Transitions to and from the CD4-Bound Conformation Are Modulated by a Single-Residue Change in the Human Immunodeficiency Virus Type 1 gp120 Inner Domain

Binding to the primary receptor CD4 induces conformational changes in the human immunodeficiency virus type 1 (HIV-1) gp120 envelope glycoprotein that allow binding to the coreceptor (CCR5 or CXCR4) and ultimately trigger viral membrane-cell membrane fusion mediated by the gp41 transmembrane envelope glycoprotein. Here we report the derivation of an HIV-1 gp120 variant, H66N, that confers envelope glycoprotein resistance to temperature extremes. The H66N change decreases the spontaneous sampling of the CD4-bound conformation by the HIV-1 envelope glycoproteins, thus diminishing CD4-independent infection. The H66N change also stabilizes the HIV-1 envelope glycoprotein complex once the CD4-bound state is achieved, decreasing the probability of CD4-induced inactivation and revealing the enhancing effects of soluble CD4 binding on HIV-1 infection. In the CD4-bound conformation, the highly conserved histidine 66 is located between the receptor-binding and gp41-interactive surfaces of gp120. Thus, a single amino acid change in this strategically positioned gp120 inner domain residue influences the propensity of the HIV-1 envelope glycoproteins to negotiate conformational transitions to and from the CD4-bound state.Human immunodeficiency virus type 1 (HIV-1), the cause of AIDS (6, 29, 66), infects target cells by direct fusion of the viral and target cell membranes. The viral fusion complex is composed of gp120 and gp41 envelope glycoproteins, which are organized into trimeric spikes on the surface of the virus (10, 51, 89). Membrane fusion is initiated by direct binding of gp120 to the CD4 receptor on target cells (17, 41, 53). CD4 binding creates a second binding site on gp120 for the chemokine receptors CCR5 and CXCR4, which serve as coreceptors (3, 12, 19, 23, 25). Coreceptor binding is thought to lead to further conformational changes in the HIV-1 envelope glycoproteins that facilitate the fusion of viral and cell membranes. The formation of an energetically stable six-helix bundle by the gp41 ectodomain contributes to the membrane fusion event (9, 10, 79, 89, 90).The energy required for viral membrane-cell membrane fusion derives from the sequential transitions that the HIV-1 envelope glycoproteins undergo, from the high-energy unliganded state to the low-energy six-helix bundle. The graded transitions down this energetic slope are initially triggered by CD4 binding (17). The interaction of HIV-1 gp120 with CD4 is accompanied by an unusually large change in entropy, which is thought to indicate the introduction of order into the conformationally flexible unliganded gp120 glycoprotein (61). In the CD4-bound state, gp120 is capable of binding CCR5 with high affinity; moreover, CD4 binding alters the quaternary structure of the envelope glycoprotein complex, resulting in the exposure of gp41 ectodomain segments (27, 45, 77, 92). The stability of the intermediate state induced by CD4 binding depends upon several variables, including the virus (HIV-1 versus HIV-2/simian immunodeficiency virus [SIV]), the temperature, and the nature of the CD4 ligand (CD4 on a target cell membrane versus soluble forms of CD4 [sCD4]) (30, 73). For HIV-1 exposed to sCD4, if CCR5 binding occurs within a given period of time, progression along the entry pathway continues. If CCR5 binding is impeded or delayed, the CD4-bound envelope glycoprotein complex decays into inactive states (30). In extreme cases, the binding of sCD4 to the HIV-1 envelope glycoproteins induces the shedding of gp120 from the envelope glycoprotein trimer (31, 56, 58). Thus, sCD4 generally inhibits HIV-1 infection by triggering inactivation events, in addition to competing with CD4 anchored in the target cell membrane (63).HIV-1 isolates vary in sensitivity to sCD4, due in some cases to a low affinity of the envelope glycoprotein trimer for CD4 and in other cases to differences in propensity to undergo inactivating conformational transitions following CD4 binding (30). HIV-1 isolates that have been passaged extensively in T-cell lines (the tissue culture laboratory-adapted [TCLA] isolates) exhibit lower requirements for CD4 than primary HIV-1 isolates (16, 63, 82). TCLA viruses bind sCD4 efficiently and are generally sensitive to neutralization compared with primary HIV-1 isolates. Differences in sCD4 sensitivity between