The human immunodeficiency virus type 1 Vpu protein specifically binds to the cytoplasmic domain of CD4: implications for the mechanism of degradation.

We have recently demonstrated that coexpression of Vpu and CD4 in HeLa cells results in the degradation of CD4 in the endoplasmic reticulum. The sensitivity of CD4 to Vpu-mediated degradation is conferred by the presence of specific sequences located between amino acids 402 and 420 in the CD4 cytoplasmic domain. Using an in vitro translation system, we also showed that degradation of CD4 by Vpu requires the two proteins to be present in the same membrane compartment. Although these results suggest that spatial proximity between CD4 and Vpu may be critical in triggering degradation, it remains unknown whether the two molecules have the ability to interact with each other. In order to better define the mechanisms involved in CD4 degradation, we investigated the existence and functional relevance of direct interactions between CD4 and Vpu. Coimmunoprecipitation experiments showed that Vpu specifically binds to the cytoplasmic tail of CD4. This phenomenon is relevant to the mechanism of CD4 degradation since the ability of CD8/CD4 chimeric molecules and various CD4 mutants to form complexes with Vpu correlates with their sensitivity to degradation. Accordingly, we found that amino acid residues in the CD4 cytoplasmic tail previously shown to be important for degradation are necessary for Vpu binding. We further demonstrate that a deletion mutant of Vpu as well as a phosphorylation mutant, both biologically inactive with regard to CD4 degradation, retained the capacity to interact with the CD4 cytoplasmic domain. Taken together, these results indicate that Vpu binding is necessary to trigger CD4 degradation. However, the binding to target molecules is not sufficient per se to cause degradation. Interaction between CD4 and Vpu is thus likely to be an early event critical in triggering a multistep process leading to CD4 degradation.     

Vpu-induced degradation of CD4: requirement for specific amino acid residues in the cytoplasmic domain of CD4.

Two functions have been attributed to the product of the human immunodeficiency virus type 1 vpu open reading frame: it increases virion release from infected cells and induces rapid degradation of CD4 shortly after its synthesis. In the absence of Vpu, newly synthesized gp160 and CD4 associate in the endoplasmic reticulum (ER), forming a complex whose further maturation is blocked and which is eventually degraded. In studies using NL4-3-based expression vectors, it has been previously shown that Vpu induces the release of gp160 from the complex that it forms with CD4 in the ER. This release, which appears to be due to the rapid degradation of CD4 induced by Vpu, allows gp160 to transit to the Golgi, where it matures further. We investigated which regions of CD4 are important for its susceptibility to Vpu-induced degradation by transfecting HeLa cells with isogenic vpu-positive and vpu-negative proviruses and vectors expressing various truncated or mutated CD4 molecules. The results suggested that the cytoplasmic domain of CD4 contains a determinant lying within amino acids 418 to 425 that is critical for susceptibility to Vpu-induced degradation. Neither the phosphorylation sites in the cytoplasmic domain nor the Lck interaction region was required for the effect. Vpu-induced degradation was specific for CD4, since CD8, even when retained in the ER, was not degraded. In addition, under conditions of high-level Vpu expression, CD4 degradation could be observed in the absence of gp160 or other means of retaining CD4 in the ER.     

Effects of deletions in the cytoplasmic domain on biological functions of human immunodeficiency virus type 1 envelope glycoproteins.

The role of the cytoplasmic domain of the human immunodeficiency virus type 1 (HIV-1) envelope glycoproteins in virus replication was investigated. Deletion of residues 840 to 856 at the carboxyl terminus of gp41 reduced the efficiency of virus entry during an early step in the virus life cycle between CD4 binding and formation of the DNA provirus without affecting envelope glycoprotein synthesis, processing, or syncytium-forming ability. Deletion of residues amino terminal to residue 846 was associated with decreased stability of envelope glycoproteins made in COS-1 cells, but this phenotype was cell type dependent. The cytoplasmic domain of gp41 was not required for the incorporation of the HIV-1 envelope glycoproteins into virions. These results suggest that the carboxyl terminus of the gp41 cytoplasmic domain plays a role in HIV-1 entry other than receptor binding or membrane fusion. The cytoplasmic domain of gp41 also affects the stability of the envelope glycoprotein in some cell types.     

