Temperature-dependent intermediates in HIV-1 envelope glycoprotein-mediated fusion revealed by inhibitors that target N- and C-terminal helical regions of HIV-1 gp41

Peptides derived from the N- (N-HR) and C- (C-HR) terminal heptad repeat regions adjacent to the fusion peptide and transmembrane domains, respectively, of human immunodeficiency virus (HIV)-1 gp41 inhibit HIV-1 viral envelope glycoproteins (Env)-mediated cell fusion specifically. The mechanism of HIV-1 Env-mediated cell fusion and its inhibition by agents that target the N- and C-HR regions was investigated. Priming experiments with Env-expressing cells indicate that the N-HR region but not the C-HR region is exposed by treatment with sCD4 at 31 degrees C, whereas both the N- and C-HR regions are exposed at 37 degrees C.     

Synergistic inhibition of HIV-1 envelope-mediated membrane fusion by inhibitors targeting the N and C-terminal heptad repeats of gp41

The human immunodeficiency virus type-1 (HIV-1) envelope (Env) proteins that mediate membrane fusion represent a major target for the development of new AIDS therapies. Three classes of Env-mediated membrane fusion inhibitors have been described that specifically target the pre-hairpin intermediate conformation of gp41. Class 2 inhibitors bind to the C-terminal heptad repeat (C-HR) of gp41. The single example of a class 3 inhibitor targets the trimeric N-terminal heptad repeat (N-HR) of gp41 and has been postulated to sequestrate the N-HR of the pre-hairpin intermediate through the formation of fusion incompetent heterotrimers. Here, we show that N(CCG)-gp41, a class 2 inhibitor, and N36(Mut(e,g)), a class 3 inhibitor, synergistically inhibit Env-mediated membrane fusion for several representative HIV-1 strains (X4 and R5) in both a cell fusion assay (with membrane-bound CD4) and an Env-pseudo-typed virus neutralization assay. The mechanistic, as well as potential therapeutic, implications of these observations for HIV-Env-mediated membrane fusion are discussed.     

The stability of the intact envelope glycoproteins is a major determinant of sensitivity of HIV/SIV to peptidic fusion inhibitors

C-peptides derived from the HIV envelope glycoprotein transmembrane subunit gp41 C-terminal heptad repeat (C-HR) region are potent HIV fusion inhibitors. These peptides interact with the gp41 N-terminal heptad repeat (N-HR) region and block the gp41 six-helix bundle formation that is required for fusion. However, the parameters that govern this inhibition have yet to be elucidated. We address this issue by comparing the ability of C34, derived from HIV-1, HIV-2 and SIV gp41, to inhibit HIV-1, HIV-2 and SIV envelope-mediated fusion and the ability of these peptides to form stable six-helix bundles with N36 peptides derived from gp41 of these three viruses. The ability to form six-helix bundles was examined by circular dichroism spectroscopy, and HIV/SIV Env-mediated membrane fusion was monitored by a dye transfer assay. HIV-1 N36 formed stable helix bundles with HIV-1, HIV-2 and SIV C34, which all inhibited HIV-1 Env-mediated fusion at IC(50)<10nM. The three C34 peptides were poor inhibitors of HIV-2 and SIV fusion (IC(50)>100nM), although HIV-2 and SIV N36 formed stable helix bundles with SIV C34. Priming experiments with sCD4 indicate that, in contrast to HIV-1, HIV-2 and SIV Env do not expose their N-HR region to SIV C34 following CD4 binding, but rapidly proceed to co-receptor engagement and six-helix bundle formation resulting in fusion. Our results suggest that several factors, including six-helix bundle stability and the ability of CD4 to destabilize the envelope glycoprotein, serve as determinants of sensitivity to entry inhibitors.     

Human immunodeficiency virus (HIV) gp41 escape mutants: cross-resistance to peptide inhibitors of HIV fusion and altered receptor activation of gp120