primary and TCLA HIV-1 strains have been mapped to the major variable loops (V1/V2 and V3) of the gp120 glycoprotein (34, 42, 62, 81). Sensitivity to sCD4 has been shown to be independent of envelope glycoprotein spike density or the intrinsic stability of the envelope glycoprotein complex (30, 35).In general, HIV-1 isolates are more sensitive to sCD4 neutralization than HIV-2 or SIV isolates (4, 14, 73). The relative resistance of SIV to sCD4 neutralization can in some cases be explained by a reduced affinity of the envelope glycoprotein trimer for sCD4 (57); however, at least some SIV isolates exhibit sCD4-induced activation of entry into CD4-negative, CCR5-expressing target cells that lasts for several hours after exposure to sCD4 (73). Thus, for some primate immunodeficiency virus envelope glycoproteins, activated intermediates in the CD4-bound conformation can be quite stable.The HIV-1 envelope glycoprotein elements important for receptor binding, subunit interaction, and membrane fusion are well conserved among different viral strains (71, 91). Thus, these elements represent potential targets for inhibitors of HIV-1 entry. Understanding the structure and longevity of the envelope glycoprotein intermediates along the virus entry pathway is relevant to attempts at inhibition. For example, peptides that target the heptad repeat 1 region of gp41 exhibit major differences in potency against HIV-1 strains related to efficiency of chemokine receptor binding (20, 21), which is thought to promote the conformational transition to the next step in the virus entry cascade. The determinants of the duration of exposure of targetable HIV-1 envelope glycoprotein elements during the entry process are undefined.To study envelope glycoprotein determinants of the movement among the distinct conformational states along the HIV-1 entry pathway, we attempted to generate HIV-1 variants that exhibit improved stability. Historically, labile viral elements have been stabilized by selecting virus to replicate under conditions, such as high temperature, that typically weaken protein-protein interactions (38, 39, 76, 102). Thus, we subjected HIV-1 to repeated incubations at temperatures between 42°C and 56°C, followed by expansion and analysis of the remaining replication-competent virus fraction. In this manner, we identified an envelope glycoprotein variant, H66N, in which histidine 66 in the gp120 N-terminal segment was altered to asparagine. The resistance of HIV-1 bearing the H66N envelope glycoproteins to changes in temperature has been reported elsewhere (37). Here, we examine the effect of the H66N change on the ability of the HIV-1 envelope glycoproteins to negotiate conformational transitions, either spontaneously or in the presence of sCD4. The H66N phenotype was studied in the context of both CD4-dependent and CD4-independent HIV-1 variants.     

A V3 Loop-Dependent gp120 Element Disrupted by CD4 Binding Stabilizes the Human Immunodeficiency Virus Envelope Glycoprotein Trimer

Human immunodeficiency virus (HIV-1) entry into cells is mediated by a trimeric complex consisting of noncovalently associated gp120 (exterior) and gp41 (transmembrane) envelope glycoproteins. The binding of gp120 to receptors on the target cell alters the gp120-gp41 relationship and activates the membrane-fusing capacity of gp41. Interaction of gp120 with the primary receptor, CD4, results in the exposure of the gp120 third variable (V3) loop, which contributes to binding the CCR5 or CXCR4 chemokine receptors. We show here that insertions in the V3 stem or polar substitutions in a conserved hydrophobic patch near the V3 tip result in decreased gp120-gp41 association (in the unliganded state) and decreased chemokine receptor binding (in the CD4-bound state). Subunit association and syncytium-forming ability of the envelope glycoproteins from primary HIV-1 isolates were disrupted more by V3 changes than those of laboratory-adapted HIV-1 envelope glycoproteins. Changes in the gp120 β2, β19, β20, and β21 strands, which evidence suggests are proximal to the V3 loop in unliganded gp120, also resulted in decreased gp120-gp41 association. Thus, a gp120 element composed of the V3 loop and adjacent beta strands contributes to quaternary interactions that stabilize the unliganded trimer. CD4 binding dismantles this element, altering the gp120-gp41 relationship and rendering the hydrophobic patch in the V3 tip available for chemokine receptor binding.The entry of human