The HIV-1 Vpu protein: a multifunctional enhancer of viral particle release

HIV accessory genes are expressed throughout the viral life cycle and regulate wide-ranging aspects of virus replication including viral infectivity (Vif and Nef), viral gene expression (Vpr) and progeny virion production (Vpu). While in many cases the molecular basis of accessory protein function is not fully understood, a consensus is emerging that these viral products are generally devoid of enzymatic activity and instead act as multifunctional adapters, subverting normal cellular processes to serve the needs of the virus. This review focuses on presenting our current knowledge of the HIV-1-specific Vpu protein and its essential role in regulating viral particle release, viral load and expression of the CD4 receptor.     

The interferon-induced protein BST-2 restricts HIV-1 release and is downregulated from the cell surface by the viral Vpu protein

The HIV-1 accessory protein Vpu counteracts a host factor that restricts virion release from infected cells. Here we show that the interferon-induced cellular protein BST-2/HM1.24/CD317 is such a factor. BST-2 is downregulated from the cell surface by Vpu, and BST-2 is specifically expressed in cells that support the vpu phenotype. Exogenous expression of BST-2 inhibits HIV-1 virion release, while suppression of BST-2 relieves the requirement for Vpu. Downregulation of BST-2 requires both the transmembrane/ion channel domain and conserved serines in the cytoplasmic domain of Vpu. Endogenous BST-2 colocalizes with the HIV-1 structural protein Gag in endosomes and at the plasma membrane, suggesting that BST-2 traps virions within and on infected cells. The unusual structure of BST-2, which includes a transmembrane domain and a lumenal GPI anchor, may allow it to retain nascent enveloped virions on cellular membranes, providing a mechanism of viral restriction counteracted by a specific viral accessory protein.     

HIV-1 Vpu promotes release and prevents endocytosis of nascent retrovirus particles from the plasma membrane

The human immunodeficiency virus (HIV) type-1 viral protein U (Vpu) protein enhances the release of diverse retroviruses from human, but not monkey, cells and is thought to do so by ablating a dominant restriction to particle release. Here, we determined how Vpu expression affects the subcellular distribution of HIV-1 and murine leukemia virus (MLV) Gag proteins in human cells where Vpu is, or is not, required for efficient particle release. In HeLa cells, where Vpu enhances HIV-1 and MLV release approximately 10-fold, concentrations of HIV-1 Gag and MLV Gag fused to cyan fluorescent protein (CFP) were initially detected at the plasma membrane, but then accumulated over time in early and late endosomes. Endosomal accumulation of Gag-CFP was prevented by Vpu expression and, importantly, inhibition of plasma membrane to early endosome transport by dominant negative mutants of Rab5a, dynamin, and EPS-15. Additionally, accumulation of both HIV and MLV Gag in endosomes required a functional late-budding domain. In human HOS cells, where HIV-1 and MLV release was efficient even in the absence of Vpu, Gag proteins were localized predominantly at the plasma membrane, irrespective of Vpu expression or manipulation of endocytic transport. While these data indicated that Vpu inhibits nascent virion endocytosis, Vpu did not affect transferrin endocytosis. Moreover, inhibition of endocytosis did not restore Vpu-defective HIV-1 release in HeLa cells, but instead resulted in accumulation of mature virions that could be released from the cell surface by protease treatment. Thus, these findings suggest that a specific activity that is present in HeLa cells, but not in HOS cells, and is counteracted by Vpu, traps assembled retrovirus particles at the cell surface. This entrapment leads to subsequent endocytosis by a Rab5a- and clathrin-dependent mechanism and intracellular sequestration of virions in endosomes.     

Structure-function correlates of Vpu,a membrane protein of HIV-1

Vpu, a membrane protein from human immunodeficiency virus-1, folds into two distinct structural domains with different biological activities: a transmembrane (TM) helical domain involved in the budding of new virions from infected cells, and a cytoplasmic domain encompassing two amphipathic helices, which is implicated in CD4 degradation. The molecular mechanism by which Vpu facilitates virion budding is not clear. This activity of Vpu requires an intact TM helical domain. And it is known that oligomerization of the VPU TM domain results in the formation of sequence-specific, cation-selective channels. It has been shown that the channel activity of Vpu is confined to the TM domain, and that the cytoplasmic helices regulate the lifetime of the Vpu channel in the conductive state. Structure-function correlates based on the convergence of information about the channel activity of Vpu reconstituted in lipid bilayers and on its 3-D structure in membranes by a combination of solution and solid-state nuclear magnetic resonance spectroscopy may provide valuable insights to understand the role of Vpu in the pathogenesis of AIDS and for drug design aimed to block channel activity.     

