Cell Surface Proteomic Map of HIV Infection Reveals Antagonism of Amino Acid Metabolism by Vpu and Nef.

Critical cell surface immunoreceptors downregulated during HIV infection have previously been identified using non-systematic, candidate approaches. To gain a comprehensive, unbiased overview of how HIV infection remodels the T cell surface, we took a distinct, systems-level, quantitative proteomic approach. >100 plasma membrane proteins, many without characterized immune functions, were downregulated during HIV infection. Host factors targeted by the viral accessory proteins Vpu or Nef included the amino acid transporter SNAT1 and the serine carriers SERINC3/5. We focused on SNAT1, a ß-TrCP-dependent Vpu substrate. SNAT1 antagonism was acquired by Vpu variants from the lineage of SIVcpz/HIV-1 viruses responsible for pandemic AIDS. We found marked SNAT1 induction in activated primary human CD4+ T cells, and used Consumption and Release (CoRe) metabolomics to identify alanine as an endogenous SNAT1 substrate required for T cell mitogenesis. Downregulation of SNAT1 therefore defines a unique paradigm of HIV interference with immunometabolism.

Antagonism of aminoacid transport in primary CD4 T cells by HIV-1 Vpu.

BACKGROUND: Less than 100 years since it was first transmitted to the human population HIV-1 infects more than 30 million people worldwide and causes almost 2 million AIDS-related deaths every year. Viruses manipulate cellular genes and pathways to benefit their survival, and the study of cell surface proteins downregulated by viruses has provided insights into both viral pathogenesis and crucial aspects of cell biology. We aimed to identify novel cell surface proteins targeted for downregulation by HIV-1. METHODS: We combined plasma membrane enrichment through selective aminooxybiotinylation with tandem mass tag-based quantitative proteomics (plasma membrane profiling) to map expression timecourses of more than 800 plasma membrane proteins in T cells infected in vitro with HIV-1. Novel substrates of the viral accessory proteins Vpu and Nef were sought by use of deletion viruses and single gene overexpression. FINDINGS: Our proteomic datasets defined more than 100 previously unsuspected cell surface targets of HIV-1, particularly proteins involved in T-cell activation, cell adhesion, and aminoacid transport. In addition to its known targets, Vpu was found to be necessary and sufficient for the downregulation of the aminoacid transporter TOV3. Downregulation of TOV3 was post transcriptional, mediated by the ß-TrCP ubiquitin E3 ligase and occurred via an endolysosomal pathway. TOV3 was highly expressed in primary human CD4 T cells, and depletion of TOV3 by RNA interference markedly impaired the mitogenic response to CD3/CD28 stimulation. We identified alanine as an endogenous TOV3 substrate, and showed that extracellular alanine was crucial for T-cell proliferation. INTERPRETATION: This study suggests that TOV3 downregulation is restricted to Vpu variants from the lineage of HIV-1 group M viruses giving rise to pandemic AIDS. Antagonism of alanine transport in CD4 T cells might contribute to HIV-1 pathogenesis through modulation of virus production, impairment of the adaptive immune response, or enhancement of CD4 T-cell loss. FUNDING: Wellcome Trust, Addenbrooke's Charitable Trust, Raymond and Beverly Sackler Foundation.

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.

Determinants of tetherin antagonism in the transmembrane domain of the human immunodeficiency virus type 1 Vpu protein.

Tetherin (BST2/CD317) potently restricts the particle release of human immunodeficiency virus type 1 (HIV-1) mutants defective in the accessory gene vpu. Vpu antagonizes tetherin activity and induces its cell surface downregulation and degradation in a manner dependent on the transmembrane (TM) domains of both proteins. We have carried out extensive mutagenesis of the HIV-1 NL4.3 Vpu TM domain to identify three amino acid positions, A14, W22, and, to a lesser extent, A18, that are required for tetherin antagonism. Despite the mutants localizing indistinguishably from the wild-type (wt) protein and maintaining the ability to multimerize, mutation of these positions rendered Vpu incapable of coimmunoprecipitating tetherin or mediating its cell surface downregulation. Interestingly, these amino acid positions are predicted to form one face of the Vpu transmembrane alpha helix and therefore potentially contribute to an interacting surface with the transmembrane domain of tetherin either directly or by modulating the conformation of Vpu oligomers. While the equivalent of W22 is invariant in HIV-1/SIVcpz Vpu proteins, the positions of A14 and A18 are highly conserved among Vpu alleles from HIV-1 groups M and N, but not those from group O or SIVcpz that lack human tetherin (huTetherin)-antagonizing activity, suggesting that they may have contributed to the adaption of HIV-1 to human tetherin.

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.