immunodeficiency virus type 1 (HIV-1) is mediated by the viral envelope glycoproteins (9, 79). The HIV-1 envelope glycoproteins are synthesized as an ∼850-amino acid precursor, which trimerizes and is posttranslationally modified by carbohydrates to create a 160-kDa glycoprotein (gp160). The gp160 envelope glycoprotein precursor is proteolytically processed in the Golgi apparatus, resulting in a gp120 exterior envelope glycoprotein and a gp41 transmembrane envelope glycoprotein (16, 17, 66, 76). In the mature HIV-1 envelope glycoprotein trimer, the three gp120 subunits are noncovalently bound to three membrane-anchored gp41 subunits (32).HIV-1 entry involves the binding of gp120 in a sequential fashion to CD4 and one of the chemokine receptors, CCR5 or CXCR4 (1, 8, 15, 18, 25, 36). CD4 binding triggers the formation of an activated intermediate that is competent for binding to CCR5 or CXCR4 (29, 69, 73, 78). These chemokine receptors are G protein-coupled, 7-transmembrane segment receptors with relatively short N termini. The choice of chemokine receptors is dictated primarily by the sequence of a gp120 region, the third variable (V3) loop, that exhibits variability among HIV-1 strains and becomes exposed upon CD4 binding (4, 8, 10, 33, 37, 38, 49, 59, 75). X-ray crystal structures of CD4-bound HIV-1 gp120 have revealed that the gp120 “core” consists of a gp41-interactive inner domain, a surface-exposed and heavily glycosylated outer domain, and a conformationally flexible bridging sheet (38, 43, 79). In the CD4-bound state, the V3 loop projects 30 Å from the gp120 core, toward the chemokine receptor (38). The V3 loop in these structures consists of three elements: (i) conserved antiparallel β strands that contain a disulfide bond at the base of the loop; (ii) a conformationally flexible stem; and (iii) a conserved tip (37, 38). During the virus entry process, the base of the gp120 V3 loop and elements of the bridging sheet interact with the CCR5 N terminus, which is acidic and contains sulfotyrosine residues (12-14, 23, 24). Sulfotyrosine 14 of CCR5 is thought to insert into a highly conserved pocket near the V3 base, driving further conformational rearrangements that result in the rigidification of the V3 stem (37). The conserved β-turn at the tip of the V3 loop, along with some residues in the V3 stem, is believed to bind the “body” of CCR5, i.e., the extracellular loops and membrane-spanning helices. CCR5 binding is thought to induce further conformational changes in the HIV-1 envelope glycoproteins, leading to the fusion of the viral and target cell membranes by the gp41 transmembrane envelope glycoproteins.CCR5 binding involves two points of contact with the gp120 V3 loop: (i) the CCR5 N terminus with the V3 base and (ii) the CCR5 body with the V3 tip and distal stem (12-14, 23, 24, 37, 38). The intervening V3 stem can tolerate greater conformational and sequence variation, features that might decrease HIV-1 susceptibility to host antibodies (30). Despite amino acid variation, the length of the V3 loop is well conserved among naturally occurring group M (major group) HIV-1 strains (30, 42). This conserved length may be important for aligning the two CCR5-binding elements of the V3 loop. In addition to allowing optimal CCR5 binding, the conserved V3 length and orientation may be important for CCR5 binding to exert effects on the conformation of the HIV-1 envelope glycoproteins. We examine here the consequences of introducing extra amino acid residues into the V3 stem. The residues were introduced either into both strands of the V3 loop, attempting to preserve the symmetry of the structure, or into one of the strands, thereby kinking the loop. The effects of these changes on assembly, stability, receptor binding, and the membrane-fusing capacity of the HIV-1 envelope glycoproteins were assessed. In addition to effects on chemokine receptor binding, unexpected disruption of gp120-gp41 association was observed. Further investigation revealed a conserved patch in the tip of the V3 loop that is important for the association of gp120 with the trimeric envelope glycoprotein complex, as well as for chemokine receptor binding. Apparently, the V3 loop and adjacent gp120 structures contribute to the stability of the trimer in the unliganded HIV-1 envelope glycoproteins. These structures are known to undergo rearrangement upon CD4 binding, suggesting their involvement in receptor-induced changes in the virus entry process.     