Towards a mechanism of function of the viral ion channel Vpu from HIV-1

Vpu, an integral membrane protein encoded in HIV-1, is implicated in the release of new virus particles from infected cells, presumably mediated by ion channel activity of homo-oligomeric Vpu bundles. Reconstitution of both full length Vpu(1-81) and a short, the transmembrane (TM) domain comprising peptide Vpu(1-32) into bilayers under a constant electric field results in an asymmetric orientation of those channels. For both cases, channel activity with similar kinetics is observed. Channels can open and remain open within a broad series of conductance states even if a small or no electric potential is applied. The mean open time for Vpu peptide channels is voltage-independent. The rate of channel opening shows a biphasic voltage activation, implicating that the gating is influenced by the interaction of the dipole moments of the TM helices with an electric field.     

An interferon-alpha-induced tethering mechanism inhibits HIV-1 and Ebola virus particle release but is counteracted by the HIV-1 Vpu protein

Type 1 interferon (IFN) inhibits the release of HIV-1 virus particles via poorly defined mechanisms. Here, we show that IFNalpha induces retention of viral particles on the surface of fibroblasts, T cells, or primary lymphocytes infected with HIV-1 lacking the Vpu protein. Retained particles are tethered to cell surfaces, can be endocytosed, appear fully assembled, exhibit mature morphology, and can be detached by protease. Strikingly, expression of the HIV-1 Vpu protein attenuates the ability of human cells to adhere to, and thereby retain, nascent HIV-1 particles upon IFNalpha treatment. Vpu also counteracts the IFNalpha-induced retention of virus-like particles assembled from the Ebola virus matrix protein. Furthermore, levels of IFNalpha that suppress replication of Vpu-defective HIV-1 have little effect on wild-type HIV-1. Thus, we propose that HIV-1 expresses Vpu to counteract an IFNalpha-induced, general host defense that inhibits dissemination of enveloped virions from the surface of infected cells.     

Insights into the oligomeric structure of the HIV-1 Vpu protein

The HIV-1-encoded protein Vpu forms an oligomeric ion channel/pore in membranes and interacts with host proteins to support the virus lifecycle. However, Vpu molecular mechanisms are currently not well understood. Here, we report on the Vpu oligomeric organization under membrane and aqueous conditions and provide insights into how the Vpu environment affects the oligomer formation. For these studies, we designed a maltose-binding protein (MBP)-Vpu chimera protein and produced it in E. coli in soluble form. We analyzed this protein using analytical size-exclusion chromatography (SEC), negative staining electron microscopy (nsEM), and electron paramagnetic resonance (EPR) spectroscopy. Surprisingly, we found that MBP-Vpu formed stable oligomers in solution, seemingly driven by Vpu transmembrane domain self-association. A coarse modeling of nsEM data as well as SEC and EPR data suggests that these oligomers most likely are pentamers, similar to what was reported regarding membrane-bound Vpu. We also noticed reduced MBP-Vpu oligomer stability upon reconstitution of the protein in β-DDM detergent and mixtures of lyso-PC/PG or DHPC/DHPG. In these cases, we observed greater oligomer heterogeneity, with MBP-Vpu oligomeric order generally lower than in solution; however, larger oligomers were also present. Notably, we found that in lyso-PC/PG, above a certain protein concentration, MBP-Vpu assembles into extended structures, which had not been reported for Vpu. Therefore, we captured various Vpu oligomeric forms, which can shed light on Vpu quaternary organization. Our findings could be useful in understanding Vpu organization and function in cellular membranes and could provide information regarding the biophysical properties of single-pass transmembrane proteins.     

HIV-1 viral cores enter the nucleus collectively through the nuclear endocytosis-like pathway

It is recognized that HIV-1 capsid cores are disassembled in the cytoplasm, releasing their genomes into the nucleus through nuclear pores, but there is also evidence showing the capsid(CA) exists in the nucleus. Whether HIV-1 enters the nucleus and how it enters the nucleus through the undersized nuclear pore remains mysterious. Based on multicolor labeling and real-time imaging of the viral and cellular components, our observations via light and electron microscopy suggest that HIV-1 selectively gathered at the microtubule organization center(MTOC), leading the nearby nuclear envelope(NE) to undergo deformation,invagination and restoration to form a nuclear vesicle in which the viral particles were wrapped; then, the inner membrane of the nuclear vesicle ruptured to release HIV-1 into the nucleus. This unexpected discovery expands our understanding of the complexity of HIV-1 nuclear entry, which may provide new insights to HIV-1 virology.     