Human immunodeficiency virus (HIV) infects cells by fusing with cellular membranes. Fusion occurs when the envelope glycoprotein (Env) undergoes conformational changes while binding to cellular receptors. Fusogenic changes involve assembly of two heptad repeats in the ectodomain of the gp41 transmembrane subunit to form a six-helix bundle (6HB), consisting of a trimeric N heptad repeat (N-HR) coiled-coil core with three antiparallel C heptad repeats (C-HRs) that pack in the coiled-coil grooves. Peptides corresponding to the N-and C-HRs (N and C peptides, respectively) interfere with formation of the 6HB in a dominant-negative manner and are emerging as a new class of antiretroviral therapeutics for treating HIV infection. We generated an escape mutant virus with resistance to an N peptide and show that early resistance involved two mutations, one each in the N- and C-HRs. The mutations conferred resistance not only to the selecting N peptide but also to C peptides, as well as other types of N-peptide inhibitors. Moreover, the N-HR mutation altered sensitivity to soluble CD4. Biophysical studies suggest that the 6HB with the resistance mutations is more stable than the wild-type 6HB and the 6HB formed by inhibitor binding to either wild-type or mutant C-HR. These findings provide new insights into potential mechanisms of resistance to HIV peptide fusion inhibitors and dominant-negative inhibitors in general. The results are discussed in the context of current models of Env-mediated membrane fusion.     

