Dissecting Tn5 transposition using HIV-1 integrase diketoacid inhibitors

Diketoacid (DKA) compounds have been shown to inhibit HIV-1 integrase by a mechanism that involves sequestration of the active site metals. Because HIV-1 integrase and Tn5 transposase have similar active site architectures and catalytic mechanisms, we investigated whether DKA analogues would inhibit Tn5 transposase activity and provide a model system to explore the mechanisms of action of these inhibitors. A screen of several hundred DKA analogues identified several with activity against Tn5 Tnp. Six DKA inhibitors used in this study manifested a variety of effects on different transposition steps suggesting that different analogues may have different binding contacts with transposase. All DKA compounds inhibited paired end complex (PEC) formation in which the nucleoprotein complex required for catalysis is assembled. Dissociation of PECs by some DKA compounds indicates that these inhibitors can decrease PEC stability. Four DKA compounds inhibited the two cleavage steps releasing transposon DNA from flanking DNA, and one of these four compounds preferentially inhibited the second cleavage step. The differential effect of this inhibitor on the second cleavage event indicates that cleavage of the two transposon-donor DNA boundaries is a sequential process requiring a conformational change. The requirement for a conformational change between cleavage events was also demonstrated by the inability of transposase to perform second cleavage at 25 degrees C. Finally, all six compounds inhibit strand transfer, the final step of Tn5 transposition. Two of the compounds that inhibited strand transfer have no effect on DNA cleavage. The strand transfer inhibition properties of various DKA compounds was sensitive to the structure of the 5'-non-transferred strand, suggesting that these compounds bind in or near the transposase active site. Other results that probe compound binding sites include the effects of active site mutations and donor DNA on DKA compound inhibition activities. Thus, DKA inhibitors will provide an important set of tools to investigate the mechanism of action of transposases and integrases.     

Computational design of novel fullerene analogues as potential HIV-1 PR inhibitors: Analysis of the binding interactions between fullerene inhibitors and HIV-1 PR residues using 3D QSAR, molecular docking and molecular dynamics simulations

A series of experimentally reported as well as computationally designed monoadducts and bisadducts of [60]fullerene analogues have been used in order to analyze the binding interactions between fullerene based inhibitors and HIV-1 PR employing docking studies. MD simulations of ligand-free and the inhibitor bound HIV-1 PR systems complemented the above studies and provided proper input structure of HIV-1 PR in docking simulations. The obtained results revealed a different orientation of the beta-hairpin flaps at these two systems. In inhibitor bound system, the flaps of the enzyme are pulled in toward the bottom of the active site (the closed form) while, in ligand-free system flaps shifted away from the dual Asp25 catalytic site and this system adopts a semi-open form. The structural analysis of these systems at catalytic and flexible flap regions of the HIV-1 PR through the simulation, assisted in understanding the structural preferences of these regions, as well as, the adopted orientations of fullerene derivatives within the active site of the enzyme. Five different combinations of steroelectronic fields of 3D QSAR/CoMSIA models were obtained from the set of biologically evaluated and computationally designed fullerene derivatives (training set=43, test set=6) in order to predict novel compounds with improved inhibition effect. The best 3D QSAR/CoMSIA model yielded a cross validated r(2) value of 0.739 and a non-cross validated r(2) value of 0.993. The derived model indicated the importance of steric (42.6%), electrostatic (12.7%), H-bond donor (16.7%) and H-bond acceptor (28.0%) contributions. The derived contour plots together with de novo drug design were then used as pilot models for proposing the novel analogues with enhanced binding affinities. Such structures may trigger the interest of medicinal chemists for novel HIV-1 PR inhibitors possessing higher bioactivity.     

Molecular Interactions of a DNA Modifying Enzyme APOBEC3F Catalytic Domain with a Single-Stranded DNA

The single-stranded DNA (ssDNA) cytidine deaminase APOBEC3F (A3F) deaminates cytosine (C) to uracil (U) and is a known restriction factor of HIV-1. Its C-terminal catalytic domain (CD2) alone is capable of binding single-stranded nucleic acids and is important for deamination. However, little is known about how the CD2 interacts with ssDNA. Here we report a crystal structure of A3F-CD2 in complex with a 10-nucleotide ssDNA composed of poly-thymine, which reveals a novel positively charged nucleic acid binding site distal to the active center that plays a key role in substrate DNA binding and catalytic activity. Lysine and tyrosine residues within this binding site interact with the ssDNA, and mutating these residues dramatically impairs both ssDNA binding and catalytic activity. This binding site is not conserved in APOBEC3G (A3G), which may explain differences in ssDNA-binding characteristics between A3F-CD2 and A3G-CD2. In addition, we observed an alternative Zn-coordination conformation around the active center. These findings reveal the structural relationships between nucleic acid interactions and catalytic activity of A3F.     