Inhibition of HIV-1 maturation via drug association with the viral Gag protein in immature HIV-1 particles

The small molecule 3-O-(3',3'-dimethylsuccinyl)-betulinic acid (DSB) potently inhibits human immunodeficiency virus, type 1 (HIV-1) replication by interfering with proteolytic cleavage of the viral Gag protein at a specific site. Here we have demonstrated that the antiviral mechanism involves the association of DSB with Gag at a 1:1 stoichiometry within immature HIV-1 particles. The binding was specific, as mutations in Gag that confer resistance to DSB inhibited the association, which could be competed by DSB but not by the inactive compound betulinic acid. The addition of DSB to purified immature viral cores inhibited the cleavage of Gag at the CA-SP1 junction in vitro, thus reproducing the effect of the drug when present during maturation of HIV-1 particles. Based on these findings, we propose a model in which a trimer of DSB associates with the CA-SP1 junction of adjacent subunits within the Gag polymer. The model may explain the ability of highly similar compounds to specifically target the seemingly unrelated steps of HIV-1 maturation and virus entry.     

Role of HIV-1 Vpu protein for virus spread and pathogenesis

Vpu is an accessory viral protein almost unique to HIV-1 among primate immunodeficiency viruses, and has two major functions: degradation of the CD4 molecule in endoplasmic reticulum and enhancement of virion release from cells. Recent identification of a novel host restriction factor, tetherin, as a Vpu-antagonist suggests that Vpu contributes to virus spread by facilitating progeny virion production. This review focuses on the two distinct functions of Vpu and summarizes current knowledge on its virological role in the HIV-1 life cycle.     

HIV-1 Vpu: putting a channel to the TASK

Vpu is an HIV-encoded protein that enhances virus release. Previously, this activity was correlated with an intrinsic ion channel activity of Vpu. In this issue of Molecular Cell, Hsu at all. propose an alternative mechanism: they suggest that Vpu functions by inhibiting another ion channel, TASK-1.     

Involvement of the betaTrCP in the ubiquitination and stability of the HIV-1 Vpu protein

The human immunodeficiency virus type 1 (HIV-1) Vpu protein binds to the CD4 receptor and targets it to the proteasome for degradation. This process requires the recruitment of human betaTrCP, a component of the Skp1-Cullin-F box (SCF) ubiquitin ligase complex, that interacts with phosphorylated Vpu molecules. Vpu, unlike other ligands of betaTrCP, has never been reported to be degraded. We provide evidence that Vpu, itself, is ubiquitinated and targeted for degradation by the proteasome. We demonstrate that the mutant Vpu2.6, which cannot interact with betaTrCP, is stable and, unlike wild-type Vpu, is not polyubiquitinated. These results suggest that betaTrCP is involved in Vpu polyubiquitination.     

Identification of calcium-modulating cyclophilin ligand as a human host restriction to HIV-1 release overcome by Vpu

The HIV-1 Vpu protein is required for efficient viral release from human cells. For HIV-2, the envelope (Env) protein replaces the role of Vpu. Both Vpu and HIV-2 Env enhance virus release by counteracting an innate host-cell block within human cells that is absent in African green monkey (AGM) cells. Here we identify calcium-modulating cyclophilin ligand (CAML) as a Vpu-interacting host factor that restricts HIV-1 release. Expression of human CAML (encoded by CAMLG) in AGM cells conferred a strong restriction of virus release that was reversed by Vpu and HIV-2 Env, suggesting that CAML is the mechanistic link between these two viral regulators. Depletion of CAML in human cells eliminated the need for Vpu in enhancing HIV-1 and murine leukemia virus release. These results point to CAML as a Vpu-sensitive host restriction factor that inhibits HIV release from human cells. The ability of CAML to inhibit virus release should illuminate new therapeutic strategies against HIV.     

