Human APOBEC3G-Mediated Editing Can Promote HIV-1 Sequence Diversification and Accelerate Adaptation to Selective Pressure

Members of the apolipoprotein B mRNA-editing enzyme-catalytic polypeptide-like-3 (APOBEC3) innate cellular cytidine deaminase family, particularly APOBEC3F and APOBEC3G, can cause extensive and lethal G-to-A mutations in HIV-1 plusstrand DNA (termed hypermutation). It is unclear if APOBEC3-induced mutations in vivo are always lethal or can occur at sublethal levels that increase HIV-1 diversification and viral adaptation to the host. The viral accessory protein Vif counteracts APOBEC3 activity by binding to APOBEC3 and promoting proteasome degradation; however, the efficiency of this interaction varies, since a range of hypermutation frequencies are observed in HIV-1 patient DNA. Therefore, we examined "footprints" of APOBEC3G and APOBEC3F activity in longitudinal HIV-1 RNA pol sequences from approximately 3,000 chronically infected patients by determining whether G-to-A mutations occurred in motifs that were favored or disfavored by these deaminases. Gto-A mutations were more frequent in APOBEC3G-disfavored than in APOBEC3G-favored contexts. In contrast, mutations in APOBEC3F-disfavored contexts were relatively rare, whereas mutations in contexts favoring APOBEC3F (and possibly other deaminases) occurred 16% more often than average G-to-A mutations. These results were supported by analyses of >500 HIV-1 env sequences from acute/early infection. IMPORTANCECollectively, our results suggest that APOBEC3G-induced mutagenesis is lethal to HIV-1, whereas mutagenesis caused by APOBEC3F and/or other deaminases may result in sublethal mutations that might facilitate viral diversification. Therefore, Vifspecific cytotoxic T lymphocyte (CTL) responses and drugs that manipulate the interplay between Vif and APOBEC3 may have beneficial or detrimental clinical effects depending on how they affect the binding of Vif to various members of the APOBEC3 family.

Section: Figsupporting

confidence: 67%

Possible Footprints of APOBEC3F and/or Other APOBEC3 Deaminases, but Not APOBEC3G, on HIV-1 from Patients with Acute/Early and Chronic Infections

Armitage

Deforche

Welch

et al. 2014

“…It was also clear that some reverse transcripts contain just one or two mutations, arguing against the notion that APOBEC3 proteins can induce only hypermutation (76). Indeed, we and others have previously suggested that infrequent G-to-A mutations driven by APOBEC3 proteins may provide a source of beneficial viral sequence diversification upon which selective pressures can act, resulting in viral evolution (77)(78)(79)(80).…”

Section: Discussionmentioning

confidence: 89%

Suppression of HIV-1 Infection by APOBEC3 Proteins in Primary Human CD4 ⁺ T Cells Is Associated with Inhibition of Processive Reverse Transcription as Well as Excessive Cytidine Deamination

Gillick

Pollpeter

Phalora

et al. 2013

Self Cite

104

101

bThe Vif protein of human immunodeficiency virus type 1 (HIV-1) promotes viral replication by downregulation of the cell-encoded, antiviral APOBEC3 proteins. These proteins exert their suppressive effects through the inhibition of viral reverse transcription as well as the induction of cytidine deamination within nascent viral cDNA. Importantly, these two effects have not been characterized in detail in human CD4؉ T cells, leading to controversies over their possible contributions to viral inhibition in the natural cell targets of HIV-1 replication. Here we use wild-type and Vif-deficient viruses derived from the CD4 ؉ T cells of multiple donors to examine the consequences of APOBEC3 protein function at natural levels of expression. We demonstrate that APOBEC3 proteins impart a profound deficiency to reverse transcription from the initial stages of cDNA synthesis, as well as excessive cytidine deamination (hypermutation) of the DNAs that are synthesized. Experiments using viruses from transfected cells and a novel method for mapping the 3= termini of cDNAs indicate that the inhibition of reverse transcription is not limited to a few specific sites, arguing that APOBEC3 proteins impede enzymatic processivity. Detailed analyses of mutation spectra in viral cDNA strongly imply that one particular APOBEC3 protein, APOBEC3G, provides the bulk of the antiviral phenotype in CD4 ؉ T cells, with the effects of APOBEC3F and APOBEC3D being less significant. Taken together, we conclude that the dual mechanisms of action of APOBEC3 proteins combine to deliver more effective restriction of HIV-1 than either function would by itself.

“…As such, permitting sublethal mA3 mutations could help these gammaretroviruses persist in their murine host and thereby increase their chances of becoming endogenized in the mouse germ line. This concept that sublethal levels of A3-induced deamination could be a driving force behind retroviral/HIV evolution, drug resistance, and immune escape has been raised several times before (63)(64)(65)(66)(67)(68).…”

Section: Discussionmentioning

confidence: 99%

N -Linked Glycosylation Protects Gammaretroviruses against Deamination by APOBEC3 Proteins

Gerpe

Renner

Bélanger

et al. 2015

Retroviruses are pathogens with rapid infection cycles that can be a source of disease, genome instability, and tumor development in their hosts. Host intrinsic restriction factors, such as APOBEC3 (A3) proteins, are constitutively expressed and dedicated to interfering with the replication cycle of retroviruses. To survive, propagate, and persist, retroviruses must counteract these restriction factors, often by way of virus genome-encoded accessory proteins. Glycosylated Gag, also called glycosylated Pr80 Gag (gPr80), is a gammaretrovirus genome-encoded protein that inhibits the antiretroviral activity of mouse A3 (mA3). Here we show that gPr80 exerts two distinct inhibitory effects on mA3: one that antagonizes deamination-independent restriction and another one that inhibits its deaminase activity. More specifically, we find that the number of N-glycosylated residues in gPr80 inversely correlates with the sensitivity of a gammaretrovirus to deamination by mouse A3 and also, surprisingly, by human A3G. Finally, our work highlights that retroviruses which have successfully integrated into the mouse germ line generally express a gPr80 with fewer glycosylated sites than exogenous retroviruses. This observation supports the suggestion that modulation of A3 deamination intensity could be a desirable attribute for retroviruses to increase genetic diversification and avoid immune detection. Overall, we present here the first description of how gammaretroviruses employ posttranslational modification to antagonize and modulate the activity of a host genome-encoded retroviral restriction factor. IMPORTANCEAPOBEC3 proteins are host factors that have a major role in protecting humans and other mammals against retroviruses. These enzymes hinder their replication and intensely mutate their DNA, thereby inactivating viral progeny and the spread of infection. Here we describe a newly recognized way in which some retroviruses protect themselves against the mutator activity of APOBEC3 proteins. We show that gammaretroviruses expressing an accessory protein called glycosylated Gag, or gPr80, use the host's posttranslational machinery and, more specifically, N-linked glycosylation as a way to modulate their sensitivity to mutations by APOBEC3 proteins. By carefully controlling the amount of mutations caused by APOBEC3 proteins, gammaretroviruses can find a balance that helps them evolve and persist.