The N-terminal and C-terminal domains (NTD and CTD, respectively) of A3G both contain Zn coordinate motifs ((H/C)xE(x)_23-28PCxxC; Wedekind et al., 2003; Conticello et al., 2005). The A3G CTD is catalytically active, whereas its NTD has no enzymatic activity but exhibits strong binding to ssDNA and RNA (Hache et al., 2005; Navarro et al., 2005; Iwatani et al., 2006). During the reverse transcription of vif-deficient HIV-1, A3G preferentially deaminates the second dC of 5′-CC dinucleotide sites in the newly synthesized viral minus-stranded ssDNA (Harris et al., 2003; Mangeat et al., 2003; Zhang et al., 2003; Yu Q. et al., 2004). This dinucleotide preference is unique among A3 family proteins (Hultquist et al., 2011; Rathore et al., 2013). This deamination occurs more efficiently at the dC close to the 5′-end of ssDNA and less efficiently at the last ∼30 nt of the 3′ ssDNA end, the so-called dead zone (Chelico et al., 2006, 2008). Therefore, it is likely that A3G more efficiently catalyzes the deamination of ssDNA when the A3G CTD is oriented toward the 5′ ssDNA end, and the A3G NTD restricts access of the CTD to the dead zone (Chelico et al., 2010; Shlyakhtenko et al., 2015). Furthermore, the deamination efficacy decreases with decreasing ssDNA length (Chelico et al., 2006), thus probably reflecting the infrequent orientation of the A3G CTD toward the 5′ ssDNA end (Shlyakhtenko et al., 2015).

Although A3G-mediated deamination was initially proposed to be the sole mechanism of the antiviral activity against vif-deficient HIV-1, subsequent studies have demonstrated that other mechanisms are also involved in the inhibition of viral replication. In addition, the enzymatic activity of A3F is not absolutely required for its inhibitory effect on vif-deficient HIV-1 replication (Holmes et al., 2007; Luo et al., 2007; Mbisa et al., 2010). Furthermore, a deaminase activity-deficient A3G mutant blocks the replication of HIV-1, mouse mammary tumor virus, and murine leukemia virus, to a certain extent (Okeoma et al., 2007; Belanger et al., 2013), thus suggesting the broad specificity of antiviral activity in terms of the deaminase-independent mechanism.

Initially, Guo et al. (2006, 2007) suggested that A3G might interfere with tRNA^Lys3 primer placement in viral reverse transcription, in a manner independent of A3G-mediated deamination (Figure 1). However, such inhibition of primer annealing has not been observed in other studies (Iwatani et al., 2007; Bishop et al., 2008). Instead, the inhibition of HIV-1 RT elongation has been demonstrated by using in vitro and in vivo systems (Iwatani et al., 2007; Bishop et al., 2008; Adolph et al., 2013; Belanger et al., 2013) (Figure 1). It has been suggested that the inhibitory effect reflects the following unique biochemical characteristics of A3G: (1) A3G protein exhibits high affinity binding specifically to single-stranded polynucleotides, such as ssDNA and RNA (Iwatani et al., 2006; Polevoda et al., 2015); (2) A3G, compared with RT, exhibits significantly higher binding affinity for polynucleotides, although A3G shows similar or slightly less binding affinity for ssDNA than the NC (Iwatani et al., 2006; Darlix et al., 2011); (3) A3G mediates homo-oligomerization in a dose-dependent manner in the presence of ssDNA or RNA, whereas A3G forms monomers, dimers, and tetramers in the absence of these polynucleotides (Wedekind et al., 2006; Salter et al., 2009); and (4) A3G initially binds ssDNA with rapid on-off rates and subsequently converts to a slow dissociation mode after homo-oligomerization (Chaurasiya et al., 2014). Therefore, A3G probably inhibits reverse transcription by tightly binding to the ssDNA or RNA template, thus forming a roadblock that physically obstructs viral DNA synthesis (Iwatani et al., 2007; Adolph et al., 2013; Chaurasiya et al., 2014) (Figure 1). This deaminase-independent mechanism might increase the availability of ssDNA for deamination by A3G (Adolph et al., 2013; Chaurasiya et al., 2014), thereby resulting in cooperative effects between deaminase-dependent and deaminase-independent mechanisms.