Cell surface CD4 inhibits HIV-1 particle release by interfering with Vpu activity

One of the hallmarks of human immunodeficiency virus type I (HIV-1) infection is the rapid removal of the viral receptor CD4 from the cell surface. This remarkably efficient receptor interference requires the activity of three separate viral proteins: Env, Vpu, and Nef. We have investigated whether this unusually tight interference on cell surface CD4 expression had a more essential function during the viral life cycle than simply preventing superinfection. We now report that the removal of cell surface CD4 is required for optimal virus production by HIV-1. Indeed, maintenance of CD4 surface expression in infected cells lead to a 3-5-fold decrease in viral particle production. This effect was not due to the formation of intracellular complexes between CD4 and the gp160 viral envelope precursor but instead required the presence of CD4 at the cell surface and was specifically mediated by CD4 but not closely related plasma membrane receptors. The finding that CD4 had no significant effect on particle release by a Vpu-deficient variant indicates that CD4 acts by inhibiting the particle release-promoting activity of Vpu. Co-immunoprecipitation experiments further showed that CD4 and Vpu physically interact at the cell surface, suggesting that CD4 might inhibit Vpu activity by disrupting its oligomeric structure.     

NMR studies of the phosphorylation motif of the HIV-1 protein Vpu bound to the F-box protein beta-TrCP

A protein-protein association regulated by phosphorylation of serine is examined by NMR studies. Degradation of the HIV receptor CD4 by the proteasome, mediated by the HIV-1 protein Vpu, is crucial for the release of fully infectious virions. Phosphorylation of Vpu at two sites, Ser52 and Ser56, on the motif DSGXXS is required for the interaction of Vpu with the ubiquitin ligase SCF-betaTrCP which triggers CD4 degradation by the proteasome. This motif is conserved in several signaling proteins known to be degraded by the proteasome. To elucidate the basis of beta-TrCP recognition, the bound conformation of the P-Vpu(41-62) peptide was determined by using NMR and MD. The TRNOE intensities provided distance constraints which were used in simulated annealing. The beta-TrCP-bound structure of P-Vpu was found to be similar to the structure of the free peptide in solution and to the structure recognized by its antibody. Residues 50-57 formed a bend while the phosphate groups are pointing away. The binding fragment was studied by STD-NMR spectroscopy. The phosphorylated motif DpS(52)GNEpS(56) was found to make intimate contact with beta-TrCP, and pSer52 displays the strongest binding effect. It is suggested that Ser phosphorylation allows protein-protein association by electrostatic stabilization: an obvious negative binding region of Vpu was recognizable by positive residues (Arg and Lys) of the WD domain of beta-TrCP. The Ile46 residue was also found essential for interaction with the beta-TrCP protein. Leu45 and Ile46 side chains lie in close proximity to a hydrophobic pocket of the WD domain.     

Bacteria-Based Analysis of HIV-1 Vpu Channel Activity

HIV-1 Vpu is a small, single-span membrane protein with two attributed functions that increase the virus'' pathogenicity: degradation of CD4 and inactivation of BST-2. Vpu has also been shown to posses ion channel activity, yet no correlation has been found between this attribute and Vpu''s role in viral release. In order to gain further insight into the channel activity of Vpu we devised two bacteria-based assays that can examine this function in detail. In the first assay Vpu was over-expressed, such that it was deleterious to bacterial growth due to membrane permeabilization. In the second and more sensitive assay, the channel was expressed at low levels in K⁺ transport deficient bacteria. Consequently, Vpu expression enabled the bacteria to grow at otherwise non permissive low K⁺ concentrations. Hence, Vpu had the opposite impact on bacterial growth in the two assays: detrimental in the former and beneficial in the latter. Furthermore, we show that channel blockers also behave reciprocally in the two assays, promoting growth in the first assay and hindering it in the second assay. Taken together, we investigated Vpu''s channel activity in a rapid and quantitative approach that is amenable to high-throughput screening, in search of novel blockers.     

Rhesus monkey TRIM5alpha restricts HIV-1 production through rapid degradation of viral Gag polyproteins

Mammalian cells have developed diverse strategies to restrict retroviral infection. Retroviruses have therefore evolved to counteract such restriction factors, in order to colonize their hosts. Tripartite motif-containing 5 isoform-alpha (TRIM5alpha) protein from rhesus monkey (TRIM5alpharh) restricts human immunodeficiency virus type 1 (HIV-1) infection at a postentry, preintegration stage in the viral life cycle, by recognizing the incoming capsid and promoting its premature disassembly. TRIM5alpha comprises an RBCC (RING, B-box 2 and coiled-coil motifs) domain and a B30.2(SPRY) domain. Sequences in the B30.2(SPRY) domain dictate the potency and specificity of the restriction. As TRIM5alpharh targets incoming mature HIV-1 capsid, but not precursor Gag, it was assumed that TRIM5alpharh did not affect HIV-1 production. Here we provide evidence that TRIM5alpharh, but not its human ortholog (TRIM5alphahu), blocks HIV-1 production through rapid degradation of HIV-1 Gag polyproteins. The specificity for this restriction is determined by sequences in the RBCC domain. Our observations suggest that TRIM5alpharh interacts with HIV-1 Gag during or before Gag assembly through a mechanism distinct from the well-characterized postentry restriction. This finding demonstrates a cellular factor blocking HIV-1 production by actively degrading a viral protein. Further understanding of this previously unknown restriction mechanism may reveal new targets for future anti-HIV-1 therapy.     