Interactions of HIV-1 Inhibitory Peptide T20 with the gp41 N-HR Coiled Coil

Cellular entry of human immunodeficiency virus type 1 (HIV-1) involves fusion of viral and cellular membranes and is mediated by structural transitions in viral glycoprotein gp41. The antiviral C-peptide T20 targets the gp41 N-terminal heptad repeat region (N-HR), blocking gp41 conformational changes essential for the entry process. To probe the T20 structure-activity relationship, we engineered a molecular mimic of the entire gp41 N-HR coiled coil using the 5-Helix design strategy. T20 bound this artificial protein (denoted 5H-ex) with nanomolar affinity (K_D = 30 nm), close to its IC₅₀ concentration (∼3 nm) but much weaker than the affinity of a related inhibitory C-peptide C37 (K_D = 0.0007 nm). T20/C37 competitive binding assays confirmed that T20 interacts with the hydrophobic groove on the surface of the N-HR coiled coil outside of a deep pocket region crucial for C37 binding. We used 5H-ex to investigate how the T20 N and C termini contributed to the inhibitor binding activity. Mutating three aromatic residues at the T20 C terminus (WNWF → ANAA) had no effect on affinity, suggesting that these amino acids do not participate in T20 binding to the gp41 N-HR. The results support recent evidence pointing to a different role for these residues in T20 inhibition (Peisajovich, S. G., Gallo, S. A., Blumenthal, R., and Shai, Y. (2003) J. Biol. Chem. 278, 21012–21017; Liu, S., Jing, W., Cheung, B., Lu, H., Sun, J., Yan, X., Niu, J., Farmar, J., Wu, S., and Jiang, S. (2007) J. Biol. Chem. 282, 9612–9620). By contrast, mutations near the T20 N terminus substantially influenced inhibitor binding strength. When Ile was substituted for Thr in the second T20 position, a 40-fold increase in binding affinity was measured (K_D = 0.75 nm). The effect of this affinity enhancement on T20 inhibitory potency varied among different viral strains. The original T20 and the higher affinity T20 variant had similar potency against wild type HIV-1. However, the higher affinity T20 variant was significantly more potent against T20-resistant virus. The findings suggest that other factors in addition to binding affinity play a role in limiting T20 potency. As a mimetic of the complete gp41 N-HR coiled coil region, 5H-ex will be a useful tool to further elucidate mechanistic profiles of C-peptide inhibitors.The HIV-1² surface glycoprotein Env promotes viral entry through the fusion of viral and cellular membranes (3). Env consists of three gp120 surface subunits and three gp41 transmembrane subunits arranged as a trimer-of-heterodimers on the virion surface. In the current model of HIV-1 entry, cellular receptor binding to gp120 initiates a series of coordinated structural transformations that stimulate gp41 to extend and insert its N-terminal fusion peptide into target cell membranes (see Fig. 1A) (4, 5). This high energy extended intermediate structure ultimately collapses into a trimer-of-hairpins conformation that juxtaposes the gp41 fusion peptide and transmembrane domain. Because the fusion peptide and transmembrane domain are inserted in target cell and viral membranes, formation of the trimer-of-hairpins is proposed to bring these membranes into the close proximity required for efficient fusion.Open in a separate windowFIGURE 1.HIV-1 gp41 and its role in viral membrane fusion. A, a model of HIV-1 entry (46). In native Env prior to receptor activation, gp41 is held in a metastable conformation by a canopy of gp120 proteins (green). Receptor binding to gp120 stimulates gp41 to extend and insert its fusion peptide segment (red) into the target cell membrane. The N-HR (gray) and C-HR (blue) regions of the gp41 ectodomain are transiently exposed in this prehairpin state. Subsequently, gp41 collapses into the trimer-of-hairpins conformation that brings the gp41 fusion peptides, transmembrane regions (purple), and their associated membranes into the close proximity for membrane fusion. The actual disposition of gp120 in both the prehairpin and trimer-of-hairpins states is uncertain; for clarity, the protein is omitted in the schematic of the trimer-of-hairpins conformation. B, a diagram of HIV-1 gp41 identifying its fusion peptide (FP), N-HR, C-HR, MPER (MP), transmembrane (TM), and cytoplasmic (cyto) domains. Amino acid sequences above and below the diagram are derived from the N-HR and C-HR/MPER regions of Env_HXB2; all but the MPER sequence WNWF (magenta) were used in the design of 5H-ex. The N-HR and C-HR segments found in the original 5-Helix are boxed in gray and blue, respectively, whereas the sequences of C37 and T20 are denoted by lines. The side chains of the C-HR amino acids marked with + pack into the hydrophobic pocket at the C terminus of the N-HR coiled coil.The core of the trimer-of-hairpins is a bundle of six α-helices formed by two hydrophobic heptad repeat sequences in the N- and C-terminal regions of the gp41 ectodomain (N-HR and C-HR, respectively) (6, 7). In the trimer-of-hairpins, the N-HR segments from three gp41 ectodomains form a central trimeric coiled coil, around which the three C-HR segments pack as antiparallel helices into hydrophobic grooves (8–11). In the prehairpin extended conformation, the N-HR and C-HR segments are unassociated and transiently accessible to inhibitors of HIV-1 entry (5, 12). Several such inhibitors are formed from the peptide sequence of the C-HR and adjacent gp41 regions (4, 6, 13, 14). Denoted C-peptides, they work in a dominant negative fashion by binding to the exposed N-HR coiled coil, thereby blocking trimer-of-hairpins formation and inhibiting viral membrane fusion (4, 15–21). One C-peptide, T20 (also called enfuvirtide), has shown antiviral activity in vivo and has been approved for use in the treatment of HIV-1 infection (22, 23).T20 is a 36-amino acid peptide extending from Tyr⁶³⁸ in the middle of the C-HR to Phe⁶⁷³ in the Trp-rich membrane proximal external region (MPER) that precedes the gp41 transmembrane domain (residue numbering is according to the Env_HXB2 sequence; see Fig. 1B) (13). In T20, these C-terminal MPER-derived residues are critical for inhibitory activity, although their structure and function in the gp41-bound state are currently unknown (1, 24, 25). A second class of similarly potent C-peptides includes C34 (residues 628–661) and the slightly larger C37 (residues 625–661) (4, 6, 26, 27). These peptides are derived entirely from the C-HR sequence and thus are shifted in the N-terminal direction compared with T20 (Fig. 1B). The interactions of C34 and C37 with gp41 are greatly stabilized by residues Trp⁶²⁸, Trp⁶³¹, and Ile⁶³⁵ near the C-HR N terminus (4). Their bulky hydrophobic side chains pack into a deep hydrophobic pocket on the surface of the N-HR coiled coil. T20 lacks these pocket binding residues and their stabilizing effect. However, T20 does contain bulky hydrophobic residues (Trp⁶⁷⁰, Trp⁶⁷², and Phe⁶⁷³) at its C terminus that might pack into a similar pocket at the other end of the N-HR coiled coil.High resolution structures of the gp41 trimer-of-hairpins have aided our understanding of the mechanism of C-peptide inhibition. These structures have enabled the design of polypeptides that mimic the gp41 N-HR coiled coil and bind C34/C37, thereby providing a tool to probe the structure-activity relationships of the inhibitors (26, 28–30). No similar tool is available for investigating T20 inhibition in detail. The structures of the gp41 trimer-of-hairpins do not include the T20 C terminus (9 residues) nor the gp41 N-terminal segments that putatively interact with it. Furthermore, gp41 N-HR-derived peptides predicted to interact with T20 are poorly soluble and difficult to use in solution phase interaction assays (6). Here we describe the design of a soluble protein (denoted 5H-ex) that mimics the putative T20-binding site on the N-HR coiled coil. 5H-ex interacts with T20 with an equilibrium dissociation constant (K_D) of 30 nm, close to the T20 50% inhibitory concentration (IC₅₀) of 3 nm. Using this protein, we explored the extent to which the N and C termini of T20 contribute to its binding activity. First, we showed that the MPER-derived residues at the peptide C terminus do not stabilize the 5H-ex/T20 interaction. Second, we identified an N-terminal substitution that significantly enhanced T20 binding affinity and improved peptide inhibitory activity against T20-resistant HIV-1. The results suggest that T20 binding to the N-HR coiled coil is stabilized primarily by residues derived from the C-HR and not the MPER. 5H-ex is likely to be a useful tool in probing the structure-activity relationship of T20.     

