HIV-1辅助蛋白Vif的结构与功能

HIV-1 Vif(viral infectivity factor)蛋白是由保守的vif基因编码的碱性蛋白质,是HIV-1病毒的辅助调节蛋白之一.研究表明Vif蛋白具有调节病毒侵入、组装、出芽和成熟等功能.此外,Vif蛋白能够特异性地与体内抗病毒因子APOBEC3G相互作用,增强病毒的感染性.因此,针对HIV-1Vif蛋白进行抑制剂设计已经成为抗HIV药物研究的热点之一.本文对HIV-1Vif蛋白的结构与功能研究的最新进展进行了综述.     

HIV-1 Vif protein mediates the degradation of APOBEC3G in fission yeast when over-expressed using codon optimization

Interaction between the HIV-1 Vif protein and the cellular host APOBEC3G protein is a promising target for inhibition of HIV-1 replication. Considering that human cells are a very complicated environment for the study of protein interactions, the goal of this study was to check whether fission yeast could be used as a model cell for studying the Vif-APOBEC3G interaction. Vif and APOBEC3G were expressed in fusion with GFP protein in the S. pombe SP223 strain. Subcellular localizations of Vif and APOBEC3G were observed with fluorescent microscopy. Codon optimization was used to over express the Vif protein in S. pombe cells. The degradation of APOBEC3G mediated by Vif was tested through expressing Vif and GFP-APOBEC3G proteins in the same cell. Western Blot analysis was used to measure the corresponding protein levels under different experimental conditions. The results showed that the Vif protein was predominantly localized in the nucleus of S.pombe cells, APOBEC3G was localized in the cytoplasm and concentrated at punctate bodies that were often in close proximity to the nucleus but were not necessarily restricted from other regions in the cytoplasm. Vif protein expression levels were increased significantly by using codon optimization and APOBEC3G was degraded when Vif was over-expressed in the same S. pombe cells. These results indicate that fission yeast is a good model for studying the interaction between the Vif and APOBEC3G proteins.     

Interruption of Vif/Elongin C interaction: In silico and experimental elucidation of the underlying molecular mechanism of benzimidazole-based APOBEC3G stabilizers

In 2014, two novel and promising benzimidazole-based APOBEC3G stabilizers MM-1 and MM-2 (MMs) were uncovered with an elusive mechanism of action. Vif-APOBEC3G axis has been recognized as a novel therapeutic target for anti HIV-1 drug development. The unexplored mechanism of MMs hindered their further development into lead compounds. To recognize their underlying mechanism we adopted an exhaustive in silico workflow by which we tested their ability to interrupt Vif complex network formation. The preliminary outcome guided us to a high likelihood of MMs interaction within Elongin C binding site, which in turn, perturbs Vif/Elongin C binding and ultimately undermines Vif action. To validate our estimation, we synthesized only MM-1 as a model to complement our study by in vitro assay for a real-time understanding. An immunoprecipitation experiment confirmed the capacity of MM-1 to interrupt Vif/Elongin C interaction. This is an integral study that lies at the interface between theoretical and experimental approaches showing the potential of molecular modelling to address issues related to drug development.     

The tyrosine kinases Fyn and Hck favor the recruitment of tyrosine-phosphorylated APOBEC3G into vif-defective HIV-1 particles

The main function of Vif is to limit the antiviral activity of APOBEC3G by counteracting its packaging into HIV-1 virions. In this work, we examine the possible functional interactions between Vif, APOBEC3G, and two Src family tyrosine kinases, Fyn and Hck, present in T lymphocytes and in monocyte-macrophages, respectively. By GST pull-down, we show that the SH3 domains of Fyn and Hck, and the corresponding full-length proteins bind Vif of HIV-1. One consequence of this interaction is a reduction in their catalytic activity. Interestingly, we also observed that APOBEC3G can be phosphorylated on tyrosine in the presence of Fyn or Hck, suggesting that both kinases may regulate APOBEC3G function. Accordingly, we demonstrate that in the presence of Fyn or Hck and in the absence of Vif, the overall level of APOBEC3G incorporated into HIV-1 particles is decreased, whereas the level of encapsidation of its phosphorylated form is significantly enhanced.     

