The C-terminal PARP domain of the long ZAP isoform contributes essential effector functions for CpG-directed antiviral activity

The zinc finger antiviral protein (ZAP) is a broad inhibitor of virus replication. Its best-characterized function is to bind CpG dinucleotides present in viral RNA and, through the recruitment of TRIM25, KHNYN and other cellular RNA degradation machinery, target them for degradation or prevent their translation. ZAPs activity requires the N-terminal RNA binding domain that selectively binds CpG-containing RNA. However, much less is known about the functional contribution of the remaining domains. Using ZAP-sensitive and ZAP-insensitive human immunodeficiency virus type I (HIV-1), we show that the catalytically inactive poly-ADP-ribose polymerase (PARP) domain of the long ZAP isoform (ZAP-L) is essential for CpG-specific viral restriction. Mutation of a crucial cysteine in the C-terminal CaaX box that mediates S-farnesylation and, to a lesser extent, the inactive catalytic site triad within the PARP domain, disrupted the activity of ZAP-L. Addition of the CaaX box to ZAP-S partly restored antiviral activity, explaining why ZAP-S lacks CpG-dependent antiviral activity despite conservation of the RNA-binding domain. Confocal microscopy confirmed the CaaX motif mediated localization of ZAP-L to vesicular structures and enhanced physical association with intracellular membranes. Importantly, the PARP domain and CaaX box together modulate the interaction between ZAP-L and its cofactors TRIM25 and KHNYN, implying that its proper subcellular localisation is required to establish an antiviral complex. The essential contribution of the PARP domain and CaaX box to ZAP-Ls CpG-directed antiviral activity was further confirmed by inhibition of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) replication. Thus, compartmentalization of ZAP-L on intracellular membranes provides an essential effector function in the ZAP-L-mediated antiviral activity. Author summaryCell-intrinsic antiviral factors, such as the zinc-finger antiviral protein (ZAP), provide a first line of defence against viral pathogens. ZAP acts by selectively binding CpG dinucleotide-rich RNAs, which are more common in some viruses than their vertebrate hosts, leading to their degradation. Here, we show that the ability to target these foreign elements is not only dependent on ZAPs N-terminal RNA-binding domain, but additional determinants in the central and C-terminal regions also regulate this process. The PARP domain and its associated CaaX box, are crucial for ZAPs CpG-specific activity and required for optimal binding to cofactors TRIM25 and KHNYN. Furthermore, a CaaX box, known to mediate post-translational modification by a hydrophobic S-farnesyl group, caused re-localization of ZAP from the cytoplasm and increased its association with intracellular membranes. This change in ZAPs distribution was essential for inhibition of both a ZAP-sensitized HIV-1 and SARS-CoV-2. Our work unveils how the determinants outside the CpG RNA-binding domain assist ZAPs antiviral activity and highlights the role of S-farnesylation and membrane association in this process.