Mammalian cells employ numerous innate cellular mechanisms to inhibit viral replication and spread. Tetherin, also known as Bst-2 or CD317, is a recently identified, IFN-induced, cellular response factor that blocks release of HIV-1 and other retroviruses from infected cells. The means by which tetherin retains retroviruses on the cell surface, as well as the mechanism used by the HIV-1 accessory protein Vpu to antagonize tetherin function and promote HIV-1 release, are unknown. Here, we document that tetherin functions as a broadly acting antiviral factor by demonstrating that both human and murine tetherin potently inhibit the release of the filovirus, Ebola, from the surface of cells. Expression of the Ebola glycoprotein (GP) antagonized the antiviral effect of human and murine tetherin and facilitated budding of Ebola particles, as did the HIV-1 Vpu protein. Conversely, Ebola GP could substitute for Vpu to promote HIV-1 virion release from tetherin-expressing cells, demonstrating a common cellular target for these divergent viral proteins. Ebola GP efficiently coimmunoprecipitated with tetherin, suggesting that the viral glycoprotein directly interferes with this host antiviral factor. These results demonstrate that tetherin is a cellular antiviral factor that restricts budding of structurally diverse enveloped viruses. Additionally, Ebola has evolved a highly effective strategy to combat this antiviral response elicited in the host during infection.antiviral ͉ CD317 ͉ viral budding ͉ HIV-1 vpu ͉ Bst-2
CCR5 antagonists inhibit HIV entry by binding to a coreceptor and inducing changes in the extracellular loops (ECLs) of CCR5. In this study, we analyzed viruses from 11 treatment-experienced patients who experienced virologic failure on treatment regimens containing the CCR5 antagonist maraviroc (MVC). Viruses from one patient developed high-level resistance to MVC during the course of treatment. Although resistance to one CCR5 antagonist is often associated with broad cross-resistance to other agents, these viruses remained sensitive to most other CCR5 antagonists, including vicriviroc and aplaviroc. MVC resistance was dependent upon mutations within the V3 loop of the viral envelope (Env) protein and was modulated by additional mutations in the V4 loop. Deep sequencing of pretreatment plasma viral RNA indicated that resistance appears to have occurred by evolution of drug-bound CCR5 use, despite the presence of viral sequences predictive of CXCR4 use. Envs obtained from this patient before and during MVC treatment were able to infect cells expressing very low CCR5 levels, indicating highly efficient use of a coreceptor. In contrast to previous reports in which CCR5 antagonist-resistant viruses interact predominantly with the N terminus of CCR5, these MVC-resistant Envs were also dependent upon the drug-modified ECLs of CCR5 for entry. Our results suggest a model of CCR5 cross-resistance whereby viruses that predominantly utilize the N terminus are broadly cross-resistant to multiple CCR5 antagonists, whereas viruses that require both the N terminus and antagonist-specific ECL changes demonstrate a narrow cross-resistance profile.
We previously reported that a human immunodeficiency virus type 1 (HIV-1) clade B envelope protein with a severely truncated V3 loop regained function after passage in tissue culture. The adapted virus, termed TA1, retained the V3 truncation, was exquisitely sensitive to neutralization by the CD4 binding site monoclonal antibody b12 and by HIV-positive human sera, used CCR5 to enter cells, and was completely resistant to small molecule CCR5 antagonists. To examine the mechanistic basis for these properties, we singly and in combination introduced each of the 5 mutations from the adapted clone TA1 into the unadapted envelope. We found that single amino acid changes in the C3 region, the V3 loop, and in the fusion peptide were responsible for imparting near-normal levels of envelope function to TA1. T342A, which resulted in the loss of a highly conserved glycosylation site in C3, played the primary role. The adaptive amino acid changes had no impact on CCR5 antagonist resistance but made virus more sensitive to neutralization by antibodies to the CD4 binding site, modestly enhanced affinity for CD4, and made TA1 more responsive to CD4 binding. Specifically, TA1 was triggered by soluble CD4 more readily than the parental Env and, unlike the parental Env, could mediate entry on cells that express low levels of CD4. In contrast, TA1 interacted with CCR5 less efficiently and was highly sensitive to antibodies that bind to the CCR5 N terminus and ECL2. Therefore, enhanced utilization of CD4 is one mechanism by which HIV-1 can overcome mutations in the V3 region that negatively affect CCR5 interactions.The human immunodeficiency virus type 1 (HIV-1) envelope protein (Env) mediates sequential binding to CD4 and a coreceptor, with these interactions triggering conformational changes in Env that result in fusion between the viral and cellular membranes (2,12,66). The V3 loop in the gp120 subunit of the Env protein is thought to interact with the extracellular loops (ECLs) of the seven-transmembrane domain HIV-1 coreceptors, CCR5 and CXCR4 (9,10,28,45,51), while the base of the V3 loop and the bridging sheet region of gp120 are thought to engage the amino-terminal domains of the coreceptors (23). In addition, the V3 loop plays a major role in determining whether a given virus strain utilizes CCR5, CXCR4, or both coreceptors subsequent to CD4 binding (6, 7, 57). Perhaps because of its role in coreceptor engagement, the overall length of the V3 loop is highly conserved, as are specific residues that may play key roles in receptor binding (11,33,70). However, the V3 loop is also a target for neutralizing antibodies, making it subject to immune selection (20,25,26,44,47). In addition, the V3 loop as well as the highly variable V1/V2 region shield more conserved regions of Env that are also involved in receptor binding (16,20,33,58,59).The importance of the V3 loop for Env function is shown by the fact that genetic deletion of residues in V3 typically results in a nonfunctional Env protein (5,19,67). While V3 loopdeleted Envs ap...