Binding and structural studies of the complexes of type 1 ribosome inactivating protein from Momordica balsamina with cytosine,cytidine, and cytidine diphosphate

The type 1 ribosome inactivating protein from Momordica balsamina (MbRIP1) has been shown to interact with purine bases, adenine and guanine of RNA/DNA. We report here the binding and structural studies of MbRIP1 with a pyrimidine base, cytosine; cytosine containing nucleoside, cytidine; and cytosine containing nucleotide, cytidine diphosphate. All three compounds bound to MbRIP1 at the active site with dissociation constants of 10^?4 M–10^?7 M. As reported earlier, in the structure of native MbRIP1, there are 10 water molecules in the substrate binding site. Upon binding of cytosine to MbRIP1, four water molecules were dislodged from the substrate binding site while five water molecules were dislodged when cytidine bound to MbRIP1. Seven water molecules were dislocated when cytidine diphosphate bound to MbRIP1. This showed that cytidine diphosphate occupied a larger space in the substrate binding site enhancing the buried surface area thus making it a relatively better inhibitor of MbRIP1 as compared to cytosine and cytidine. The key residues involved in the recognition of cytosine, cytidine and cytidine diphosphate were Ile71, Glu85, Tyr111 and Arg163. The orientation of cytosine in the cleft is different from that of adenine or guanine indicating a notable difference in the modes of binding of purine and pyrimidine bases. Since adenine containing nucleosides/nucleotides are suitable substrates, the cytosine containing nucleosides/nucleotides may act as inhibitors.     

Identification of an APOBEC3G binding site in human immunodeficiency virus type 1 Vif and inhibitors of Vif-APOBEC3G binding

The APOBEC3 cytidine deaminases are potent antiviral factors that restrict replication of human immunodeficiency virus type 1 (HIV-1). HIV-1 Vif binds APOBEC3G and APOBEC3F and targets these proteins for ubiquitination by forming an E3 ubiquitin ligase with cullin 5 and elongins B and C. The N-terminal region of Vif is required for APOBEC3G binding, but the binding site(s) is unknown. To identify the APOBEC3G binding site in Vif, we established a scalable binding assay in a format compatible with development of high-throughput screens. In vitro binding assays using recombinant proteins identified Vif peptides and monoclonal antibodies that inhibit Vif-APOBEC3G binding and suggested involvement of Vif residues 33 to 83 in APOBEC3G binding. Cell-based binding assays confirmed these results and demonstrated that residues 40 to 71 in the N terminus of Vif contain a nonlinear binding site for APOBEC3G. Mutation of the highly conserved residues His42/43 but not other charged residues in this region inhibited Vif-APOBEC3G binding, Vif-mediated degradation of APOBEC3G, and viral infectivity. In contrast, mutation of these residues had no significant effect on Vif binding and degradation of APOBEC3F, suggesting a differential requirement for His42/43 in Vif binding to APOBEC3G and APOBEC3F. These results identify a nonlinear APOBEC3 binding site in the N terminus of Vif and demonstrate that peptides or antibodies directed against this region can inhibit Vif-APOBEC3G binding, validating the Vif-APOBEC3 interface as a potential drug target.     

The enzymatic activity of CEM15/Apobec-3G is essential for the regulation of the infectivity of HIV-1 virion but not a sole determinant of its antiviral activity

Human immunodeficiency virus, type 1 (HIV-1) Vif protein plays an essential role in the regulation of the infectivity of HIV-1 virion. Vif functions to counteract an anti-HIV-1 cellular factor in non-permissive cells, CEM15/Apobec-3G, which shares a cytidine deaminase motif. CEM15/Apobec-3G deaminates dC to dU in the minus strand DNA of HIV-1, resulting in G to A hypermutation in the plus strand DNA. In this study, we have done the mutagenesis analysis on two cytidine deaminase motifs in CEM15/Apobec-3G and examined their antiviral functions as well as the DNA editing activity. Point mutations in the C-terminal active site such as E259Q and C291A almost completely abrogated the antiviral function, while those in the N-terminal active site such as E67Q and C100A retained this activity to a lesser extent as compared with that of the wild type. The DNA editing activities of E67Q and E259Q mutants were both retained but impaired to the same extent. This indicates that the enzymatic activity of this protein is essential but not a sole determinant of the antiviral activity. Furthermore, all the deletion mutants tested in this study lost the antiviral activity because of the loss of the activity for dimerization, suggesting that the entire protein structure is necessary for the antiviral function.     