Inhibition of SIRT1 by HIV-1 viral protein Tat results in activation of p53 pathway

Human immunodeficiency virus-1 (HIV-1) disease is characterized by a relentless decline in CD4(+) T cells, resulting in the development of AIDS. Extracellular Tat secreted from the HIV-1 infected cells, enters non-infected T cells to induce apoptosis. A number of mechanisms, none of which is mutually exclusive, have been attributed to the cell depletion property of Tat protein. In the present communication, we provide evidence that the cell-killing effect of Tat is mediated by the activation of p53 pathway via inhibition of SIRT1, an NAD(+)-dependent deacetylase belonging to class III histone deacetylases. This evidence is based on the following experimental facts reported herein: (1) Overexpression of Tat protein decreases both the deacetylase and promoter activity of SIRT1, (2) SIRT1 inhibition by Tat involves increased levels of acetylated p53 and (3) The activation of p53 leads to subsequent increases in the expression of p53 target genes, p21 and BAX.     

NMR studies for identifying phosphopeptide ligands of the HIV-1 protein Vpu binding to the F-box protein beta-TrCP

The human immunodeficiency virus type 1 (HIV-1) Vpu enhances viral particle release and, its interaction with the ubiquitin ligase SCF-beta-TrCP triggers the HIV-1 receptor CD4 degradation by the proteasome. The interaction between beta-TrCP protein and ligands containing the phosphorylated DpSGXXpS motif plays a key role for the development of severe disease states, such as HIV or cancer. This study examines the binding and conformation of phosphopeptides (P1, LIERAEDpSG and P2, EDpSGNEpSE) from HIV protein Vpu to beta-TrCP with the objective of defining the minimum length of peptide needed for effective binding. The screening step can be analyzed by NMR spectroscopy, in particular, saturation transfer NMR methods clearly identify the residues in the peptide that make direct contact with beta-TrCP protein when bound. An analysis of saturation transfer difference (STD) spectra provided clear evidence that the two peptides efficiently bound beta-TrCP receptor protein. To better characterize the ligand-protein interaction, the bound conformation of the phosphorylated peptides was determined using transferred NOESY methods, which gave rise to a well-defined structure. P1 and P2 can fold in a bend arrangement for the DpSG motif, showing the protons identified by STD-NMR as exposed in close proximity at the molecule surface. Ser phosphorylation allows electrostatic interaction and hydrogen bond with the amino acids of the beta-TrCP binding pocket. The upstream LIER hydrophobic region was also essential in binding to a hydrophobic pocket of the beta-TrCP WD domain. These findings are in good agreement with a recently published X-ray structure of a shorter beta-Catenin fragment with the beta-TrCP complex.     

Biophysical characterization of Vpu from HIV-1 suggests a channel-pore dualism

Vpu from HIV-1 is an 81 amino acid type I integral membrane protein which consists of a cytoplasmic and a transmembrane (TM) domain. The TM domain is known to alter membrane permeability for ions and substrates when inserted into artificial membranes. Peptides corresponding to the TM domain of Vpu (Vpu(1-32)) and mutant peptides (Vpu(1-32)-W23L, Vpu(1-32)-R31V, Vpu(1-32)-S24L) have been synthesized and reconstituted into artificial lipid bilayers. All peptides show channel activity with a main conductance level of around 20 pS. Vpu(1-32)-W23L has a considerable flickering pattern in the recordings and longer open times than Vpu(1-32). Whilst recordings for Vpu(1-32)-R31V are almost indistinguishable from those of the WT peptide, recordings for Vpu(1-32)-S24L do not exhibit any noticeable channel activity. Recordings of WT peptide and Vpu(1-32)-W23L indicate Michaelis-Menten behavior when the salt concentration is increased. Both peptide channels follow the Eisenman series I, indicative for a weak ion channel with almost pore like characteristics.