Rebekah E. Dumm scite author profile

Summary Many viral RNAs are modified by methylation of the N6 position of adenosine (m6A). m6A is thought to regulate RNA splicing, stability, translation and secondary structure. Influenza A virus (IAV) expresses m6A-modified RNAs but the effects of m6A on this segmented RNA virus remain unclear. We demonstrate that global inhibition of m6A addition inhibits IAV gene expression and replication. In contrast, overexpression of the cellular m6A “reader” protein YTHDF2 increases IAV gene expression and replication. To address whether m6A residues modulate IAV RNA function in cis, we mapped m6A residues on the IAV plus (mRNA) and minus (vRNA) strands and used synonymous mutations to ablate m6A on both strands of the hemagglutinin (HA) segment. These mutations inhibited HA mRNA and protein expression, while leaving other IAV mRNAs and proteins unaffected, and also resulted in reduced IAV pathogenicity in mice. Thus, m6A residues in IAV transcripts enhance viral gene expression.

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A CRISPR Activation Screen Identifies a Pan-avian Influenza Virus Inhibitory Host Factor

Heaton

et al. 2017

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Summary Influenza A virus (IAV) is a pathogen that poses significant risks to human health. It is therefore critical to develop strategies to prevent influenza disease. Many loss-of-function screens have been performed to identify the host proteins required for viral infection. However, there has been no systematic screen to identify the host factors that when over-expressed are sufficient to prevent infection. In this study, we utilized CRISPR/dCas9 activation technology to perform a genome-wide overexpression screen to identify IAV restriction factors. The major hit from our screen, B4GALNT2, showed inhibitory activity against influenza viruses with an α2,3 linked sialic acid receptor preference. In fact, B4GALNT2 overexpression prevented the infection of every avian influenza virus strain tested, including the H5, H9, and H7 subtypes, which have previously caused disease in humans. Thus, we have utilized CRISPR/dCas9 activation technology to identify a factor that can completely abolish infection by avian influenza viruses.

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Rationally Designed Influenza Virus Vaccines That Are Antigenically Stable during Growth in Eggs

Harding

Heaton

Dumm

et al. 2017

mBio

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Influenza virus vaccine production is currently limited by the ability to grow circulating human strains in chicken eggs or in cell culture. To facilitate cost-effective growth, vaccine strains are serially passaged under production conditions, which frequently results in mutations of the major antigenic protein, the viral hemagglutinin (HA). Human vaccination with an antigenically drifted strain is known to contribute to poor vaccine efficacy. To address this problem, we developed a replication-competent influenza A virus (IAV) with an artificial genomic organization that allowed the incorporation of two independent and functional HA proteins with different growth requirements onto the same virion. Vaccination with these viruses induced protective immunity against both strains from which the HA proteins were derived, and the magnitude of the response was as high as or higher than vaccination with either of the monovalent parental strains alone. Dual-HA viruses also displayed remarkable antigenic stability; even when using an HA protein known to be highly unstable during growth in eggs, we observed high-titer virus amplification without a single adaptive mutation. Thus, the viral genomic design described in this work can be used to grow influenza virus vaccines to high titers without introducing antigenic mutations.

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Rebekah E. Dumm

Epitranscriptomic Enhancement of Influenza A Virus Gene Expression and Replication

A CRISPR Activation Screen Identifies a Pan-avian Influenza Virus Inhibitory Host Factor

Rationally Designed Influenza Virus Vaccines That Are Antigenically Stable during Growth in Eggs

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