Sequences present in the cytoplasmic domain of CD4 are necessary and sufficient to confer sensitivity to the human immunodeficiency virus type 1 Vpu protein.

CD4 is an integral membrane glycoprotein which functions as the human immunodeficiency virus receptor for infection of human host cells. We have recently demonstrated that Vpu, a human immunodeficiency virus type 1-encoded integral membrane phosphoprotein, induces rapid degradation of CD4 in the endoplasmic reticulum. Using an in vitro model system, we demonstrated that Vpu targets specific sequences in the cytoplasmic domain of CD4 to promote its degradation. In this report, we have further delineated regions within CD4 which are required for susceptibility to Vpu. Transfer of the CD4 cytoplasmic region into a heterologous protein, CD8, rendered the chimeric protein sensitive to Vpu-dependent degradation. In contrast, substitution of the CD8 transmembrane domain with the analogous region from CD4 did not confer sensitivity to Vpu. Finally, mutant forms of the CD4 protein containing the extracellular region alone or the extracellular and transmembrane regions linked to a heterologous cytoplasmic domain were not targeted by Vpu. Thus, sequences present in the cytoplasmic domain of CD4 are necessary and sufficient to confer sensitivity to Vpu.     

Human immunodeficiency virus type 1 Vpu protein induces degradation of CD4 in vitro: the cytoplasmic domain of CD4 contributes to Vpu sensitivity.

CD4 is an integral membrane glycoprotein which functions as the human immunodeficiency virus (HIV) receptor for infection of human host cells. We have recently demonstrated that Vpu, an HIV type 1 (HIV-1) encoded integral membrane phosphoprotein, induces rapid degradation of CD4 in the endoplasmic reticulum. In this report, we describe an in vitro model system that allowed us to define important parameters for Vpu-dependent CD4 degradation. The rate of CD4 decay in rabbit reticulocyte lysate was approximately one-third of that observed previously in tissue culture experiments in the presence of Vpu (40 versus 12 min) and required no other HIV-1 encoded proteins. Degradation was contingent on the presence of microsomal membranes in the assay and the coexpression of Vpu and CD4 in the same membrane compartment. By using the in vitro degradation assay, the effects of specific mutations in CD4, including C-terminal truncations and glycosylation mutants, were analyzed. The results of these experiments indicate that Vpu has the capacity to induce degradation of glycosylated as well as nonglycosylated membrane-associated CD4. Truncation of 13 C-terminal amino acids of CD4 did not affect the ability of Vpu to induce its degradation. However, the removal of 32 amino acids from the C-terminus of CD4 completely abolished sensitivity to Vpu. This suggests that Vpu targets specific sequences in the cytoplasmic domain of CD4 to induce its degradation. We also analyzed the effects of mutations in Vpu on its biological activity in the in vitro CD4 degradation assay. The results of these experiments suggest that sequences critical for this function of Vpu are located in its hydrophilic C-terminal domain.     

Functional domains within the human immunodeficiency virus type 2 envelope protein required to enhance virus production

Primate lentiviruses code for a protein that stimulates virus production. In human immunodeficiency virus type 1 (HIV-1), the activity is provided by the accessory protein, Vpu, while in HIV-2 and simian immunodeficiency virus it is a property of the envelope (Env) glycoprotein. Using a group of diverse retroviruses and cell types, we have confirmed the functional equivalence of the two proteins. However, despite these similarities, the two proteins have markedly different functional domains. While the Vpu activity is associated primarily with its membrane-spanning region, we have determined that the HIV-2 Env activity requires both the cytoplasmic tail and ectodomain of the protein, with the membrane-spanning domain being less important. Within the Env cytoplasmic tail, we further defined the necessary sequence as a membrane-proximal tyrosine-based motif. Providing the two Env regions separately as distinct CD8 chimeric proteins did not increase virus release. This suggests that the two domains must be either contained within a single protein or closely associated within a multiprotein oligomer, such as the Env trimer, in order to function. Finally, we observed that wild-type levels of incorporation of the HIV-2 Env into budding viruses were not required for this activity.     

