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Ver, HIV-1 loads appeared lower and T cell counts higher overall in patients with stable A3H proteins in comparison to those with unstable proteins, suggesting that A3H may help to control viral pathogenesis in vivo (Ooms et al., 2013). Additionally intriguing is that a significant subset of global HIV-1 isolates may have Vif proteins that are specifically hypofunctional toward A3H because a large proportion of the human population is homozygous for unstable A3H haplotypes, therefore exerting little or no selective pressure to maintain full Vif function (Refsland et al., 2014). Given the potential potency of A3-mediated HIV-1 restriction and the plethora of circulatingLY-2523355 manufacturer Author Manuscript Author Manuscript Author Manuscript Author ManuscriptVirology. Author manuscript; available in PMC 2016 May 01.Harris and DudleyPagehaplotypes, these enzymes should be further investigated as candidate factors in long-term non-progression, elite control, and overt resistance to infection. HIV-1 drug resistance studies have also provided Mangafodipir (trisodium) web valuable portals into understanding the potential impact of A3 enzymes in vivo. Several common antiretroviral drug resistance mutations are potential A3-mediated G-to-A events (Berkhout and de Ronde, 2004; Hach?et al., 2006; Jern et al., 2009; Kim et al., 2010; Kim et al., 2014; Mulder et al., 2008; Pillai et al., 2008; Sadler et al., 2010). For instance, deep-sequencing studies have revealed that drug resistance mutations are more common in HIV-1 cultures in the presence of A3G than in its absence, and that potential A3-mediated drug resistance mutations pre-exist in clinical HIV-1 populations (Kim et al., 2010; Mulder et al., 2008). In addition, adaptive immune responses exert strong selective pressures on HIV-1, and sequencing studies have shown that many putative immune escape mutants correspond to potential A3-mediated G-to-A editing sites (Kim et al., 2014). Finally, significant proportions of transmission-associated mutations also correspond to potential A3-mediated G-to-A mutation events (Wood et al., 2009). These mutations may have been required for escaping immune responses and/or adapting to differences in host factor compositions (restriction or dependence factors) during or shortly after transmission. Taken together, these studies strongly implicate A3 mutagenesis in providing HIV-1 with mutational fuel and evolutionary diversity upon which natural adaptive immune and pharmacologic pressures may act. As detailed below, many concepts in APOBEC restriction extend far beyond HIV-1 to multiple DNA parasites.Author Manuscript Author Manuscript Author Manuscript Author ManuscriptHuman APOBEC3 enzymes and HTLV-1 restrictionHTLV-1 restriction Cell culture over-expression experiments have indicated that multiple A3 enzymes can restrict the infectivity of human T-cell leukemia virus type 1 (HTLV-1) (Derse et al., 2007; Mahieux et al., 2005; Navarro et al., 2005; Ooms et al., 2012; Sasada et al., 2005; Strebel, 2005). However, in head-to-head experiments, HTLV-1 appears considerably more resistant than HIV-1 to restriction by A3D, A3F, and A3G (Derse et al., 2007; Navarro et al., 2005; Ooms et al., 2012). Only stably expressed haplotypes of A3H caused strong restriction of both viruses (Ooms et al., 2012). HTLV-1 also appeared preferentially susceptible to restriction by A3A and A3B (Ooms et al., 2012). Both deaminase-dependent and independent mechanisms have been noted (Derse et al., 2007; Mahieux et al., 2005; Navarro.Ver, HIV-1 loads appeared lower and T cell counts higher overall in patients with stable A3H proteins in comparison to those with unstable proteins, suggesting that A3H may help to control viral pathogenesis in vivo (Ooms et al., 2013). Additionally intriguing is that a significant subset of global HIV-1 isolates may have Vif proteins that are specifically hypofunctional toward A3H because a large proportion of the human population is homozygous for unstable A3H haplotypes, therefore exerting little or no selective pressure to maintain full Vif function (Refsland et al., 2014). Given the potential potency of A3-mediated HIV-1 restriction and the plethora of circulatingAuthor Manuscript Author Manuscript Author Manuscript Author ManuscriptVirology. Author manuscript; available in PMC 2016 May 01.Harris and DudleyPagehaplotypes, these enzymes should be further investigated as candidate factors in long-term non-progression, elite control, and overt resistance to infection. HIV-1 drug resistance studies have also provided valuable portals into understanding the potential impact of A3 enzymes in vivo. Several common antiretroviral drug resistance mutations are potential A3-mediated G-to-A events (Berkhout and de Ronde, 2004; Hach?et al., 2006; Jern et al., 2009; Kim et al., 2010; Kim et al., 2014; Mulder et al., 2008; Pillai et al., 2008; Sadler et al., 2010). For instance, deep-sequencing studies have revealed that drug resistance mutations are more common in HIV-1 cultures in the presence of A3G than in its absence, and that potential A3-mediated drug resistance mutations pre-exist in clinical HIV-1 populations (Kim et al., 2010; Mulder et al., 2008). In addition, adaptive immune responses exert strong selective pressures on HIV-1, and sequencing studies have shown that many putative immune escape mutants correspond to potential A3-mediated G-to-A editing sites (Kim et al., 2014). Finally, significant proportions of transmission-associated mutations also correspond to potential A3-mediated G-to-A mutation events (Wood et al., 2009). These mutations may have been required for escaping immune responses and/or adapting to differences in host factor compositions (restriction or dependence factors) during or shortly after transmission. Taken together, these studies strongly implicate A3 mutagenesis in providing HIV-1 with mutational fuel and evolutionary diversity upon which natural adaptive immune and pharmacologic pressures may act. As detailed below, many concepts in APOBEC restriction extend far beyond HIV-1 to multiple DNA parasites.Author Manuscript Author Manuscript Author Manuscript Author ManuscriptHuman APOBEC3 enzymes and HTLV-1 restrictionHTLV-1 restriction Cell culture over-expression experiments have indicated that multiple A3 enzymes can restrict the infectivity of human T-cell leukemia virus type 1 (HTLV-1) (Derse et al., 2007; Mahieux et al., 2005; Navarro et al., 2005; Ooms et al., 2012; Sasada et al., 2005; Strebel, 2005). However, in head-to-head experiments, HTLV-1 appears considerably more resistant than HIV-1 to restriction by A3D, A3F, and A3G (Derse et al., 2007; Navarro et al., 2005; Ooms et al., 2012). Only stably expressed haplotypes of A3H caused strong restriction of both viruses (Ooms et al., 2012). HTLV-1 also appeared preferentially susceptible to restriction by A3A and A3B (Ooms et al., 2012). Both deaminase-dependent and independent mechanisms have been noted (Derse et al., 2007; Mahieux et al., 2005; Navarro.

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