HIV-1 and MLV Gag proteins are sufficient to recruit APOBEC3G into virus-like particles

The cytidine deaminase hAPOBEC3G is an antiviral human factor that counteracts the replication of HIV-1 in absence of the Vif protein. hAPOBEC3G is packaged into virus particles and lethally hypermutates HIV-1. In this work, we examine the mechanisms governing hAPOBEC3G packaging. By GST pull-down and co-immunoprecipitation assays, we show that hAPOBEC3G binds to HIV-1 Pr55 Gag and its NC domain and to the RT and IN domains contained in Pr160 Gag-Pol. We demonstrate that the expression of HIV-1 Gag is sufficient to induce the packaging of hAPOBEC3G into Gag particles. Gag-Pol polypeptides containing RT and IN domains, as well as HIV-1 genomic RNA, seem not to be necessary for hAPOBEC3G packaging. Lastly, we show that hAPOBEC3G and its murine ortholog are packaged into HIV-1 and MLV Gag particles. We conclude that the Gag polypeptides from distant retroviruses have conserved domains allowing the packaging of the host antiviral factor APOBEC3G.     

APOBEC3G与Vif在HIV-1感染中的作用

载脂蛋白B mRNA编辑催化多肽样（apolipoprotein B mRNA-editing catalytic polypeptide-like,APOBEC）蛋白是一组胞嘧啶脱氨基酶,具有天然的抗病毒活性,对多种病毒具有抑制作用,特别是逆转录病毒. APOBEC3蛋白能够抑制人类免疫缺陷病毒(HIV-1)的感染,其中APOBEC3G和APOBEC3F的作用最强. APOBEC3G能够通过胞嘧啶脱氨基作用和非胞嘧啶脱氨基作用抑制病毒感染. HIV-1病毒感染因子(Vif) 蛋白主要经泛素-蛋白酶体途径介导APOBEC3G降解,从而拮抗其抗病毒作用. APOBEC3G和Vif之间相互作用的研究对于寻求新的抗HIV治疗靶点具有重要意义.     

Identification of Two APOBEC3F Splice Variants Displaying HIV-1 Antiviral Activity and Contrasting Sensitivity to Vif

Approximately half of all human genes undergo alternative mRNA splicing. This process often yields homologous gene products exhibiting diverse functions. Alternative splicing of APOBEC3G (A3G) and APOBEC3F (A3F), the major host resistance factors targeted by the HIV-1 protein Vif, has not been explored. We investigated the effects of alternative splicing on A3G/A3F gene expression and antiviral activity. Three alternatively spliced A3G mRNAs and two alternatively spliced A3F mRNAs were detected in peripheral blood mononuclear cells in each of 10 uninfected, healthy donors. Expression of these splice variants was altered in different cell subsets and in response to cellular stimulation. Alternatively spliced A3G variants were insensitive to degradation by Vif but displayed no antiviral activity against HIV-1. Conversely, alternative splicing of A3F produced a 37-kDa variant lacking exon 2 (A3FΔ2) that was prominently expressed in macrophages and monocytes and was resistant to Vif-mediated degradation. Alternative splicing also produced a 24-kDa variant of A3F lacking exons 2–4 (A3FΔ2–4) that was highly sensitive to Vif. Both A3FΔ2 and A3FΔ2–4 displayed reduced cytidine deaminase activity and moderate antiviral activity. These alternatively spliced A3F gene products, particularly A3FΔ2, were incorporated into HIV virions, albeit at levels less than wild-type A3F. Thus, alternative splicing of A3F mRNA generates truncated antiviral proteins that differ sharply in their sensitivity to Vif.     