Sequences in gibbon ape leukemia virus envelope that confer sensitivity to HIV-1 accessory protein Vpu

HIV-1 efficiently forms pseudotyped particles with many gammaretrovirus glycoproteins, such as Friend murine leukemia virus (F-MLV) Env, but not with the related gibbon ape leukemia virus (GaLV) Env or with a chimeric F-MLV Env with a GaLV cytoplasmic tail domain (CTD). This incompatibility is modulated by the HIV-1 accessory protein Vpu. Because the GaLV Env CTD does not resemble tetherin or CD4, the well-studied targets of Vpu, we sought to characterize the modular sequence in the GaLV Env CTD required for this restriction in the presence of Vpu. Using a systematic mutagenesis scan, we determined that the motif that makes GaLV Env sensitive to Vpu is INxxIxxVKxxVxRxK. This region in the CTD of GaLV Env is predicted to form a helix. Mutations in the CTD that would break this helix abolish sensitivity to Vpu. Although many of these positions can be replaced with amino acids with similar biophysical properties without disrupting the Vpu sensitivity, the final lysine residue is required. This Vpu sensitivity sequence appears to be modular, as the unrelated Rous sarcoma virus (RSV) Env can be made Vpu sensitive by replacing its CTD with the GaLV Env CTD. In addition, F-MLV Env can be made Vpu sensitive by mutating two amino acids in its cytoplasmic tail to make it resemble more closely the Vpu sensitivity motif. Surprisingly, the core components of this Vpu sensitivity sequence are also present in the host surface protein CD4, which is also targeted by Vpu through its CTD.     

Vpu Downmodulates Two Distinct Targets,Tetherin and Gibbon Ape Leukemia Virus Envelope,through Shared Features in the Vpu Cytoplasmic Tail

During human immunodeficiency virus-1 (HIV-1) assembly, the host proteins CD4 (the HIV-1 receptor) and tetherin (an interferon stimulated anti-viral protein) both reduce viral fitness. The HIV-1 accessory gene Vpu counteracts both of these proteins, but it is thought to do so through two distinct mechanisms. Modulation of CD4 likely occurs through proteasomal degradation from the endoplasmic reticulum. The exact mechanism of tetherin modulation is less clear, with possible roles for degradation and alteration of protein transport to the plasma membrane. Most investigations of Vpu function have used different assays for CD4 and tetherin. In addition, many of these investigations used exogenously expressed Vpu, which could result in variable expression levels. Thus, few studies have investigated these two Vpu functions in parallel assays, making direct comparisons difficult. Here, we present results from a rapid assay used to simultaneously investigate Vpu-targeting of both tetherin and a viral glycoprotein, gibbon ape leukemia virus envelope (GaLV Env). We previously reported that Vpu modulates GaLV Env and prevents its incorporation into HIV-1 particles through a recognition motif similar to that found in CD4. Using this assay, we performed a comprehensive mutagenic scan of Vpu in its native proviral context to identify features required for both types of activity. We observed considerable overlap in the Vpu sequences required to modulate tetherin and GaLV Env. We found that features in the cytoplasmic tail of Vpu, specifically within the cytoplasmic tail hinge region, were required for modulation of both tetherin and GaLV Env. Interestingly, these same regions features have been determined to be critical for CD4 downmodulation. We also observed a role for the transmembrane domain in the restriction of tetherin, as previously reported, but not of GaLV Env. We propose that Vpu may target both proteins in a mechanistically similar manner, albeit in different cellular locations.     

An internalization signal in the simian immunodeficiency virus transmembrane protein cytoplasmic domain modulates expression of envelope glycoproteins on the cell surface