Sequence Flexibility in the Polytropic env gp70-Derived Region of the Membrane Glycoprotein (gp55) of Friend Spleen Focus-Forming Virus Affects Its Biological Activity

We previously reported (N. Watanabe, M. Nishi, Y. Ikawa, and H. Amanuma, J. Virol. 65:132–137, 1991) that the mutant Friend spleen focus-forming virus (F-SFFV_MS), which encodes a mutant gp55 membrane glycoprotein with an ecotropic env gp70 sequence, was nonpathogenic. Here we injected the F-SFFV_MS–Friend murine leukemia virus (F-MuLV) clone 57 complex into newborn DBA/2 mice. We obtained four groups of pathogenic variant F-SFFV complexes, each showing a different degree of pathogenicity in adult mice and a different gp55 profile. Of these, group 1 variant F-SFFV was particularly interesting, because it was the most frequently obtained and because it produced doublet bands of gp55 (59 and 57 kDa), neither of which reacted with the nonecotropic gp70-specific monoclonal antibody, and because its DNA intermediate did not hybridize with the nonecotropic env-specific probe. Cloning and DNA sequence analysis of the env region of one isolate of the group 1 variant F-SFFV revealed that this virus consisted of two distinct F-SFFV genomes; one (clone 117) differed from the other (clone 118) due to the presence of a 39-bp in-frame deletion. Reconstitution to full-length F-SFFV genomes and a pathogenicity assay showed that each reconstituted F-SFFV was pathogenic, with clone 117 showing a higher degree of pathogenicity than clone 118. Both reconstituted F-SFFVs caused activation of the mouse erythropoietin receptor in the factor-independent cell proliferation assay, although much less efficiently than the wild-type polycythemia-inducing isolate F-SFFVp. Clone 118 produced a gp55 of 59 kDa, while clone 117 produced one of 57 kDa. Clone 118 had a substitution by the F-MuLV clone 57 gp70 sequence, indicating that it was derived from the F-SFFV_MS env gene by a homologous recombination with the F-MuLV clone 57 env gene. The site of the 39-bp deletion in clone 117 corresponded to the portion of the clone 118 sequence which was unique to the ecotropic env genes. These results indicated the importance for the biological activity of gp55 of the sequences in the gp70 differential region, which are contained in both polytropic and ecotropic env genes.Friend spleen focus-forming virus (F-SFFV), a replication-defective mouse type C retrovirus contained in the Friend virus complex, causes an acute erythroleukemia in adult mice of susceptible strains in the presence of a helper virus, such as the replication-competent Friend murine leukemia virus (F-MuLV) (reviewed in references 8 and 23). F-SFFV does not encode a viral oncogene, but its defective env gene product, gp55, plays a critical role in inducing the disease. In vitro biochemical evidence demonstrated that gp55, a membrane glycoprotein encoded by the polycythemia-inducing isolate of F-SFFV (F-SFFVp), specifically binds to a mouse erythropoietin receptor (EPO-R) and activates it, causing mitogenic signal transduction in the absence of the natural ligand erythropoietin (EPO) (12). Since the EPO-R is expressed in the erythroid progenitor cells, and the interaction between EPO and EPO-R regulates the level of erythropoiesis (15), it is assumed that the continuous expression of F-SFFV gp55 results in an abnormal proliferation of these cells, leading to leukemic transformation after several additional cytogenetic changes (3).gp55, although closely related to the Env protein of MuLV, is not incorporated into the retrovirus particles, but stays inside the cells, mainly in the rough endoplasmic reticulum membrane, with a small fraction of the molecules (3 to 5%) processed through the Golgi apparatus to the cytoplasmic membrane (6, 21, 24). Cell surface-localized gp55 is then shed from the cells, probably after proteolytic cleavage from the transmembrane domain (6, 20, 21).There are three major differences between the primary structures of gp55 of F-SFFVp and the Env protein of ecotropic MuLV (1, 4, 31). These are, from the N terminus, a substitution by the polytropic (dualtropic) env gp70 sequence, a 585-bp deletion which eliminates the proteolytic cleavage site for gp70 and p15E, and a 6-bp duplication and a single base insertion which cause premature termination of translation and loss of a 34-amino-acid peptide at the C terminus. By constructing F-SFFV encoding a mutant gp55, analyzing its pathogenicity in vivo, and also obtaining spontaneous revertant F-SFFVs from the mutant F-SFFV, we demonstrated that each of these three structural differences is essential for the pathogenicity of gp55 (2, 27–29). We previously reported (28) that the constructed F-SFFV (F-SFFV_MS) encoding the mutant gp55, in which the polytropic gp70 sequence had been replaced by the ecotropic F-MuLV clone K-1 gp70 sequence, was nonpathogenic in adult mice. The polytropic gp70-derived sequence in gp55 appears to contain a binding site for EPO-R (32). The purpose of the present study was to obtain spontaneous revertants from mice neonatally injected with F-SFFV_MS and to analyze the structure of their gp55s, with the goal of pinpointing the sequence required for pathogenicity and activation of EPO-R. The results indicated the importance of the sequences in the gp70 differential region, which are contained in both polytropic and ecotropic env genes.     

