Divergence in poxvirus-encoded E3-like proteins can dictate poxvirus activation of cellular necroptosis

Poxviruses encode a plethora of proteins to modulate diverse cellular responses against viruses. Poxvirus-encoded E3-like proteins are multifunctional, regulating diverse cellular antiviral responses. The canonical Vaccinia E3-like proteins have two domains: an N-terminal Z-form nucleic acid binding domain (Zα-BD) and a C-terminal double-stranded RNA binding domain (dsRNA-BD)-.Using protein sequence and structural homology modeling, we identified the presence of dsRNA- BD-containing proteins in all the poxviruses except Avipoxviruses, Salmon poxvirus and Entemopoxviruses. However, the acquisition of these proteins likely happened under three distinct events. Using structural homology modeling and FATCAT score, we can classify E3-like proteins in three distinct categories: i) the E3-like proteins with highly conserved dsRNA-BD but with or without the N-terminal domain, present in most poxviruses; ii) unconventional E3-like proteins with highly diverged dsRNA-BD, present in Macropoxvirus and Molluscipoxvirus and iii) E3-like protein with dsRNA-BD that may have different origin present in Crocodilepoxvirus. ^12–52–6

Members of Leporipoxvirus, Waddenpoxvirus, Cetaceanpoxvirus, and selected members of Orthopoxvirus contain E3-like proteins missing the N-terminal Zα-BD required for necroptosis inhibition. Additionally, using Alphafold, we show that the Zα-BD of Chordopoxviruses E3-like proteins is structurally more variable than the ds-RNA binding domain. Compared to members of Orthopoxviruses–Vaccinia virus (VACV) and Cowpox virus (CPXV) that have been shown to inhibit necroptosis and contain an N-terminus Zα-BD of the canonical E3 protein, our results show that members of leporipoxviruses induce necroptosis in human and mouse necroptosis competent cell lines. Furthermore, myxoma virus (MYXV) infection activates RIP1 and RIP3-mediated necroptosis in both human and mouse necroptosis-competent cells. These data suggest that Leporipoxviruses lack countermeasures to necroptosis compared to Orthopoxviruses that encode multiple key regulators of necroptosis, possibly due to a lack of selective pressure within the viral host species (Lagomorphs).