A Tyr to Cys mutation at amino acid position 723 in the cytoplasmic domain of the simian immunodeficiency virus (SIV) transmembrane (TM) molecule has been shown to increase expression of envelope glycoproteins on the surface of infected cells. Here we show that Tyr- 723 contributes to a sorting signal that directs the rapid endocytosis of viral glycoproteins from the plasma membrane via coated pits. On cells infected by SIVs with a Tyr at position 723, envelope glycoproteins were transiently expressed on the cell surface and then rapidly endocytosed. Similar findings were noted for envelope molecules expressed in the absence of other viral proteins. Immunoelectron microscopy demonstrated that these molecules were localized in patches on the cell surface and were frequently associated with coated pits. In contrast, envelope glycoproteins containing a Y723C mutation were diffusely distributed over the entire plasma membrane. To determine if an internalization signal was present in the SIV TM, chimeric molecules were constructed that contained the CD4 external and membrane spanning domains and a SIV TM cytoplasmic tail with a Tyr or other amino acids at SIV position 723. In Hela cells stably expressing these molecules, chimeras with a Tyr-723 were rapidly endocytosed, while chimeras containing other amino acids at position 723, including a Phe, were internalized at rates only slightly faster than a CD4 molecule that lacked a cytoplasmic domain. In addition, the biological effects of the internalization signal were evaluated in infectious viruses. A mutation that disrupted the signal and as a result, increased the level of viral envelope glycoprotein on infected cells, was associated with accelerated infection kinetics and increased cell fusion during viral replication. These results demonstrate that a Tyr-dependent motif in the SIV TM cytoplasmic domain can function as an internalization signal that can modulate expression of the viral envelope molecules on the cell surface and affect the biological properties of infectious viruses. The conservation of an analogous Tyr in all human and simian immunodeficiency viruses suggests that this signal may be present in other primate lentiviruses and could be important in the pathogenesis of these viruses in vivo.     

The two biological activities of human immunodeficiency virus type 1 Vpu protein involve two separable structural domains.

The human immunodeficiency virus type 1 (HIV-1) Vpu protein is an integral membrane phosphoprotein that induces CD4 degradation in the endoplasmic reticulum and enhances virus release from the cell surface. CD4 degradation is specific, requires phosphorylation of Vpu, and involves the interaction between Vpu and the CD4 cytoplasmic domain. In contrast, regulation of virus release is less specific and not restricted to HIV-1 and may be mechanistically-distinct from CD4 degradation. We show here that a mutant of Vpu, Vpu35, lacking most of its cytoplasmic domain has residual biological activity for virus release but is unable to induce CD4 degradation. This finding suggests that the N terminus of Vpu encoding the transmembrane (TM) anchor represents an active domain important for the regulation of virus release but not CD4 degradation. To better define the functions of Vpu's TM anchor and cytoplasmic domain, we designed a mutant, VpuRD, containing a scrambled TM sequence with a conserved amino acid composition and alpha-helical structure. The resulting protein was integrated normally into membranes, was able to form homo-oligomers, and exhibited expression levels, protein stability, and subcellular localization similar to those of wild-type Vpu. Moreover, VpuRD was capable of binding to CD4 and to induce CD4 degradation with wild-type efficiency, confirming proper membrane topology and indicating that the alteration of the Vpu TM domain did not interfere with this function of Vpu. However, VpuRD was unable to enhance the release of virus particles from infected or transfected cells, and virus encoding VpuRD had replication characteristics in T cells indistinguishable from those of a Vpu-deficient HIV-1 isolate. Mutation of the phosphorylation sites in VpuRD resulted in a protein which was unable to perform either function of Vpu. The results of our experiments suggest that the two biological activities of Vpu operate via two distinct molecular mechanisms and involve two different structural domains of the Vpu protein.     

Analysis of the cell fusion activities of chimeric simian immunodeficiency virus-murine leukemia virus envelope proteins: inhibitory effects of the R peptide.

It was previously reported that truncation or proteolytic removal of the C-terminal 16 amino acids (the R peptide) from the cytoplasmic tail of the murine leukemia virus (MuLV) envelope protein greatly increases its fusion activity. In this study, to investigate the specificity of the effect of the R peptide on the fusion activity of viral envelope proteins, we expressed simian immunodeficiency virus (SIV)-MuLV chimeric proteins in which the entire cytoplasmic tail of the SIV envelope protein was replaced by either the full-length MuLV cytoplasmic tail or a truncated MuLV cytoplasmic tail with the R peptide deleted. Extensive fusion of CD4-positive cells with the chimeric protein containing a truncated MuLV cytoplasmic tail was observed. In contrast, no cell fusion activity was found for the chimeric protein with a full-length MuLV cytoplasmic tail. We constructed another SIV-MuLV chimeric protein in which the MuLV R peptide was added to an SIV envelope protein cytoplasmic tail 17 amino acids from its membrane-spanning domain. No fusion activity was observed within this construct, while the corresponding truncated SIV envelope protein lacking the R peptide showed extensive fusion activity. No significant difference in the transport or surface expression was observed among the various SIV-MuLV chimeric proteins and the truncated SIV envelope protein. Our results thus demonstrate that the MuLV R peptide has profound inhibitory effects on virus-induced cell fusion, not only with MuLV but also in a distantly related retroviral envelope protein which utilizes a different receptor and fuses different cell types.     

