 locally and mobilize it to efficiently and preferentially target cellular mRNAs for decapping and promote viral mRNA translation. Our results have broad impacts for understanding the functions and regulatory mechanisms of decapping enzymes.