Characterization of conserved motifs in HIV-1 Vif required for APOBEC3G and APOBEC3F interaction

Apolipoprotein B mRNA-editing catalytic polypeptide-like 3G (APOBEC3G, or A3G) and related cytidine deaminases such as apolipoprotein B mRNA-editing catalytic polypeptide-like 3F (APOBEC3F, or A3F) are potent inhibitors of retroviruses. Formation of infectious human immunodeficiency virus (HIV)-1 requires suppression of multiple cytidine deaminases by Vif. HIV-1 Vif suppresses various APOBEC3 proteins through a common mechanism by recruiting Cullin5, ElonginB, and ElonginC E3 ubiquitin ligase to induce target protein polyubiquitination and proteasome-mediated degradation. Domains in Vif that mediate APOBEC3 recognition have not been fully characterized. In the present study, we identified a VxIPLx_4-5LxΦx₂YWxL motif in HIV-1 Vif, which is required for efficient interaction between Vif and A3G, Vif-mediated A3G degradation and virion exclusion, and functional suppression of the A3G antiviral activity. Amino acids 52 to 72 of HIV-1 Vif (including the VxIPLx_4-5LxΦx₂YWxL motif) alone could mediate interaction with A3G, and this interaction was abolished by mutations of two hydrophobic amino acids in this region. We have also observed that a Vif mutant was ineffective against A3G, yet it retained the ability to interact with Cullin5-E3 ubiquitin complex and A3G, suggesting that interaction with A3G is necessary but not sufficient to inhibit its antiviral function. Unlike the previously identified motif of HIV-1 Vif amino acids 40 to 44, which is only important for A3G suppression, the VxIPLx_4-5LxΦx₂YWxL motif is also required for efficient A3F interaction and suppression. On the other hand, another motif, TGERxW, of HIV-1 Vif amino acids 74 to 79 was found to be mainly important for A3F interaction and inhibition. Both the VxIPLx_4-5LxΦx₂YWxL and TGERxW motifs are highly conserved among HIV-1, HIV-2, and various simian immunodeficiency virus Vif proteins. Our data suggest that primate lentiviral Vif molecules recognize their autologous APOBEC3 proteins through conserved structural features that represent attractive targets for the development of novel inhibitors.     

Signals in APOBEC3F N-terminal and C-terminal deaminase domains each contribute to encapsidation in HIV-1 virions and are both required for HIV-1 restriction

Human cytidine deaminases APOBEC3F (A3F) and APOBEC3G (A3G) inhibit human immunodeficiency virus type-1 (HIV-1) replication. In the absence of HIV-1 Vif, A3F and/or A3G are incorporated into assembling virions and exert antiviral functions in subsequently infected target cells. Encapsidation of A3F or A3G within the protease-matured virion core following their incorporation into virions is hypothesized to be important for the antiviral function of these proteins. In this report, we demonstrated that A3F was quantitatively encapsidated in the mature virion core. In distinct contrast, A3G was distributed both within and outside of the virion core. Analysis of a series of A3F-A3G chimeras comprised of exchanged N- and C-terminal deaminase domains identified a 14 amino acid segment in the A3F C-terminal deaminase domain that contributed to preferential encapsidation and anti-HIV activity. Amino acid residue L306 in this C-terminal segment was determined to be necessary, but not sufficient, for these effects. Amino acid residue W126 in the N-terminal deaminase domain was determined also to contribute to preferential encapsidation and antiviral activity of A3F. Analysis of the A3F (W126A L306A) double mutant revealed that both residues are required for full anti-HIV function. The results reported here advance our understanding of the mechanisms of A3F virion encapsidation and antiviral function and may lead to innovative strategies to inhibit HIV-1 replication.     