Structural and molecular interactions of CCR5 inhibitors with CCR5

We have characterized the structural and molecular interactions of CC-chemokine receptor 5 (CCR5) with three CCR5 inhibitors active against R5 human immunodeficiency virus type 1 (HIV-1) including the potent in vitro and in vivo CCR5 inhibitor aplaviroc (AVC). The data obtained with saturation binding assays and structural analyses delineated the key interactions responsible for the binding of CCR5 inhibitors with CCR5 and illustrated that their binding site is located in a predominantly lipophilic pocket in the interface of extracellular loops and within the upper transmembrane (TM) domain of CCR5. Mutations in the CCR5 binding sites of AVC decreased gp120 binding to CCR5 and the susceptibility to HIV-1 infection, although mutations in TM4 and TM5 that also decreased gp120 binding and HIV-1 infectivity had less effects on the binding of CC-chemokines, suggesting that CCR5 inhibition targeting appropriate regions might render the inhibition highly HIV-1-specific while preserving the CC chemokine-CCR5 interactions. The present data delineating residue by residue interactions of CCR5 with CCR5 inhibitors should not only help design more potent and more HIV-1-specific CCR5 inhibitors, but also give new insights into the dynamics of CC-chemokine-CCR5 interactions and the mechanisms of CCR5 involvement in the process of cellular entry of HIV-1.     

Identification of HIV-1 integrase inhibitors via three-dimensional database searching using ASV and HIV-1 integrases as targets

Integration of viral DNA into the host cell genome is a critical step in the life cycle of HIV. This essential reaction is catalyzed by integrase (IN) through two steps, 3'-processing and DNA strand transfer. Integrase is an attractive target for drug design because there is no known cellular analogue and integration is essential for successful replication of HIV. A computational three-dimensional (3-D) database search was used to identify novel HIV-1 integrase inhibitors. Starting from the previously identified Y3 (4-acetylamino-5-hydroxynaphthalene-2,7-disulfonic acid) binding site on the avian sarcoma virus integrase (ASV IN), a preliminary search of all compounds in the nonproprietary, open part of the National Cancer Institute 3-D database yielded a collection of 3100 compounds. A more rigorous scoring method was used to rescreen the 3100 compounds against both ASV IN and HIV-1 IN. Twenty-two of those compounds were selected for inhibition assays against HIV-1 IN. Thirteen of the 22 showed inhibitory activity against HIV-1 IN at concentrations less than 200 microM and three of them showed antiviral activities in HIV-1 infected CEM cells with effective concentrations (EC50) ranging from 0.8 to 200 microM. Analysis of the computer-generated binding modes of the active compounds to HIV-1 IN showed that simultaneous interaction with the Y3 site and the catalytic site is possible. In addition, interactions between the active compounds and the flexible loop involved in the binding of DNA by IN are indicated to occur. The structural details and the unique binding motif between the HIV-1 IN and its inhibitors identified in the present work may contribute to the future development of IN inhibitors.     

Localization of the ATP-binding site in the 23-kDa and 20-kDa regions of the heavy chain of the skeletal muscle myosin head