Multilayered Mechanism of CD4 Downregulation by HIV-1 Vpu Involving Distinct ER Retention and ERAD Targeting Steps

A key function of the Vpu protein of HIV-1 is the targeting of newly-synthesized CD4 for proteasomal degradation. This function has been proposed to occur by a mechanism that is fundamentally distinct from the cellular ER-associated degradation (ERAD) pathway. However, using a combination of genetic, biochemical and morphological methodologies, we find that CD4 degradation induced by Vpu is dependent on a key component of the ERAD machinery, the VCP-UFD1L-NPL4 complex, as well as on SCF^β-TrCP-dependent ubiquitination of the CD4 cytosolic tail on lysine and serine/threonine residues. When degradation of CD4 is blocked by either inactivation of the VCP-UFD1L-NPL4 complex or prevention of CD4 ubiquitination, Vpu still retains the bulk of CD4 in the ER mainly through transmembrane domain interactions. Addition of a strong ER export signal from the VSV-G protein overrides this retention. Thus, Vpu exerts two distinct activities in the process of downregulating CD4: ER retention followed by targeting to late stages of ERAD. The multiple levels at which Vpu engages these cellular quality control mechanisms underscore the importance of ensuring profound suppression of CD4 to the life cycle of HIV-1.     

Separable determinants of subcellular localization and interaction account for the inability of group O HIV-1 Vpu to counteract tetherin

Tetherin (BST-2/CD317) is thought to restrict retroviral particle release by cross-linking nascent viral and cellular membranes. Unlike the Vpu proteins encoded by human immunodeficiency virus type 1 (HIV-1) group M strains (M-Vpu), those from the nonpandemic HIV-1 group O (O-Vpu) are not able to counteract tetherin activity. Here, we characterized the basis of this defect in O-Vpu. O-Vpu differs from M-Vpu in that it fails to interact with tetherin and downregulate it from the cell surface. Unlike M-Vpu, O-Vpu localizes to the endoplasmic reticulum (ER) rather than the trans-Golgi network (TGN). Interestingly M-Vpu bearing an ER retention signal at the C terminus localizes similarly to O-Vpu. While it still interacts with tetherin, it fails to promote virus release, suggesting that O-Vpu deficiency correlates with its cellular distribution in the endoplasmic reticulum as well as its failure to bind tetherin. O-Vpu-M-Vpu chimeras were designed to identify the minimal changes required to restore tetherin antagonism. While several chimeric proteins bearing residues of the M-Vpu transmembrane domain into the O-Vpu transmembrane domain recovered tetherin binding in coimmunoprecipitation studies, efficient antagonism required an additional glutamic acid-to-lysine change in the membrane-proximal hinge region of the O-Vpu cytoplasmic tail that was sufficient to abolish ER retention and permit TGN localization.     

Virion incorporation of envelope glycoproteins with long but not short cytoplasmic tails is blocked by specific, single amino acid substitutions in the human immunodeficiency virus type 1 matrix.

Incorporation of envelope glycoproteins into a budding retrovirus is an essential step in the formation of an infectious virus particle. By using site-directed mutagenesis, we identified specific amino acid residues in the matrix domain of the human immunodeficiency virus type 1 (HIV-1) Gag protein that are critical to the incorporation of HIV-1 envelope glycoproteins into virus particles. Pseudotyping analyses were used to demonstrate that two heterologous envelope glycoproteins with short cytoplasmic tails (the envelope of the amphotropic murine leukemia virus and a naturally truncated HIV-2 envelope) are efficiently incorporated into HIV-1 particles bearing the matrix mutations. Furthermore, deletion of the cytoplasmic tail of HIV-1 transmembrane envelope glycoprotein gp41 from 150 to 7 or 47 residues reversed the incorporation block imposed by the matrix mutations. These results suggest the existence of a specific functional interaction between the HIV-1 matrix and the gp41 cytoplasmic tail.     