Differential Anti-APOBEC3G Activity of HIV-1 Vif Proteins Derived from Different Subtypes

Antiretroviral cytidine deaminase APOBEC3G, which is abundantly expressed in peripheral blood lymphocytes and macrophages, strongly protects these cells against HIV-1 infection. The HIV-1 Vif protein overcomes this antiviral effect by enhancing proteasome-mediated APOBEC3G degradation and is key for maintaining viral infectivity. The 579-bp-long vif gene displays high genetic diversity among HIV-1 subtypes. Therefore, it is intriguing to address whether Vif proteins derived from different subtypes differ in their viral defense activity against APOBEC3G. Expression plasmids encoding Vif proteins derived from subtypes A, B, C, CRF01_AE, and CRF02_AG isolates were created, and their anti-APOBEC3G activities were compared. Viruses produced from cells expressing APOBEC3G and Vif proteins from different subtypes showed relatively different viral infectivities. Notably, subtype C-derived Vif proteins tested had the highest activity against APOBEC3G that was ascribed to its increased binding activity, for which the N-terminal domain of the Vif protein sequences was responsible. These results suggest that the biological differences of Vif proteins belonging to different subtypes might affect viral fitness and quasispecies in vivo.     

Single-stranded RNA facilitates nucleocapsid: APOBEC3G complex formation

Binding of APOBEC3G to the nucleocapsid (NC) domain of the human immunodeficiency virus (HIV) Gag polyprotein may represent a critical early step in the selective packaging of this antiretroviral factor into HIV virions. Previously, we and others have reported that this interaction is mediated by RNA. Here, we demonstrate that RNA binding by APOBEC3G is key for initiation of APOBEC3G:NC complex formation in vitro. By adding back nucleic acids to purified, RNase-treated APOBEC3G and NC protein preparations in vitro, we demonstrate that complex formation is rescued by short (> or =10 nucleotides) single-stranded RNAs (ssRNAs) containing G residues. In contrast, complex formation is not induced by add-back of short ssRNAs lacking G, by dsRNAs, by ssDNAs, by dsDNAs or by DNA:RNA hybrid molecules. While some highly structured RNA molecules, i.e., tRNAs and rRNAs, failed to rescue APOBEC3G:NC complex formation, other structured RNAs, i.e., human Y RNAs and 7SL RNA, did promote NC binding by APOBEC3G. Together, these results indicate that ternary complex formation requires ssRNA, but suggest this can be presented in the context of an otherwise highly structured RNA molecule. Given previous data arguing that APOBEC3G binds, and edits, ssDNA effectively in vitro, these data may also suggest that APOBEC3G can exist in two different conformational states, with different activities, depending on whether it is bound to ssRNA or ssDNA.     

Structural perspectives on HIV‐1 Vif and APOBEC3 restriction factor interactions

Human immunodeficiency virus (HIV) is a retroviral pathogen that targets human immune cells such as CD4⁺ T cells, macrophages, and dendritic cells. The human apo lipoprotein B mRNA‐ e diting c atalytic polypeptide 3 (APOBEC3 or A3) cytidine deaminases are a key class of intrinsic restriction factors that inhibit replication of HIV. When HIV‐1 enters the cell, the immune system responds by inducing the activation of the A3 family proteins, which convert cytosines to uracils in single‐stranded DNA replication intermediates, neutralizing the virus. HIV counteracts this intrinsic immune response by encoding a protein termed viral infectivity factor (Vif). Vif targets A3 to an E3 ubiquitin ligase complex for poly‐ubiquitination and proteasomal degradation. Vif is unique in that it can recognize and counteract multiple A3 restriction factor substrates. Structural biology studies have provided significant insights into the overall architectures and functions of Vif and A3 proteins; however, a structure of the Vif‐A3 complex has remained elusive. In this review, we summarize and reanalyze experimental data from recent structural, biochemical, and functional studies to provide key perspectives on the residues involved in Vif‐A3 protein–protein interactions.     

A single amino acid in human APOBEC3F alters susceptibility to HIV-1 Vif

Human APOBEC3F (huA3F) potently restricts the infectivity of HIV-1 in the absence of the viral accessory protein virion infectivity factor (Vif). Vif functions to preserve viral infectivity by triggering the degradation of huA3F but not rhesus macaque A3F (rhA3F). Here, we use a combination of deletions, chimeras, and systematic mutagenesis between huA3F and rhA3F to identify Glu(324) as a critical determinant of huA3F susceptibility to HIV-1 Vif-mediated degradation. A structural model of the C-terminal deaminase domain of huA3F indicates that Glu(324) is a surface residue within the α4 helix adjacent to residues corresponding to other known Vif susceptibility determinants in APOBEC3G and APOBEC3H. This structural clustering suggests that Vif may bind a conserved surface present in multiple APOBEC3 proteins.     