The HIV envelope (Env) protein uses a dense coat of glycans to mask conserved domains and evade host humoral immune responses. The broadly neutralizing antibody 2G12, which binds a specific cluster of high-mannose glycans on HIV Env, shows that the glycan shield can also serve as a target for neutralizing antibodies. We have described a triple mutant Saccharomyces cerevisiae strain that expresses high-mannose glycoproteins that bind to 2G12. When used to immunize rabbits, this yeast elicits antibodies that bind to gp120-associated glycans but fail to neutralize virus. Here we sought to determine the reason for these discordant results. Affinity purification of sera over columns conjugated with three 2G12-reactive yeast glycoproteins showed that these proteins could adsorb 80% of the antibodies that bind to gp120 glycans. Despite binding to monomeric gp120, these mannose-specific antibodies failed to bind cell surface-expressed trimeric Env. However, when Env was expressed in the presence of the mannosidase inhibitor kifunensine to force retention of high-mannose glycans at all sites, the purified antibodies gained the abilities to bind trimeric Env and to strongly and broadly neutralize viruses produced under these conditions. Combined, these data show that the triple mutant yeast strain elicits antibodies that bind to high-mannose glycans presented on the HIV envelope, but only when they are displayed in a manner not found on native Env trimers. This implies that the underlying structure of the protein scaffold used to present the high-mannose glycans may be critical to allow elicitation of antibodies that recognize trimeric Env and neutralize virus.
The human immunodeficiency virus type 1 (HIV-1) envelope (Env) protein contains numerous N-linked carbohydrates that shield conserved peptide epitopes and promote trans infection by dendritic cells via binding to cell surface lectins. The potent and broadly neutralizing monoclonal antibody 2G12 binds a cluster of high-mannose-type oligosaccharides on the gp120 subunit of Env, revealing a conserved and highly exposed epitope on the glycan shield. To find an effective antigen for eliciting 2G12-like antibodies, we searched for endogenous yeast proteins that could bind to 2G12 in a panel of Saccharomyces cerevisiae glycosylation knockouts and discovered one protein that bound weakly in a ⌬pmr1 strain deficient in hyperglycosylation. 2G12 binding to this protein, identified as Pst1, was enhanced by adding the ⌬mnn1 deletion to the ⌬pmr1 background, ensuring the exposure of terminal ␣1,2-linked mannose residues on the D1 and D3 arms of high-mannose glycans. However, optimum 2G12 antigenicity was found when Pst1, a heavily N-glycosylated protein, was expressed with homogenous Man 8 GlcNAc 2 structures in ⌬och1 ⌬mnn1 ⌬mnn4 yeast. Surface plasmon resonance analysis of this form of Pst1 showed high affinity for 2G12, which translated into Pst1 efficiently inhibiting gp120 interactions with 2G12 and DC-SIGN and blocking 2G12-mediated neutralization of HIV-1 pseudoviruses. The high affinity of the yeast glycoprotein Pst1 for 2G12 highlights its potential as a novel antigen to induce 2G12-like antibodies.The human immunodeficiency virus (HIV) has evolved numerous means to evade the humoral immune response, including a two-receptor mechanism for entry that recesses and protects highly conserved binding sites in the gp120 subunit of the viral envelope (Env) protein, trimerization of Env to further protect neutralizing epitopes readily exposed on the monomer, and rapid and continual mutation in the face of immune selective pressure (8, 9). Another highly effective defense mechanism is found in the extensive array of oligosaccharides covering gp120, with approximately 25
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.