An Autoimmunity-associated allele of enhances the innate immune response to promote protection against acute coronavirus infection.

Allelic variation can impact viral clearance and disease severity, but the effect of the autoimmunity-associated allelic variant of (PEP-R619W) on antiviral immunity remains incomplete. This research defines how the loss of (PEP-null) and PEP-R619W changes antiviral immunity during acute coronavirus infection. We address the hypothesis that CRISPR/Cas9-generated PEP-null and PEP-R619W mice have enhanced antiviral immunity over PEP-WT mice during coronavirus infection. Following Mouse Hepatitis Virus (MHV) A59 infection, we interrogated pathology, cytokine production, and cellular responses in the blood, spleen, and liver of PEP-WT, PEP-null, and PEP-R619W mice. Key findings show that PEP-R619W mice have reduced viral titer and weight loss, increased survival, and more mature NK cells in the liver and spleen compared to PEP-WT mice. Interestingly, protection against disease in PEP-null mice was inoculation-dose-dependent, whereas PEP-R619W conferred immunity regardless of infection dose. Further, Rag1-/- PEP-R619W mice had increased survival and reduced viral titer over Rag1-/- PEP-WT mice. PEP-R619W mice also had higher concentrations of IFNγ and enhanced IFNγ production by mature NK cells in the liver at 3 days post-infection. Finally, NK cell depletion elevated PEP-R619W viral titer to similar levels as PEP-WT mice. This is one of the first studies investigating the role of within NK cells and demonstrates that the allelic variant augments NK cell function and is beneficial during coronavirus infection.