gp340 Promotes Transcytosis of Human Immunodeficiency Virus Type 1 in Genital Tract-Derived Cell Lines and Primary Endocervical Tissue

The human scavenger receptor gp340 has been identified as a binding protein for the human immunodeficiency virus type 1 (HIV-1) envelope that is expressed on the cell surface of female genital tract epithelial cells. This interaction allows such epithelial cells to efficiently transmit infective virus to susceptible targets and maintain viral infectivity for several days. Within the context of vaginal transmission, HIV must first traverse a normally protective mucosa containing a cell barrier to reach the underlying T cells and dendritic cells, which propagate and spread the infection. The mechanism by which HIV-1 can bypass an otherwise healthy cellular barrier remains an important area of study. Here, we demonstrate that genital tract-derived cell lines and primary human endocervical tissue can support direct transcytosis of cell-free virus from the apical to basolateral surfaces. Further, this transport of virus can be blocked through the addition of antibodies or peptides that directly block the interaction of gp340 with the HIV-1 envelope, if added prior to viral pulsing on the apical side of the cell or tissue barrier. Our data support a role for the previously described heparan sulfate moieties in mediating this transcytosis but add gp340 as an important facilitator of HIV-1 transcytosis across genital tract tissue. This study demonstrates that HIV-1 actively traverses the protective barriers of the human genital tract and presents a second mechanism whereby gp340 can promote heterosexual transmission.Through correlative studies with macaques challenged with simian immunodeficiency virus (SIV), the initial targets of infection in nontraumatic vaginal exposure to human immunodeficiency virus type 1 (HIV-1) have been identified as subepithelial T cells and dendritic cells (DCs) (18, 23, 31, 36-38). While human transmission may differ from macaque transmission, the existing models of human transmission remain controversial. For the virus to successfully reach its CD4⁺ targets, HIV must first traverse the columnar mucosal epithelial cell barrier of the endocervix or uterus or the stratified squamous barrier of the vagina or ectocervix, whose normal functions include protection of underlying tissue from pathogens. This portion of the human innate immune defense system represents a significant impediment to transmission. Studies have placed the natural transmission rate of HIV per sexual act between 0.005 and 0.3% (17, 45). Breaks in the epithelial barrier caused by secondary infection with other sexual transmitted diseases or the normal physical trauma often associated with vaginal intercourse represent one potential means for viral exposure to submucosal cells and have been shown to significantly increase transmission (reviewed in reference 11). However, studies of nontraumatic exposure to SIV in macaques demonstrate that these disruptions are not necessary for successful transmission to healthy females. This disparity indicates that multiple mechanisms by which HIV-1 can pass through mucosal epithelium might exist in vivo. Identifying these mechanisms represents an important obstacle to understanding and ultimately preventing HIV transmission.Several host cellular receptors, including DC-specific intercellular adhesion molecule-grabbing integrin, galactosyl ceramide, mannose receptor, langerin, heparan sulfate proteoglycans (HSPGs), and chondroitin sulfate proteoglycans, have been identified that facilitate disease progression through binding of HIV virions without being required for fusion and infection (2, 3, 12, 14, 16, 25, 29, 30, 43, 46, 50). These host accessory proteins act predominately through glycosylation-based interactions between HIV envelope (Env) and the host cellular receptors. These different host accessory factors can lead to increased infectivity in cis and trans or can serve to concentrate and expose virus at sites relevant to furthering its spread within the body. The direct transcytosis of cell-free virus through primary genital epithelial cells and the human endometrial carcinoma cell line HEC1A has been described (7, 9); this is, in part, mediated by HSPGs (7). Within the HSPG family, the syndecans have been previously shown to facilitate trans infection of HIV in vitro through binding of a specific region of Env that is moderately conserved (7, 8). This report also demonstrates that while HSPGs mediate a portion of the viral transcytosis that occurs in these two cell types, a significant portion of the observed transport occurs through an HSPG-independent mechanism. Other host cell factors likely provide alternatives to HSPGs for HIV-1 to use in subverting the mucosal epithelial barrier.gp340 is a member of the scavenger receptor cysteine-rich (SRCR) family of innate immune receptors. Its numerous splice variants can be found as a secreted component of human saliva (34, 41, 42) and as a membrane-associated receptor in a large number of epithelial cell lineages (22, 32, 40). Its normal cellular function includes immune surveillance of bacteria (4-6, 44), interaction with influenza A virus (19, 20, 32, 51) and surfactant proteins in the lung (20, 22, 33), and facilitating epithelial cell regeneration at sites of cellular inflammation and damage (27, 32). The secreted form of gp340, salivary agglutinin (SAG), was identified as a component of saliva that inhibits HIV-1 transmission in the oral pharynx through a specific interaction with the viral envelope protein that serves to agglutinate the virus and target it for degradation (34, 35, 41). Interestingly, SAG was demonstrated to form a direct protein-protein interaction with HIV Env (53, 54). Later, a cell surface-associated variant of SAG called gp340 was characterized as a binding partner for HIV-1 in the female genital tract that could facilitate virus transmission to susceptible targets of infection (47) and as a macrophage-expressed enhancer of infection (10).     