Three kinds of ATP analogues were synthesized. These ATP analogues can be classified into two conformations, i.e. syn and anti forms with respect to the N-glycosidic bond between adenine and ribose groups of ATP. 3'-O-(N-Methylanthraniloyl)-2-azidoadenosine 5'-triphosphate (MantN2(3)ATP) is recognized as the anti form, as ATP, and the other two, 3'-O-(N-methylanthraniloyl)-8-azidoadenosine 5'-triphosphate (MantN8(3)ATP) and 1,N6-etheno-8-azidoadenosine 5'-triphosphate (epsilon N8(3)ATP) are both syn forms. Mant and etheno groups are both fluorescent which allows detection of their binding to proteins. The photochemical binding of azido groups in ATP analogues to the myosin active site, examined in the presence and absence of ATP, showed that all the analogues bound to the site of myosin ATPase. These analogues also acted as substrates of the ATPase and were hydrolyzed in the active site, as judged by competitive inhibition of the ATPase and by their ATPase activities. Of these analogues, MantN2(3)ATP is very similar to ATP in divalent-cation dependence of its hydrolysis rate and in its ability to trap ADP in the active site with vanadate, while the other two are different from ATP in these respects. The photochemical binding sites of ATP analogues were localized by gel electrophoresis of trypsinized myosin ATPase with photocross-linked ATP analogues and/or by isolating the modified peptides. MantN2(3)ATP was found in the 23-kDa fragment which has a structure common to ATP-binding proteins, i.e. Gly-Xaa-Xaa-Gly-Xaa-Gly-Lys-Thr. Mant N8(3)ATP was found in a region of the 20-kDa fragment where actin is reported to attach.     

Nucleoside and nucleotide inactivation of R17 coat protein: evidence for a transient covalent RNA-protein bond

R17 coat protein forms a specific complex with a 21-nucleotide RNA hairpin containing the initiation site for the phage replicase gene. The RNA binding activity of the protein is inhibited by prior incubation with 5-bromouridine (BrU). The inactivation occurs with pseudo-first-order kinetics, and the inactive protein is stable to dilution. RNA binding activity of the BrU-inactivated protein is restored upon incubation with dithiothreitol. Inactivation of coat protein by N-ethylmaleimide or p-(chloromercuri)-benzenesulfonate indicates that a cysteine residue is located near the RNA binding site. Since 5-bromodeoxyuridine does not inactivate coat protein, a specific binding event appears to be required before inactivation can occur. Surprisingly, unmodified cytidine nucleotides also inactivate coat protein, with a specificity similar to the modified analogues. These results are discussed with regard to the formation of a transient covalent RNA-protein bond.     

Enantioselective synthesis of new analogues of neplanocin A

An efficient synthesis of analogues of (-)-aristeromycin (1) and (-)-neplanocin A (2) has been developed in an enantioselective and stereocontrolled manner by chemicoenzymatic strategy. The symmetric unsaturated dimethyl ester (3) was quantitatively hydrolyzed with pig liver esterase to yield a half ester (4). Decarboxylative ozonolysis followed by chemical transformation afforded versatile chiral intermediates, cyclopentylamine (7) and cyclopentenylamine (9), which were converted to carbocyclic analogues of 5-aminoimidazole-4-carboxamide riboside (16), (18), uridine (21), cytidine (23), and guanosine (25). The cytidine analogue (23) was found most active against KB cells in culture.     

Closing of the flaps of HIV-1 protease induced by substrate binding: a model of a flap closing mechanism in retroviral aspartic proteases

The active site of aspartic proteases is covered by one or more flaps, which control access to the active site and play a significant role in the binding of the substrate. An extensive conformational change of the flaps takes place upon binding of substrate to the active site. A long molecular dynamics simulation was performed on the complex consisting of a peptide (CA-p2) from a natural substrate cleavage site of the gag/pol polyprotein placed in the active site of HIV-1 protease (PR) with an open flap conformation. During the simulation, the substrate induced the closing of the flaps into the closed conformation in an asymmetrical way through a hydrophobic intermediate state cluster. The nature of the residues of HIV-1 PR identified to be important in the flap closing mechanism is conserved across known structures of retroviral aspartic proteases family. The flap closing mechanism described in HIV-1 PR is proposed to be a general model for flap closing in retroviral aspartic proteases.     

Viral RNA is required for the association of APOBEC3G with human immunodeficiency virus type 1 nucleoprotein complexes

APOBEC3G (APO3G) is a host cytidine deaminase that is incorporated into human immunodeficiency virus type 1 (HIV-1) particles. We report here that viral RNA promotes stable association of APO3G with HIV-1 nucleoprotein complexes (NPC). A target sequence located within the 5′-untranslated region of the HIV-1 RNA was identified to be necessary and sufficient for efficient APO3G packaging. Fine mapping revealed a sequence normally involved in viral genomic RNA dimerization and Gag binding to be important for APO3G packaging and association with viral NPC. Our data suggest that packaging of APO3G into HIV-1 NPC is enhanced by viral RNA.     