A3G-mediated inhibition of plus-strand DNA transfer and integration has also been observed (Mbisa et al., 2007, 2010) (Figure 1). A3G decreases the efficiency and specificity of tRNA processing and removal during reverse transcription, thereby producing aberrant viral DNA ends defective for efficient plus-strand transfer and integration. Interestingly, it has been reported that A3F exerts an inhibitory effect on viral DNA integration, although its mechanism differs from that of A3G; A3F prevents integration by its binding to the double-stranded DNA of the proviral DNA ends (Mbisa et al., 2010). In contrast to the competition of nucleic acid interactions between A3G and RT/integrase, direct interactions of the A3G protein with HIV-1 RT (Wang et al., 2012) or integrase (Luo et al., 2007) (Figure 1) have been reported to be a deaminase-independent mechanism, although the molecular mechanism underlying the specific affinity of A3G for a variety of retroviral RTs and integrases remains unclear. This may be associated with a loss of the reverse transcription complex structure in newly infected cells when A3G coexists with RT (Carr et al., 2006).

Recent progress in determining the A3G protein structure has enhanced the current understanding of A3G-mediated antiviral mechanisms, particularly interactions between nucleotides and A3G. First, three-dimensional structures of the A3G CTD were determined by using NMR spectroscopy (Chen et al., 2008; Furukawa et al., 2009; Harjes et al., 2009) and X-ray crystallography (Holden et al., 2008; Shandilya et al., 2010; Li et al., 2012; Lu et al., 2015). Although the structure of the A3G CTD/ssDNA complex has not yet been determined experimentally, four different structural models of the ssDNA-bound A3G CTD have been proposed to explain how A3G recognizes the ssDNA substrate. The first ssDNA-bound model shows the nearly vertical orientation of ssDNA relative to helices α2 and α3 of the A3G CTD along a cleft around the Zn-coordination center (Zn-center pocket; “brim” model) (Chen et al., 2008). The second model suggests that ssDNA binds to the Zn-center pocket with the ssDNA crossed over the cleft seen in the brim model (“kinked” model; Holden et al., 2008). The third model resembles the brim model, although in this model, helices α2 and α3 are involved in ssDNA binding to a greater extent (“straight” model; Furukawa et al., 2009). The recently proposed fourth model based on the crystal structure of the A3G CTD-CTD dimer is a hybrid model of the kinked and brim models (Lu et al., 2015). Nevertheless, it remains inconclusive which ssDNA substrate-binding model is appropriate for deamination catalysis.

Structures of the highly insoluble A3G NTD protein have recently been determined by using NMR spectroscopy (Kouno et al., 2015) and X-ray crystallography (Xiao et al., 2016). The crystal structure of the A3G NTD, derived from the rhesus macaque (Macaca mulatta) protein, reveals a detailed structural mechanism illustrating A3G dimerization and the interaction between the A3G NTD and ssDNA (Xiao et al., 2016). The structural data suggest that ssDNA binding to the A3G NTD changes the conformation of the loops around the Zn-center pocket and Y124 in loop7, thus functioning as a “molecular switch” that regulates the opened/closed status of the Zn-center pocket. The structure also indicates that the dimerization interfaces of the A3G NTD dimer provide a large positively charged surface, including the Zn-center pocket, thereby resulting in the formation of a high affinity surface toward the ssDNA or RNA (Figure 2). These structural features are consistent with results of previous biochemical studies suggesting that the NTD-NTD interaction is crucial for A3G oligomerization, nucleic acid binding, and the antiviral activity of A3G (Bennett et al., 2008; Huthoff et al., 2009; Chelico et al., 2010; Shandilya et al., 2010; Belanger et al., 2013; Chaurasiya et al., 2014).