Breadth of Neutralizing Antibodies Elicited by Stable,Homogeneous Clade A and Clade C HIV-1 gp140 Envelope Trimers in Guinea Pigs

The native envelope (Env) spike on the surface of human immunodeficiency virus type 1 (HIV-1) is trimeric, and thus trimeric Env vaccine immunogens are currently being explored in preclinical immunogenicity studies. Key challenges have included the production and purification of biochemically homogeneous and stable trimers and the evaluation of these immunogens utilizing standardized virus panels for neutralization assays. Here we report the binding and neutralizing antibody (NAb) responses elicited by clade A (92UG037.8) and clade C (CZA97.012) Env gp140 trimer immunogens in guinea pigs. These trimers have been selected and engineered for optimal biochemical stability and have defined antigenic properties. Purified gp140 trimers with Ribi adjuvant elicited potent, cross-clade NAb responses against tier 1 viruses as well as detectable but low-titer NAb responses against select tier 2 viruses from clades A, B, and C. In particular, the clade C trimer elicited NAbs that neutralized 27%, 20%, and 47% of tier 2 viruses from clades A, B, and C, respectively. Heterologous DNA prime, protein boost as well as DNA prime, recombinant adenovirus boost regimens expressing these antigens, however, did not result in an increased magnitude or breadth of NAb responses in this system. These data demonstrate the immunogenicity of stable, homogeneous clade A and clade C gp140 trimers and exemplify the utility of standardized tier 1 and tier 2 virus panels for assessing the NAb responses of candidate HIV-1 Env immunogens.The development and evaluation of novel HIV-1 Env immunogens are critical priorities of the HIV-1 vaccine field (2, 10, 25). The major antigenic target for neutralizing antibodies (NAbs) is the trimeric Env glycoprotein on the virion surface (4, 18, 30). Monomeric gp120 immunogens have not elicited broadly reactive NAbs in animal models (5, 13, 28, 29) or humans (16, 31), and thus several groups have focused on generating trimer immunogens that better mimic the native Env spike found on virions (3, 7, 14, 15, 20, 22, 27). It has, however, proven difficult to produce stable and conformationally homogeneous Env trimers. Strategies to modify Env immunogens have therefore been explored, including the removal of the cleavage site between gp120 and gp41 (3, 7, 23, 39, 40), the incorporation of an intramolecular disulfide bond to stabilize cleaved gp120 and gp41 moieties (6), and the addition of trimerization motifs such as the T4 bacteriophage fibritin “fold-on” (Fd) domain (8, 17, 39).Preclinical evaluation of candidate Env immunogens is critical for concept testing and for the prioritization of vaccine candidates. Luciferase-based virus neutralization assays with TZM.bl cells (21, 24) have been developed as high-throughput assays that can be standardized (26). However, the optimal use of this assay requires the generation of standardized virus panels derived from multiple clades that reflect both easy-to-neutralize (tier 1) and primary isolate (tier 2) viruses (21, 24). A tiered approach for the evaluation of novel Env immunogens has been proposed, in which tier 1 viruses represent homologous vaccine strains and a small number of heterologous neutralization-sensitive viruses while tier 2 viruses provide a greater measure of neutralization breadth for the purpose of comparing immunogens (24).We screened a large panel of primary HIV-1 isolates for Env stability and identified two viruses, CZA97.012 (clade C) (32) and 92UG037.8 (clade A) (17), that yielded biochemically homogeneous and stable Env trimers with well defined and uniform antigenic properties (17). The addition of the T4 bacteriophage fibritin “fold-on” (Fd) trimerization domain further increased their yield and purity (17). In the present study, we assessed the immunogenicity of these stable clade A and clade C gp140 trimers in guinea pigs. Both trimers elicited high-titer binding antibody responses and cross-clade neutralization of select tier 1 viruses as well as low-titer but detectable NAb responses against select tier 2 viruses from clades A, B, and C. These data demonstrate the immunogenicity of these stable gp140 trimers and highlight the utility of standardized virus panels in the evaluation of novel HIV-1 Env immunogens.     