Mutations conferring resistance to human immunodeficiency virus type 1 fusion inhibitors are restricted by gp41 and Rev-responsive element functions

One of the human immunodeficiency virus (HIV) envelope proteins, gp41, plays a key role in HIV fusion. A gp41-derived peptide, T-20, efficiently inhibits HIV fusion and is currently approved for treatment of HIV-infected individuals. Although resistant variants have been reported, the mechanism of the resistance remains to be defined. To elucidate the mechanism in detail, we generated variants resistant to C34, a peptide derived from the gp41 carboxyl terminus heptad repeat (C-HR) in vitro. The resistant variants had a 5-amino-acid deletion in gp120 and a total of seven amino acid substitutions in gp41. Binding assays revealed that an I37K substitution in the N-terminal heptad repeat (N-HR) impaired the binding of C34, whereas an N126K substitution in the C-HR enhanced the binding to mutated N-HR, indicating that both mutations were directly involved in resistance. On the other hand, substitutions for A30 and D36 seemed to be secondary mutations, located complementary to each other in the Rev-responsive element (RRE), and were mutated simultaneously to maintain the secondary structure of the RRE that was impaired by the mutations at I37. Thus, HIV acquired resistance to C34 by mutations in N-HR, which directly interacted with C34. However, since this region also encoded the RRE, additional mutations were required to maintain viral replication. These results suggest that HIV fusion is one of the attractive targets for HIV chemotherapy.     

Quaternary protein mimetics of gp41 elicit neutralizing antibodies against HIV fusion-active intermediate state

During viral entry, the fusogenic state of human immunodeficiency virus Type 1 (HIV-1) envelope protein gp41 is a quaternary structure consisting of three gp41 glycoproteins, each with two conserved helical domains (N-HR and C-HR). Thus far, the examination of monomeric gp41 peptides as an immunologically focused approach to vaccine design has not been successful. Here we report an approach using quaternary protein mimetics (called 3alpha mimetics) that are based on the gp41 N-HR and C-HR domains to closely mimic the fusogenic state and overcome the deficiencies of the monomeric peptide approach for synthetic vaccine design. The 3alpha mimetics are conveniently prepared by chemoselective ligation of unprotected monomeric peptides to an interstrand linker, and display enhanced conformational stability compared to the corresponding monomers. The 3alpha mimetics with or without a covalently attached T-helper epitope were immunogenic and elicited antisera that bound both recombinant gp160, which contains gp41, and HIV-1 virions and immunoprecipitated recombinant gp41. Anti-3alpha mimetic antisera neutralized viral infectivity against R5- and X4-tropic strains of HIV-1 at 31.5 degrees C. The results suggest that a quaternary protein approach to mimic conserved and functional domains of viral envelope proteins is desirable for HIV vaccine development as such antigens are more likely to produce immunologically-focused and broadly neutralizing antibody responses.     

HIV-1 gp41 fusogenic function triggers autophagy in uninfected cells

Cell-expressed HIV-1 envelope glycoproteins (gp120 and gp41, called Env) induce autophagy in uninfected CD4 T cells, leading to their apoptosis, a mechanism most likely contributing to immunodeficiency. The presence of CD4 and CXCR4 on target cells is required for this process, but Env-induced autophagy is independent of CD4 signaling. Here we demonstrate that CXCR4-mediated signaling pathways are not directly involved in autophagy and cell death triggering. Indeed, cells stably expressing mutated forms of CXCR4, unable to transduce different Gi-dependent and -independent signals, still undergo autophagy and cell death after coculture with effector cells expressing Env. After gp120 binding to CD4 and CXCR4, the N terminus fusion peptide (FP) of gp41 is inserted into the target membrane, and gp41 adopts a trimeric extended pre-hairpin intermediate conformation, target of HIV fusion inhibitors such as T20 and C34, before formation of a stable six-helix bundle structure and cell-to-cell fusion. Interestingly, Env-mediated autophagy is triggered in both single cells (hemifusion) and syncytia (complete fusion), and prevented by T20 and C34. The gp41 fusion activity is responsible for Env-mediated autophagy since the Val2Glu mutation in the gp41 FP totally blocks this process. On the contrary, deletion of the C-terminal part of gp41 enhances Env-induced autophagy. These results underline the major role of gp41 in inducing autophagy in the uninfected cells and indicate that the entire process leading to HIV entry into target cells through binding of Env to its receptors, CD4 and CXCR4, is responsible for autophagy and death in the uninfected, bystander cells.     