Structure,interaction and real‐time monitoring of the enzymatic reaction of wild‐type APOBEC3G

Human APOBEC3G exhibits anti‐human immunodeficiency virus‐1 (HIV‐1) activity by deaminating cytidines of the minus strand of HIV‐1. Here, we report a solution structure of the C‐terminal deaminase domain of wild‐type APOBEC3G. The interaction with DNA was examined. Many differences in the interaction were found between the wild type and recently studied mutant APOBEC3Gs. The position of the substrate cytidine, together with that of a DNA chain, in the complex, was deduced. Interestingly, the deamination reaction of APOBEC3G was successfully monitored using NMR signals in real time. Real‐time monitoring has revealed that the third cytidine of the d(CCCA) segment is deaminated at an early stage and that then the second one is deaminated at a late stage, the first one not being deaminated at all. This indicates that the deamination is carried out in a strict 3′ → 5′ order. Virus infectivity factor (Vif) of HIV‐1 counteracts the anti‐HIV‐1 activity of APOBEC3G. The structure of the N‐terminal domain of APOBEC3G, with which Vif interacts, was constructed with homology modelling. The structure implies the mechanism of species‐specific sensitivity of APOBEC3G to Vif action.     

HIV-1 Vif protein binds the editing enzyme APOBEC3G and induces its degradation

The viral infectivity factor (Vif) encoded by HIV-1 neutralizes a potent antiviral pathway that occurs in human T lymphocytes and several leukemic T-cell lines termed nonpermissive, but not in other cells termed permissive. In the absence of Vif, this antiviral pathway efficiently inactivates HIV-1. It was recently reported that APOBEC3G (also known as CEM-15), a cytidine deaminase nucleic acid-editing enzyme, confers this antiviral phenotype on permissive cells. Here we describe evidence that Vif binds APOBEC3G and induces its rapid degradation, thus eliminating it from cells and preventing its incorporation into HIV-1 virions. Studies of Vif mutants imply that it contains two domains, one that binds APOBEC3G and another with a conserved SLQ(Y/F)LA motif that mediates APOBEC3G degradation by a proteasome-dependent pathway. These results provide promising approaches for drug discovery.     

Evolutionarily conserved pressure for the existence of distinct G2/M cell cycle arrest and A3H inactivation functions in HIV-1 Vif

HIV-1 Vif assembles the Cul5-EloB/C E3 ubiquitin ligase to induce proteasomal degradation of the cellular antiviral APOBEC3 proteins. Detailed structural studies have confirmed critical functional domains in Vif that we have previously identified as important for the interaction of EloB/C, Cul5, and CBFβ. However, the mechanism by which Vif recognizes substrates remains poorly understood. Specific regions of Vif have been identified as being responsible for binding and depleting APOBEC3G and APOBEC3F. Interestingly, we have now identified distinct yet overlapping domains that are required for HIV-1 Vif-mediated G2/M-phase cell cycle arrest and APOBEC3H degradation, but not for the inactivation of APOBEC3G or APOBEC3F. Surprisingly, Vif molecules from primary HIV-1 variants that caused G2/M arrest were unable to inactivate APOBEC3H; on the other hand, HIV-1 Vif variants that could inactivate APOBEC3H were unable to induce G2/M arrest. All of these Vif variants still maintained the ability to inactivate APOBEC3G/F. Thus, primary HIV-1 variants have evolved to possess distinct functional activities that allow them to suppress APOBEC3H or cause G2 cell cycle arrest, using mutually exclusive interface domains. APOBEC3H depletion and G2 arrest are apparently evolutionary selected features that cannot co-exist on a single Vif molecule. The existence and persistence of both types of HIV-1 Vif variant suggests the importance of APOBEC3H suppression and cell cycle regulation for HIV-1''s survival in vivo.