Caveolin-1 Modulates HIV-1 Envelope-Induced Bystander Apoptosis through gp41

Human immunodeficiency virus (HIV) envelope (Env)-mediated bystander apoptosis is known to cause the progressive, severe, and irreversible loss of CD4⁺ T cells in HIV-1-infected patients. Env-induced bystander apoptosis has been shown to be gp41 dependent and related to the membrane hemifusion between envelope-expressing cells and target cells. Caveolin-1 (Cav-1), the scaffold protein of specific membrane lipid rafts called caveolae, has been reported to interact with gp41. However, the underlying pathological or physiological meaning of this robust interaction remains unclear. In this report, we examine the interaction of cellular Cav-1 and HIV gp41 within the lipid rafts and show that Cav-1 modulates Env-induced bystander apoptosis through interactions with gp41 in SupT1 cells and CD4⁺ T lymphocytes isolated from human peripheral blood. Cav-1 significantly suppressed Env-induced membrane hemifusion and caspase-3 activation and augmented Hsp70 upregulation. Moreover, a peptide containing the Cav-1 scaffold domain sequence markedly inhibited bystander apoptosis and apoptotic signal pathways. Our studies shed new light on the potential role of Cav-1 in limiting HIV pathogenesis and the development of a novel therapeutic strategy in treating HIV-1-infected patients.HIV infection causes a progressive, severe, and irreversible depletion of CD4⁺ T cells, which is responsible for the development of AIDS (9). The mechanism through which HIV infection induces cell death involves a variety of processes (58). Among these processes, apoptosis is most likely responsible for T-cell destruction in HIV-infected patients (33), because active antiretroviral therapy has been associated with low levels of CD4⁺ T-cell apoptosis (7), and AIDS progression was shown previously to correlate with the extent of immune cell apoptosis (34). Importantly, bystander apoptosis of uninfected cells was demonstrated to be one of the major processes involved in the destruction of immune cells (58), with the majority of apoptotic CD4⁺ T cells in the peripheral blood and lymph nodes being uninfected in HIV patients (22).Binding to uninfected cells or the entry of viral proteins released by infected cells is responsible for the virus-mediated killing of innocent-bystander CD4⁺ T cells (2-4, 9, 65). The HIV envelope glycoprotein complex, consisting of gp120 and gp41 subunits expressed on an HIV-infected cell membrane (73), is believed to induce bystander CD4⁺ T-cell apoptosis (58). Although there is a soluble form of gp120 in the blood, there is no conclusive agreement as to whether the concentration is sufficient to trigger apoptosis (57, 58). The initial step in HIV infection is mediated by the Env glycoprotein gp120 binding with high affinity to CD4, the primary receptor on the target cell surface, which is followed by interactions with the chemokine receptor CCR5 or CXCR4 (61). This interaction triggers a conformational change in gp41 and the insertion of its N-terminal fusion peptide into the target membrane (30). Next, a prehairpin structure containing leucine zipper-like motifs is formed by the two conserved coiled-coil domains, called the N-terminal and C-terminal heptad repeats (28, 66, 70). This structure quickly collapses into a highly stable six-helix bundle structure with an N-terminal heptad repeat inside and a hydrophobic C-terminal heptad repeat outside (28, 66, 70). The formation of the six-helix bundle leads to a juxtaposition and fusion with the target cell membrane (28, 66, 70). The fusogenic potential of HIV Env is proven to correlate with the pathogenesis of both CXCR4- and CCR5-tropic viruses by not only delivering the viral genome to uninfected cells but also mediating Env-induced bystander apoptosis (71). Initial infection is dominated by the CCR5-tropic strains, with the CXCR4-tropic viruses emerging in the later stages of disease (20). Studies have shown that CXCR4-tropic HIV-1 triggers more depletion of CD4⁺ T cells than CCR5-tropic strains (36).Glycolipid- and cholesterol-enriched membrane microdomains, termed lipid rafts, are spatially organized plasma membranes and are known to have many diverse functions (26, 53). These functions include membrane trafficking, endocytosis, the regulation of cholesterol and calcium homeostasis, and signal transduction in cellular growth and apoptosis. Lipid rafts have also been implicated in HIV cell entry and budding processes (19, 46, 48, 51). One such organelle is the caveola, which is a small, flask-shaped (50 to 100 nm in diameter) invagination in the plasma membrane (5, 62). The caveola structure, which is composed of proteins known as caveolins, plays a role in various functions by serving as a mobile platform for many receptors and signal proteins (5, 62). Caveolin-1 (Cav-1) is a 22- to 24-kDa major coat protein responsible for caveola assembly (25, 47). This scaffolding protein forms a hairpin-like structure and exists as an