HIV-1 gp41 fusogenic function triggers autophagy in uninfected cells

Cell-expressed HIV-1 envelope glycoproteins (gp120 and gp41, called Env) induce autophagy in uninfected CD4 T cells, leading to their apoptosis, a mechanism most likely contributing to immunodeficiency. The presence of CD4 and CXCR4 on target cells is required for this process, but Env-induced autophagy is independent of CD4 signaling. Here, we demonstrate that CXCR4-mediated signaling pathways are not directly involved in autophagy and cell death triggering. Indeed, cells stably expressing mutated forms of CXCR4, unable to transduce different Gi-dependent and -independent signals, still undergo autophagy and cell death after coculture with effector cells expressing Env. After gp120 binding to CD4 and CXCR4, the N terminus fusion peptide (FP) of gp41 is inserted into the target membrane, and gp41 adopts a trimeric extended pre-hairpin intermediate conformation, target of HIV fusion inhibitors such as T20 and C34, before formation of a stable six-helix bundle structure and cell-to-cell fusion. Interestingly, Env-mediated autophagy is triggered in both single cells (hemifusion) and syncytia (complete fusion), and prevented by T20 and C34. The gp41 fusion activity is responsible for Env-mediated autophagy since the Val2Glu mutation in the gp41 FP totally blocks this process. On the contrary, deletion of the C-terminal part of gp41 enhances Env-induced autophagy. These results underline the major role of gp41 in inducing autophagy in the uninfected cells and indicate that the entire process leading to HIV entry into target cells through binding of Env to its receptors, CD4 and CXCR4, is responsible for autophagy and death in the uninfected, bystander cells.     

Three-dimensional structures of soluble CD4-bound states of trimeric simian immunodeficiency virus envelope glycoproteins determined by using cryo-electron tomography

The trimeric envelope glycoprotein (Env) spikes displayed on the surfaces of simian immunodeficiency virus (SIV) and human immunodeficiency virus type 1 (HIV-1) virions are composed of three heterodimers of the viral glycoproteins gp120 and gp41. Although binding of gp120 to cell surface CD4 and a chemokine receptor is known to elicit conformational changes in gp120 and gp41, changes in quaternary structure of the trimer have only recently been elucidated. For the HIV-1 BaL isolate, CD4 attachment results in a striking rearrangement of the trimer from a "closed" to an "open" conformation. The effect of CD4 on SIV trimers, however, has not been described. Using cryo-electron tomography, we have now determined molecular architectures of the soluble CD4 (sCD4)-bound states of SIV Env trimers for three different strains (SIVmneE11S, SIVmac239, and SIV CP-MAC). In marked contrast to HIV-1 BaL, SIVmneE11S and SIVmac239 Env showed only minor conformational changes following sCD4 binding. In SIV CP-MAC, where trimeric Env displays a constitutively "open" conformation similar to that seen for HIV-1 BaL Env in the sCD4-complexed state, we show that there are no significant further changes in conformation upon the binding of either sCD4 or 7D3 antibody. The density maps also show that 7D3 and 17b antibodies target epitopes on gp120 that are on opposites sides of the coreceptor binding site. These results provide new insights into the structural diversity of SIV Env and show that there are strain-dependent variations in the orientation of sCD4 bound to trimeric SIV Env.     

Asymmetric Deactivation of HIV-1 gp41 following Fusion Inhibitor Binding

Both equilibrium and nonequilibrium factors influence the efficacy of pharmaceutical agents that target intermediate states of biochemical reactions. We explored the intermediate state inhibition of gp41, part of the HIV-1 envelope glycoprotein complex (Env) that promotes viral entry through membrane fusion. This process involves a series of gp41 conformational changes coordinated by Env interactions with cellular CD4 and a chemokine receptor. In a kinetic window between CD4 binding and membrane fusion, the N- and C-terminal regions of the gp41 ectodomain become transiently susceptible to inhibitors that disrupt Env structural transitions. In this study, we sought to identify kinetic parameters that influence the antiviral potency of two such gp41 inhibitors, C37 and 5-Helix. Employing a series of C37 and 5-Helix variants, we investigated the physical properties of gp41 inhibition, including the ability of inhibitor-bound gp41 to recover its fusion activity once inhibitor was removed from solution. Our results indicated that antiviral activity critically depended upon irreversible deactivation of inhibitor-bound gp41. For C37, which targets the N-terminal region of the gp41 ectodomain, deactivation was a slow process that depended on chemokine receptor binding to Env. For 5-Helix, which targets the C-terminal region of the gp41 ectodomain, deactivation occurred rapidly following inhibitor binding and was independent of chemokine receptor levels. Due to this kinetic disparity, C37 inhibition was largely reversible, while 5-Helix inhibition was functionally irreversible. The fundamental difference in deactivation mechanism points to an unappreciated asymmetry in gp41 following inhibitor binding and impacts the development of improved fusion inhibitors and HIV-1 vaccines. The results also demonstrate how the activities of intermediate state inhibitors critically depend upon the final disposition of inhibitor-bound states.     

