Jillian S. Shapiro scite author profile

Cellular utilization of RNA interference (RNAi) as a mechanism to combat virus infection is thought to be restricted to plants and invertebrates. In vertebrates, antiviral defenses are largely dependent on interferons (IFNs), with the use of small RNAs restricted to microRNA (miRNA)-mediated targeting of host transcripts. Here we demonstrate that incorporation of a primary miRNA into a cytoplasmic virus results in the formation of a Dicer-dependent, DGCR8-independent, mature miRNA capable of conferring RNAi-like activity. Processing of the viral mirtron-like product (virtron) is indistinguishable from endogenous miRNA maturation and elicits post-transcriptional gene silencing, albeit at a reduced level. Furthermore, virtrons impose Dicerdependent, microprocessor-independent, and IFN-independent interference on virus replication in a sequence-specific manner. Taken together, these results suggest the existence of a noncanonical, small-RNA-based activity capable of processing cytoplasmic hairpins and perhaps contributing to the cell's antiviral arsenal.

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Evidence for a cytoplasmic microprocessor of pri-miRNAs

Shapiro¹,

Langlois²,

Pham³

et al. 2012

RNA

106

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microRNAs (miRNAs) represent a class of noncoding RNAs that fine-tune gene expression through post-transcriptional silencing. While miRNA biogenesis occurs in a stepwise fashion, initiated by the nuclear microprocessor, rare noncanonical miRNAs have also been identified. Here we characterize the molecular components and unique attributes associated with the processing of virus-derived cytoplasmic primary miRNAs (c-pri-miRNAs). RNA in situ hybridization and inhibition of cellular division demonstrated a complete lack of nuclear involvement in c-pri-miRNA cleavage while genetic studies revealed that maturation still relied on the canonical nuclear RNase III enzyme, Drosha. The involvement of Drosha was mediated by a dramatic relocalization to the cytoplasm following virus infection. Deep sequencing analyses revealed that the cytoplasmic localization of Drosha does not impact the endogenous miRNA landscape during infection, despite allowing for robust synthesis of virus-derived miRNAs in the cytoplasm. Taken together, this research describes a unique function for Drosha in the processing of highly structured cytoplasmic RNAs in the context of virus infection.

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Degradation of Host MicroRNAs by Poxvirus Poly(A) Polymerase Reveals Terminal RNA Methylation as a Protective Antiviral Mechanism

Backes

Shapiro

Sabin

et al. 2012

Cell Host & Microbe

107

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SUMMARY The life cycle of several viruses involves host or virally encoded small noncoding RNAs, which play important roles in posttranscriptional regulation. Small noncoding RNAs include microRNAs (miRNAs), which modulate the transcriptome, and small interfering RNAs (siRNAs), which are involved in pathogen defense in plants, worms, and insects. We show that insect and mammalian poxviruses induce the degradation of host miRNAs. The virally encoded poly(A) polymerase, which polyadenylates viral transcripts, also mediates 3′ polyadenylation of host miRNAs, resulting in their degradation by the host machinery. In contrast, siRNAs, which are protected by 2′O-methylation (2′OMe), were not targeted by poxviruses. These findings suggest that poxviruses may degrade host miRNAs to promote replication and that virus-mediated small RNA degradation likely contributed to 2′OMe evolution.

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MicroRNA-based strategy to mitigate the risk of gain-of-function influenza studies

et al. 2013

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Recent gain-of-function studies in influenza A virus H5N1 strains revealed that as few as three amino-acid changes in the hemagglutinin protein confer the capacity for viral transmission between ferrets1, 2. As transmission between ferrets is considered a surrogate indicator of transmissibility between humans, these studies raised concerns about the risks of gain-of-function influenza A virus research. Here we present an approach to strengthen the biosafety of gain-of-function influenza experiments. We exploit species-specific endogenous small RNAs to restrict influenza A virus tropism. In particular, we found that the microRNA miR-192 was expressed in primary human respiratory tract epithelial cells as well as mouse lungs but absent from the ferret respiratory tract. Incorporation of miR-192 target sites into influenza A virus did not prevent influenza replication and transmissibility in ferrets, but did attenuate influenza pathogenicity in mice. This molecular biocontainment approach should be applicable beyond influenza A virus to minimize the risk of experiments involving other pathogenic viruses.

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Drosha as an interferon-independent antiviral factor

Shapiro

Schmid

Aguado

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Significance Virus infections must be combated at a cellular level. The strategies used to inhibit virus differ dramatically when comparing plants and insects to mammals. Here, we identify an evolutionary conserved antiviral response that is independent of these known defenses. We demonstrate that an RNA nuclease called Drosha is repurposed during virus infection to cleave viral RNA and modulate the cellular environment as a means of inhibiting virus replication.

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