Expression, purification, and activities of full-length and truncated versions of the integral membrane protein Vpu from HIV-1

Vpu is an 81-residue accessory protein of HIV-1. Because it is a membrane protein, it presents substantial technical challenges for the characterization of its structure and function, which are of considerable interest because the protein enhances the release of new virus particles from cells infected with HIV-1 and induces the intracellular degradation of the CD4 receptor protein. The Vpu-mediated enhancement of the virus release rate from HIV-1-infected cells is correlated with the expression of an ion channel activity associated with the transmembrane hydrophobic helical domain. Vpu-induced CD4 degradation and, to a lesser extent, enhancement of particle release are both dependent on the phosphorylation of two highly conserved serine residues in the cytoplasmic domain of Vpu. To define the minimal folding units of Vpu and to identify their activities, we prepared three truncated forms of Vpu and compared their structural and functional properties to those of full-length Vpu (residues 2-81). Vpu(2-37) encompasses the N-terminal transmembrane alpha-helix; Vpu(2-51) spans the N-terminal transmembrane helix and the first cytoplasmic alpha-helix; Vpu(28-81) includes the entire cytoplasmic domain containing the two C-terminal amphipathic alpha-helices without the transmembrane helix. Uniformly isotopically labeled samples of the polypeptides derived from Vpu were prepared by expression of fusion proteins in E. coli and were studied in the model membrane environments of lipid micelles by solution NMR spectroscopy and oriented lipid bilayers by solid-state NMR spectroscopy. The assignment of backbone resonances enabled the secondary structure of the constructs corresponding to the transmembrane and the cytoplasmic domains of Vpu to be defined in micelle samples by solution NMR spectroscopy. Solid-state NMR spectra of the polypeptides in oriented lipid bilayers demonstrated that the topology of the domains is retained in the truncated polypeptides. The biological activities of the constructs of Vpu were evaluated. The ion channel activity is confined to the transmembrane alpha-helix. The C-terminal alpha-helices modulate or promote the oligomerization of Vpu in the membrane and stabilize the conductive state of the channel, in addition to their involvement in CD4 degradation.     

Truncation of the cytoplasmic domain of the simian immunodeficiency virus envelope glycoprotein increases env incorporation into particles and fusogenicity and infectivity.

Growth of macaque simian immunodeficiency virus (SIVmac) in certain cloned human T-cell lines, such as HUT.78, selects for isolates containing a premature stop codon within the cytoplasmic domain of the transmembrane envelope glycoprotein. In contrast, propagation of virus in macaques or in their cultured T cells favors replication of virus containing the full-length envelope glycoprotein. To elucidate the causes of this phenomenon, we used a human immunodeficiency virus pseudotyping system to assess the effects on infectivity of the cytoplasmic domains of envelope glycoproteins obtained from SIVmac1A11 and SIVmac239. These envelopes contain truncated and full-length cytoplasmic domains, respectively. By analyzing human immunodeficiency virus particles containing selectable genes pseudotyped with each glycoprotein or with chimeric derivatives, we found that truncation of the cytoplasmic domain resulted in a significant advantage in viral entry into HUT.78 T cells and CD4+ U87.MG glial cells. Truncation of the cytoplasmic domain significantly enhanced both envelope density on particles and envelope-mediated cell-to-cell fusion. It is likely that one or both of these effects contribute to the observed differences in infectivity and to the selection of virions with short cytoplasmic tails in human T cells.     

Human immunodeficiency virus type 1 Vpu protein induces rapid degradation of CD4.