X-ray Crystallographic Study of an HIV-1 Fusion Inhibitor with the gp41 S138A Substitution

The S138A substitution of fusion inhibitory peptides derived from the C-terminal heptad repeat (C-HR) of the human immunodeficiency virus type 1 (HIV-1) gp41 leads to enhanced binding affinity to the N-terminal heptad repeat (N-HR). As such, these peptides exhibit highly potent anti-HIV-1 activity. X-ray crystallographic analysis was performed to understand the effect of the substitution on binding affinity. The comparison of the native and S138A crystal structures indicated that the increase in the hydrophobicity of the S138A substitution may aid the stabilization of the N-HR/C-HR complex through additional hydrophobic contacts. Free-energy calculations suggest that the difference between the desolvation free energies of the C-HR-derived peptides with and without the S138A mutation dominates the observed difference in anti-HIV-1 activity.     

Role of the fusion peptide and membrane-proximal domain in HIV-1 envelope glycoprotein-mediated membrane fusion

The N-terminal fusion peptide and the interfacial sequence preceding the transmembrane anchor of HIV-1 gp41 are required for viral fusion. Studies with synthetic peptides indicated that these regions function by destabilizing membranes, which is regarded as a crucial step in the membrane fusion reaction. However, it is not clear whether membrane destabilization is induced by these sequences in the intact gp41. We address this question by examining fusion and destabilization of membranes expressing HIV-1(IIIB) wild-type Env and two mutant Envs. (1) A Glu residue at position 2 of the gp41 fusion peptide is substituted for Val (V2E) to produce one mutant. (2) Residues 665-682 in the membrane-proximal domain are deleted to form the other. The process of membrane destabilization was monitored by the influx of Sytox, an impermeant fluorescent dye, into the Env-expressing cells following the interaction with CD4-CXCR4 complexes, and fusion was monitored by observing dye transfer between Env-expressing cells and appropriate target cells. We also monitored the conformational changes in the Envs following their interactions with CD4 and CXCR4 by immunofluorescence using an anti-gp41 mAb that reacts with the six-helix bundle. In contrast to the wild type, both Env mutants did not mediate cell fusion. The V2E Env did not mediate membrane destabilization. However, the Env with an unmodified fusion peptide but with a deletion of residues 665-682 in the membrane-proximal domain did mediate membrane destabilization. The wild type and both mutant Envs undergo conformational changes detected by the anti-gp41 six-helix bundle mAbs. Our results suggest that in intact HIV-1 Env the membrane-proximal domain is not required for membrane perturbations, but rather enables the bending of gp41 that is required for viral and target membranes to come together. Moreover, the observation that the Delta665-683 Env self-inserts its fusion peptide but does not cause fusion suggests that self-insertion of the fusion peptide is not sufficient for HIV-1 Env-mediated fusion.     

Stabilizing Exposure of Conserved Epitopes by Structure Guided Insertion of Disulfide Bond in HIV-1 Envelope Glycoprotein

Entry of HIV-1 into target cells requires binding of the viral envelope glycoprotein (Env) to cellular receptors and subsequent conformational changes that culminates in fusion of viral and target cell membranes. Recent structural information has revealed that these conformational transitions are regulated by three conserved but potentially flexible layers stacked between the receptor-binding domain (gp120) and the fusion arm (gp41) of Env. We hypothesized that artificial insertion of a covalent bond will ‘snap’ Env into a conformation that is less mobile and stably expose conserved sites. Therefore, we analyzed the interface between these gp120 layers (layers 1, 2 and 3) and identified residues that may form disulfide bonds when substituted with cysteines. We subsequently probed the structures of the resultant mutant gp120 proteins by assaying their binding to a variety of ligands using Surface Plasmon Resonance (SPR) assay. We found that a single disulfide bond strategically inserted between the highly conserved layers 1 and 2 (C65-C115) is able to ‘lock’ gp120 in a CD4 receptor bound conformation (in the absence of CD4), as indicated by the lower dissociation constant (Kd) for the CD4-induced (CD4i) epitope binding 17b antibody. When disulfide-stabilized monomeric (gp120) and trimeric (gp140) Envs were used to immunize rabbits, they were found to elicit a higher proportion of antibodies directed against both CD4i and CD4 binding site epitopes than the wild-type proteins. These results demonstrate that structure-guided stabilization of inter-layer interactions within HIV-1 Env can be used to expose conserved epitopes and potentially overcome the sequence diversity of these molecules.     

