Mechanism for APOBEC3G catalytic exclusion of RNA and non-substrate DNA.

The potent antiretroviral protein APOBEC3G (A3G) specifically targets and deaminates deoxycytidine nucleotides, generating deoxyuridine, in single stranded DNA (ssDNA) intermediates produced during HIV replication. A non-catalytic domain in A3G binds strongly to RNA, an interaction crucial for recruitment of A3G to the virion; yet, A3G displays no deamination activity for cytidines in viral RNA. Here, we report NMR and molecular dynamics (MD) simulation analysis for interactions between A3Gctd and multiple substrate or non-substrate DNA and RNA, in combination with deamination assays. NMR ssDNA-binding experiments revealed that the interaction with residues in helix1 and loop1 (T201-L220) distinguishes the binding mode of substrate ssDNA from non-substrate. Using 2'-deoxy-2'-fluorine substituted cytidines, we show that a 2'-endo sugar conformation of the target deoxycytidine is favored for substrate binding and deamination. Trajectories of the MD simulation indicate that a ribose 2'-hydroxyl group destabilizes the π-π stacking of the target cytosine and H257, resulting in dislocation of the target cytosine base from the catalytic position. Interestingly, APOBEC3A, which can deaminate ribocytidines, retains the ribocytidine in the catalytic position throughout the MD simulation. Our results indicate that A3Gctd catalytic selectivity against RNA is dictated by both the sugar conformation and 2'-hydroxyl group.

Impact of H216 on the DNA binding and catalytic activities of the HIV restriction factor APOBEC3G.

APOBEC3G has an important role in human defense against retroviral pathogens, including HIV-1. Its single-stranded DNA cytosine deaminase activity, located in its C-terminal domain (A3Gctd), can mutate viral cDNA and restrict infectivity. We used time-resolved nuclear magnetic resonance (NMR) spectroscopy to determine kinetic parameters of A3Gctd's deamination reactions within a 5'-CCC hot spot sequence. A3Gctd exhibited a 45-fold preference for 5'-CCC substrate over 5'-CCU substrate, which explains why A3G displays almost no processivity within a 5'-CCC motif. In addition, A3Gctd's shortest substrate sequence was found to be a pentanucleotide containing 5'-CCC flanked on both sides by a single nucleotide. A3Gctd as well as full-length A3G showed peak deamination velocities at pH 5.5. We found that H216 is responsible for this pH dependence, suggesting that protonation of H216 could play a key role in substrate binding. Protonation of H216 appeared important for HIV-1 restriction activity as well, since substitutions of H216 resulted in lower restriction in vivo.

Prokaryotic ubiquitin-like protein pup is intrinsically disordered.

The prokaryotic ubiquitin-like protein Pup targets substrates for degradation by the Mycobacterium tuberculosis proteasome through its interaction with Mpa, an ATPase that is thought to abut the 20S catalytic subunit. Ubiquitin, which is assembled into a polymer to similarly signal for proteasomal degradation in eukaryotes, adopts a stable and compact structural fold that is adapted into other proteins for diverse biological functions. We used NMR spectroscopy to demonstrate that, unlike ubiquitin, the 64-amino-acid protein Pup is intrinsically disordered with small helical propensity in the C-terminal region. We found that the Pup:Mpa interaction involves an extensive contact surface that spans S21-K61 and that the binding is in the "slow exchange" regime on the NMR time scale, thus demonstrating higher affinity than most ubiquitin:ubiquitin receptor pairs. Interestingly, during the titration experiment, intermediate Pup species were observable, suggesting the formation of one or more transient state(s) upon binding. Moreover, Mpa selected one configuration for a region undergoing chemical exchange in the free protein. These findings provide mechanistic insights into Pup's functional role as a degradation signal.