CD4 is an integral membrane glycoprotein which is known as the human immunodeficiency virus (HIV) receptor for infection of human cells. The protein is synthesized in the endoplasmic reticulum (ER) and subsequently transported to the cell surface via the Golgi complex. HIV infection of CD4+ cells leads to downmodulation of cell surface CD4, due at least in part to the formation of stable intracellular complexes between CD4 and the HIV type 1 (HIV-1) Env precursor polyprotein gp160. This process "traps" both proteins in the ER, leading to reduced surface expression of CD4 and reduced processing of gp160 to gp120 and gp41. We have recently demonstrated that the presence of the HIV-1-encoded integral membrane protein Vpu can reduce the formation of Env-CD4 complexes, resulting in increased gp160 processing and decreased CD4 stability. We have studied the effect of Vpu on CD4 stability and found that Vpu induces rapid degradation of CD4, reducing the half-life of CD4 from 6 h to 12 min. By using a CD4-binding mutant of gp160, we were able to show that this Vpu-induced degradation of CD4 requires retention of CD4 in the ER, which is normally accomplished through its binding to gp160. The involvement of gp160 in the induction of CD4 degradation is restricted to its function as a CD4 trap, since, in the absence of Env, an ER retention mutant of CD4, as well as wild-type CD4 in cultures treated with brefeldin A, a drug that blocks transport of proteins from the ER, is degraded in the presence of Vpu.     

The RING-CH Ligase K5 Antagonizes Restriction of KSHV and HIV-1 Particle Release by Mediating Ubiquitin-Dependent Endosomal Degradation of Tetherin

Tetherin (CD317/BST2) is an interferon-induced membrane protein that inhibits the release of diverse enveloped viral particles. Several mammalian viruses have evolved countermeasures that inactivate tetherin, with the prototype being the HIV-1 Vpu protein. Here we show that the human herpesvirus Kaposi''s sarcoma-associated herpesvirus (KSHV) is sensitive to tetherin restriction and its activity is counteracted by the KSHV encoded RING-CH E3 ubiquitin ligase K5. Tetherin expression in KSHV-infected cells inhibits viral particle release, as does depletion of K5 protein using RNA interference. K5 induces a species-specific downregulation of human tetherin from the cell surface followed by its endosomal degradation. We show that K5 targets a single lysine (K18) in the cytoplasmic tail of tetherin for ubiquitination, leading to relocalization of tetherin to CD63-positive endosomal compartments. Tetherin degradation is dependent on ESCRT-mediated endosomal sorting, but does not require a tyrosine-based sorting signal in the tetherin cytoplasmic tail. Importantly, we also show that the ability of K5 to substitute for Vpu in HIV-1 release is entirely dependent on K18 and the RING-CH domain of K5. By contrast, while Vpu induces ubiquitination of tetherin cytoplasmic tail lysine residues, mutation of these positions has no effect on its antagonism of tetherin function, and residual tetherin is associated with the trans-Golgi network (TGN) in Vpu-expressing cells. Taken together our results demonstrate that K5 is a mechanistically distinct viral countermeasure to tetherin-mediated restriction, and that herpesvirus particle release is sensitive to this mode of antiviral inhibition.     

Molecular determinants of acute single-cell lysis by human immunodeficiency virus type 1.

Human immunodeficiency virus type 1 (HIV-1) infection of CD4-positive lymphocytes is accompanied by acute cytopathic effects, i.e., syncytium formation and single-cell lysis. Syncytium formation involves cell-cell fusion mediated by viral envelope glycoproteins on the surface of infected cells and by CD4 glycoproteins on adjacent cells. The molecular basis for the lysis of single-HIV-1 infected cells is unclear. Here we report that the expression of functional envelope glycoproteins from primary and laboratory-adapted HIV-1 isolates resulted in the lysis of single CD4-positive lymphocytes. As was previously observed in HIV-1 infected cultures, single-cell lysis in this system primarily involved necrosis and was not inhibited by soluble CD4. Binding of the viral envelope glycoproteins to the CD4 glycoprotein facilitated, but was not sufficient for, cytolysis. Importantly, the ability of the HIV-1 envelope glycoproteins to mediate membrane fusion was essential for single-cell killing. By contrast, the long cytoplasmic tail of the gp41 transmembrane envelope glycoprotein was neither necessary nor sufficient for single-cell lysis. These results suggest that intracellular envelope glycoprotein-CD4 interactions initiate autofusion events that disrupt cell membrane integrity, leading to single-cell lysis by HIV-1.