Structural Mechanism of Trimeric HIV-1 Envelope Glycoprotein Activation

HIV-1 infection begins with the binding of trimeric viral envelope glycoproteins (Env) to CD4 and a co-receptor on target T-cells. Understanding how these ligands influence the structure of Env is of fundamental interest for HIV vaccine development. Using cryo-electron microscopy, we describe the contrasting structural outcomes of trimeric Env binding to soluble CD4, to the broadly neutralizing, CD4-binding site antibodies VRC01, VRC03 and b12, or to the monoclonal antibody 17b, a co-receptor mimic. Binding of trimeric HIV-1 BaL Env to either soluble CD4 or 17b alone, is sufficient to trigger formation of the open quaternary conformation of Env. In contrast, VRC01 locks Env in the closed state, while b12 binding requires a partial opening in the quaternary structure of trimeric Env. Our results show that, despite general similarities in regions of the HIV-1 gp120 polypeptide that contact CD4, VRC01, VRC03 and b12, there are important differences in quaternary structures of the complexes these ligands form on native trimeric Env, and potentially explain differences in the neutralizing breadth and potency of antibodies with similar specificities. From cryo-electron microscopic analysis at ∼9 Å resolution of a cleaved, soluble version of trimeric Env, we show that a structural signature of the open Env conformation is a three-helix motif composed of α-helical segments derived from highly conserved, non-glycosylated N-terminal regions of the gp41 trimer. The three N-terminal gp41 helices in this novel, activated Env conformation are held apart by their interactions with the rest of Env, and are less compactly packed than in the post-fusion, six-helix bundle state. These findings suggest a new structural template for designing immunogens that can elicit antibodies targeting HIV at a vulnerable, pre-entry stage.     

Site-specific mutations in HIV-1 gp41 reveal a correlation between HIV-1-mediated bystander apoptosis and fusion/hemifusion

The loss of CD4(+) T cells in HIV-1 infections is hypothesized to be caused by apoptosis of bystander cells mediated by cell surface-expressed HIV-1 Env glycoprotein. However, the mechanism by which Env mediates this process remains controversial. Specifically, the role of HIV-1 gp120 binding to CD4 and CXCR4 versus the fusion process mediated by gp41 remains unresolved. Env-induced apoptosis in bystander cells has been shown to be gp41-dependent and correlates with the redistribution of membrane lipids between Env-expressing cells and target cells (hemifusion). Using a rational mutagenesis approach aimed at targeting Env function via the gp41 subunit, we examined the role of HIV gp41 in bystander apoptosis. A mutation in the fusion domain of gp41 (V513E) resulted in a fusion-defective Env that failed to induce apoptosis. A mutation in the gp41 N-terminal helix (G547D) reduced cell fusion capacity and apoptosis; conversely, an Env mutant with a deletion of the gp41 cytoplasmic tail (Ct Del) enhanced both cell-to-cell fusion and apoptosis. Most significantly, an Env mutant containing a substitution in the loop region of gp41 (D589L) mediated transfer of lipids (hemifusion) to bystander cells but was defective in cell-to-cell and to a lesser degree virus-to-cell fusion. This mutant was still able to induce apoptosis in bystander cells. Hence, we have provided the first direct evidence that gp41-mediated hemifusion is both required and sufficient for induction of apoptosis in bystander cells. These results may help to explain the mechanism of HIV-1 Env-induced T cell depletion.     