Probing the S1/S1' substrate binding pocket geometry of HIV-1 protease with modified aspartic acid analogues

Aspartates 25 and 125, the active site residues of HIV-1 protease, participate functionally in proteolysis by what is believed to be a general acid-general base mechanism. However, the structural role that these residues may play in the formation and maintenance of the neighboring S1/S1' substrate binding pockets remains largely unstudied. Because the active site aspartic acids are essential for catalysis, alteration of these residues to any other naturally occurring amino acid by conventional site-directed mutagenesis renders the protease inactive, and hence impossible to characterize functionally. To investigate whether Asp-25 and Asp-125 may also play a structural role that influences substrate processing, a series of active site protease mutants has been produced in a cell-free protein synthesizing system via readthrough of mRNA nonsense (UAG) codons by chemically misacylated suppressor tRNAs. The suppressor tRNAs were activated with the unnatural aspartic acid analogues erythro-beta-methylaspartic acid, threo-beta-methylaspartic acid, or beta,beta-dimethylaspartic acid. On the basis of the specific activity measurements of the mutants that were produced, the introduction of the beta-methyl moiety was found to alter protease function to varying extents depending upon its orientation. While a beta-methyl group in the erythro orientation was the least deleterious to the specific activity of the protease, a beta-methyl group in the threo orientation, present in the modified proteins containing threo-beta-methylaspartate and beta,beta-dimethylaspartate, resulted in specific activities between 0 and 45% of that of the wild type depending upon the substrate and the substituted active site position. Titration studies of pH versus specific activity and inactivation studies, using an aspartyl protease specific suicide inhibitor, demonstrated that the mutant proteases maintained bell-shaped pH profiles, as well as suicide-inhibitor susceptibilities that are characteristic of aspartyl proteases. A molecular dynamics simulation of the beta-substituted aspartates in position 25 of HIV-1 protease indicated that the threo-beta-methyl moiety may partially obstruct the adjacent S1' binding pocket, and also cause reorganization within the pocket, especially with regard to residues Val-82 and Ile-84. This finding, in conjunction with the biochemical studies, suggests that the active site aspartate residues are in proximity to the S1/S1' binding pocket and may be spatially influenced by the residues presented in these pockets upon substrate binding. It thus seems possible that the catalytic residues cooperatively interact with the residues that constitute the S1/S1' binding pockets and can be repositioned during substrate binding to orient the active site carboxylates with respect to the scissile amide bond, a process that likely affects the facility of proteolysis.     

Divergence in Dimerization and Activity of Primate APOBEC3C

The APOBEC3 (A3) family of single-stranded DNA cytidine deaminases are host restriction factors that inhibit lentiviruses, such as HIV-1, in the absence of the Vif protein that causes their degradation. Deamination of cytidine in HIV-1 (−)DNA forms uracil that causes inactivating mutations when uracil is used as a template for (+)DNA synthesis. For APOBEC3C (A3C), the chimpanzee and gorilla orthologues are more active than human A3C, and we determined that Old World Monkey A3C from rhesus macaque (rh) is not active against HIV-1. Biochemical, virological, and coevolutionary analyses combined with molecular dynamics simulations showed that the key amino acids needed to promote rhA3C antiviral activity, 44, 45, and 144, also promoted dimerization and changes to the dynamics of loop 1, near the enzyme active site. Although forced evolution of rhA3C resulted in a similar dimer interface with hominid A3C, the key amino acid contacts were different. Overall, our results determine the basis for why rhA3C is less active than human A3C and establish the amino acid network for dimerization and increased activity. Based on identification of the key amino acids determining Old World Monkey antiviral activity we predict that other Old World Monkey A3Cs did not impart anti-lentiviral activity, despite fixation of a key residue needed for hominid A3C activity. Overall, the coevolutionary analysis of the A3C dimerization interface presented also provides a basis from which to analyze dimerization interfaces of other A3 family members.     

