As many as five members of the APOBEC3 family of DNA cytosine deaminases are capable of inhibiting HIV-1 replication by deaminating viral cDNA cytosines and interfering with reverse transcription. HIV-1 counteracts restriction with the virally encoded Vif protein, which forms a hybrid ubiquitin ligase complex that directly binds APOBEC3 enzymes and targets them for proteasomal degradation. APOBEC3H (A3H) is unique among family members by dimerization through cellular and viral duplex RNA species. RNA binding is required for localization of A3H to the cytoplasmic compartment, for efficient packaging into nascent HIV-1 particles and ultimately for effective virus restriction activity. Here we compared wild-type human A3H and RNA binding-defective mutants to ask whether RNA may be a factor in the functional interaction with HIV-1 Vif. We used structural modeling, immunoblotting, live cell imaging, and split green fluorescence protein (GFP) reconstitution approaches to assess the capability of HIV-1 Vif to promote the degradation of wild-type A3H in comparison to RNA binding-defective mutants. The results combined to show that RNA is not strictly required for Vif-mediated degradation of A3H, and that RNA and Vif are likely to bind this single-domain DNA cytosine deaminase on physically distinct surfaces. However, a subset of the results also indicated that the A3H degradation process may be affected by A3H protein structure, subcellular localization, and differences in the constellation of A3H interaction partners, suggesting additional factors may also influence the fate and functionality of this host-pathogen interaction.

The APOBEC3 family of DNA cytosine deaminases is capable of restricting the replication of HIV-1 and other pathogens. Here, we report a 1.92 Å resolution crystal structure of the Vif-binding and catalytic domain of APOBEC3F (A3F). This structure is distinct from the previously published APOBEC and phylogenetically related deaminase structures, as it is the first without zinc in the active site. We determined an additional structure containing zinc in the same crystal form that allows direct comparison with the zinc-free structure. In the absence of zinc, the conserved active site residues that normally participate in zinc coordination show unique conformations, including a 90 degree rotation of His249 and disulfide bond formation between Cys280 and Cys283. We found that zinc coordination is influenced by pH, and treating the protein at low pH in crystallization buffer is sufficient to remove zinc. Zinc coordination and catalytic activity are reconstituted with the addition of zinc only in a reduced environment likely due to the two active site cysteines readily forming a disulfide bond when not coordinating zinc. We show that the enzyme is active in the presence of zinc and cobalt but not with other divalent metals. These results unexpectedly demonstrate that zinc is not required for the structural integrity of A3F and suggest that metal coordination may be a strategy for regulating the activity of A3F and related deaminases.