Antigenic properties of the human immunodeficiency virus transmembrane glycoprotein during cell-cell fusion

Human immunodeficiency virus (HIV) entry is triggered by interactions between a pair of heptad repeats in the gp41 ectodomain, which convert a prehairpin gp41 trimer into a fusogenic three-hairpin bundle. Here we examined the disposition and antigenic nature of these structures during the HIV-mediated fusion of HeLa cells expressing either HIV(HXB2) envelope (Env cells) or CXCR4 and CD4 (target cells). Cell-cell fusion, indicated by cytoplasmic dye transfer, was allowed to progress for various lengths of time and then arrested. Fusion intermediates were then examined for reactivity with various monoclonal antibodies (MAbs) against immunogenic cluster I and cluster II epitopes in the gp41 ectodomain. All of these MAbs produced similar staining patterns indicative of reactivity with prehairpin gp41 intermediates or related structures. MAb staining was seen on Env cells only upon exposure to soluble CD4, CD4-positive, coreceptor-negative cells, or stromal cell-derived factor-treated target cells. In the fusion system, the MAbs reacted with the interfaces of attached Env and target cells within 10 min of coculture. MAb reactivity colocalized with the formation of gp120-CD4-coreceptor tricomplexes after longer periods of coculture, although reactivity was absent on cells exhibiting cytoplasmic dye transfer. Notably, the MAbs were unable to inhibit fusion even when allowed to react with soluble-CD4-triggered or temperature-arrested antigens prior to initiation of the fusion process. In comparison, a broadly neutralizing antibody, 2F5, which recognizes gp41 antigens in the HIV envelope spike, was immunoreactive with free Env cells and Env-target cell clusters but not with fused cells. Notably, exposure of the 2F5 epitope required temperature-dependent elements of the HIV envelope structure, as MAb binding occurred only above 19 degrees C. Overall, these results demonstrate that immunogenic epitopes, both neutralizing and nonneutralizing, are accessible on gp41 antigens prior to membrane fusion. The 2F5 epitope appears to depend on temperature-dependent elements on prefusion antigens, whereas cluster I and cluster II epitopes are displayed by transient gp41 structures. Such findings have important implications for HIV vaccine approaches based on gp41 intermediates.     

Binding of HIV-1 gp41-Directed Neutralizing and Non-Neutralizing Fragment Antibody Binding Domain (Fab) and Single Chain Variable Fragment (ScFv) Antibodies to the Ectodomain of gp41 in the Pre-Hairpin and Six-Helix Bundle Conformations

We previously reported a series of antibodies, in fragment antigen binding domain (Fab) formats, selected from a human non-immune phage library, directed against the internal trimeric coiled-coil of the N-heptad repeat (N-HR) of HIV-1 gp41. Broadly neutralizing antibodies from that series bind to both the fully exposed N-HR trimer, representing the pre-hairpin intermediate state of gp41, and to partially-exposed N-HR helices within the context of the gp41 six-helix bundle. While the affinities of the Fabs for pre-hairpin intermediate mimetics vary by only 2 to 20-fold between neutralizing and non-neutralizing antibodies, differences in inhibition of viral entry exceed three orders of magnitude. Here we compare the binding of neutralizing (8066) and non-neutralizing (8062) antibodies, differing in only four positions within the CDR-H2 binding loop, in Fab and single chain variable fragment (ScFv) formats, to several pre-hairpin intermediate and six-helix bundle constructs of gp41. Residues 56 and 58 of the mini-antibodies are shown to be crucial for neutralization activity. There is a large differential (≥150-fold) in binding affinity between neutralizing and non-neutralizing antibodies to the six-helix bundle of gp41 and binding to the six-helix bundle does not involve displacement of the outer C-terminal helices of the bundle. The binding stoichiometry is one six-helix bundle to one Fab or three ScFvs. We postulate that neutralization by the 8066 antibody is achieved by binding to a continuum of states along the fusion pathway from the pre-hairpin intermediate all the way to the formation of the six-helix bundle, but prior to irreversible fusion between viral and cellular membranes.     

Filamin-A regulates actin-dependent clustering of HIV receptors

Human immunodeficiency virus (HIV)-1 infection requires envelope (Env) glycoprotein gp120-induced clustering of CD4 and coreceptors (CCR5 or CXCR4) on the cell surface; this enables Env gp41 activation and formation of a complex that mediates fusion between Env-containing and target-cell membranes. Kinetic studies show that viral receptors are actively transported to the Env-receptor interface in a process that depends on plasma membrane composition and the actin cytoskeleton. The mechanisms by which HIV-1 induces F-actin rearrangement in the target cell remain largely unknown. Here, we show that CD4 and the coreceptors interact with the actin-binding protein filamin-A, whose binding to HIV-1 receptors regulates their clustering on the cell surface. We found that gp120 binding to cell receptors induces transient cofilin-phosphorylation inactivation through a RhoA-ROCK-dependent mechanism. Blockade of filamin-A interaction with CD4 and/or coreceptors inhibits gp120-induced RhoA activation and cofilin inactivation. Our results thus identify filamin-A as an adaptor protein that links HIV-1 receptors to the actin cytoskeleton remodelling machinery, which may facilitate virus infection.