Studies on flexibility and binding affinity of Asp25 of HIV-1 protease mutants

We have investigated and highlighted the behavior of binding residue, Asp25 by computational analysis, which play an important role in understanding docking process with drug molecule, Ritonavir (Norvir^®) and the flexibility nature of the Human Immunodeficiency Virus-1 (HIV-1) protease enzyme. It is well known that Ritonavir is a potent and a selective HIV-1 protease inhibitor. Molecular dockings were performed in order to gain insights regarding the binding mode of this inhibitor. In our analysis, we observed Ritonavir had different rank orders of scores against different mutant of this enzyme. Asp25 of the enzyme was found to be the active site for all the mutants. The results clearly suggest that Ritonavir is not able to appropriately bind at the active site of each HIV-1 protease mutant due to RMSD difference of the amino acid (Asp) at the position 25 of all mutants. These findings support the concept that 3D space of active site is a qualitative assessment for binding affinity of inhibitor with an enzyme. The investigation on the flexibility nature of Asp25 by normal mode analysis, show that binding residue posses less flexibility due to its solvation potential. The overall analysis of our study brings clarity to the binding behavior with respect to the different mutants with Ritonavir on the basis RMSD and also on the flexible nature of HIV-1 protease enzyme with respect to Asp25 position.     

Mechanism of inhibition of the retroviral protease by a Rous sarcoma virus peptide substrate representing the cleavage site between the gag p2 and p10 proteins.

The activity of the avian myeloblastosis virus (AMV) or the human immunodeficiency virus type 1 (HIV-1) protease on peptide substrates which represent cleavage sites found in the gag and gag-pol polyproteins of Rous sarcoma virus (RSV) and HIV-1 has been analyzed. Each protease efficiently processed cleavage site substrates found in their cognate polyprotein precursors. Additionally, in some instances heterologous activity was detected. The catalytic efficiency of the RSV protease on cognate substrates varied by as much as 30-fold. The least efficiently processed substrate, p2-p10, represents the cleavage site between the RSV p2 and p10 proteins. This peptide was inhibitory to the AMV as well as the HIV-1 and HIV-2 protease cleavage of other substrate peptides with Ki values in the 5-20 microM range. Molecular modeling of the RSV protease with the p2-p10 peptide docked in the substrate binding pocket and analysis of a series of single-amino acid-substituted p2-p10 peptide analogues suggested that this peptide is inhibitory because of the potential of a serine residue in the P1' position to interact with one of the catalytic aspartic acid residues. To open the binding pocket and allow rotational freedom for the serine in P1', there is a further requirement for either a glycine or a polar residue in P2' and/or a large amino acid residue in P3'. The amino acid residues in P1-P4 provide interactions for tight binding of the peptide in the substrate binding pocket.     

Distinct Determinants in HIV-1 Vif and Human APOBEC3 Proteins Are Required for the Suppression of Diverse Host Anti-Viral Proteins

Background

APOBEC3G (A3G) and related cytidine deaminases of the APOBEC3 family of proteins are potent inhibitors of many retroviruses, including HIV-1. Formation of infectious HIV-1 requires the suppression of multiple cytidine deaminases by Vif. HIV-1 Vif suppresses various APOBEC3 proteins through the common mechanism of recruiting the Cullin5-ElonginB-ElonginC E3 ubiquitin ligase to induce target protein polyubiquitination and proteasome-mediated degradation. The domains in Vif and various APOBEC3 proteins required for APOBEC3 recognition and degradation have not been fully characterized.

Methods and Findings

In the present study, we have demonstrated that the regions of APOBEC3F (A3F) that are required for its HIV-1-mediated binding and degradation are distinct from those reported for A3G. We found that the C-terminal cytidine deaminase domain (C-CDD) of A3F alone is sufficient for its interaction with HIV-1 Vif and its Vif-mediated degradation. We also observed that the domains of HIV-1 Vif that are uniquely required for its functional interaction with full-length A3F are also required for the degradation of the C-CDD of A3F; in contrast, those Vif domains that are uniquely required for functional interaction with A3G are not required for the degradation of the C-CDD of A3F. Interestingly, the HIV-1 Vif domains required for the degradation of A3F are also required for the degradation of A3C and A3DE. On the other hand, the Vif domains uniquely required for the degradation of A3G are dispensable for the degradation of cytidine deaminases A3C and A3DE.

Conclusions

Our data suggest that distinct regions of A3F and A3G are targeted by HIV-1 Vif molecules. However, HIV-1 Vif suppresses A3F, A3C, and A3DE through similar recognition determinants, which are conserved among Vif molecules from diverse HIV-1 strains. Mapping these determinants may be useful for the design of novel anti-HIV inhibitors.