oligomeric complex of 14 to 16 monomers (21). Cav-1 has been shown to be expressed by a variety of cell types, mostly endothelial cells, type I pneumocytes, fibroblasts, and adipocytes (5, 62). In addition, Cav-1 expression is evident in immune cells such as macrophages and dendritic cells (38, 39). However, Cav-1 is not expressed in isolated thymocytes (49). Furthermore, Cav-1 and caveolar structures are absent in human or murine T-cell lines (27, 41, 68). Contrary to this, there has been one report showing evidence of Cav-1 expression in bovine primary cell subpopulations of CD4⁺, CD8⁺, CD21⁺, and IgM⁺ cells with Cav-1 localized predominantly in the perinuclear region (38). That report also demonstrated a membrane region staining with Cav-1-specific antibody of human CD21⁺ and CD26⁺ peripheral blood lymphocytes (PBLs). Recently, the expression of Cav-1 in activated murine B cells, with a potential role in the development of a thymus-independent immune response, was also reported (56). It remains to be determined whether Cav-1 expression is dependent on the activation state of lymphocytes. For macrophages, however, which are one of the main cell targets for HIV infection, Cav-1 expression has been clearly documented (38).The scaffolding domain of Cav-1, located in the juxtamembranous region of the N terminus, is responsible for its oligomerization and binding to various proteins (5, 62, 64). It recognizes a consensus binding motif, ΦXΦXXXXΦ, ΦXXXXΦXXΦ, or ΦXΦXXXXΦXXΦ, where Φ indicates an aromatic residue (F, W, or Y) and X indicates any residue (5, 62, 64). A Cav-1 binding motif (WNNMTWMQW) has been identified in the HIV-1 envelope protein gp41 (42, 43). Cav-1 has been shown to associate with gp41 by many different groups under various circumstances, including the immunoprecipitation of gp41 and Cav-1 in HIV-infected cells (42, 43, 52). However, the underlying pathological or physiological functions of this robust interaction between Cav-1 and gp41 remain unclear.Here, we report that the interaction between Cav-1 and gp41 leads to a modification of gp41 function, which subsequently regulates Env-induced T-cell bystander apoptosis. Moreover, we show that a peptide containing the Cav-1 scaffold domain sequence is capable of modulating Env-induced bystander apoptosis, which suggests a novel therapeutic application for HIV-1-infected patients.     

Fundamental Difference in the Content of High-Mannose Carbohydrate in the HIV-1 and HIV-2 Lineages

The virus-encoded envelope proteins of human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV) typically contain 26 to 30 sites for N-linked carbohydrate attachment. N-linked carbohydrate can be of three major types: high mannose, complex, or hybrid. The lectin proteins from Galanthus nivalis (GNA) and Hippeastrum hybrid (HHA), which specifically bind high-mannose carbohydrate, were found to potently inhibit the replication of a pathogenic cloned SIV from rhesus macaques, SIVmac239. Passage of SIVmac239 in the presence of escalating concentrations of GNA and HHA yielded a lectin-resistant virus population that uniformly eliminated three sites (of 26 total) for N-linked carbohydrate attachment (Asn-X-Ser or Asn-X-Thr) in the envelope protein. Two of these sites were in the gp120 surface subunit of the envelope protein (Asn244 and Asn460), and one site was in the envelope gp41 transmembrane protein (Asn625). Maximal resistance to GNA and HHA in a spreading infection was conferred to cloned variants that lacked all three sites in combination. Variant SIV gp120s exhibited dramatically decreased capacity for binding GNA compared to SIVmac239 gp120 in an enzyme-linked immunosorbent assay (ELISA). Purified gp120s from six independent HIV type 1 (HIV-1) isolates and two SIV isolates from chimpanzees (SIVcpz) consistently bound GNA in ELISA at 3- to 10-fold-higher levels than gp120s from five SIV isolates from rhesus macaques or sooty mangabeys (SIVmac/sm) and four HIV-2 isolates. Thus, our data indicate that characteristic high-mannose carbohydrate contents have been retained in the cross-species transmission lineages for SIVcpz-HIV-1 (high), SIVsm-SIVmac (low), and SIVsm-HIV-2 (low).The envelope proteins of human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV) are heavily glycosylated. N-linked carbohydrate is attached to the nascent protein at the asparagine of the consensus sequence N-X-S or N-X-T, where X is any amino acid except a proline (31, 52, 53). The number of potential N-linked carbohydrate attachment sites in the surface subunit of Env (gp120) ranges from 18 to 33, with a median of 25 (34, 65). There are typically 3 or 4 potential N-linked sites in the ectodomain of the Env transmembrane protein (gp41) (34).N-linked glycosylation of a protein consists of the en bloc transfer of the carbohydrate core oligosaccharide (two N-acetylglucosamines, nine mannoses, and three glucoses) from dolichol to the asparagine of the N-linked attachment site (8, 60). Initially the attached carbohydrate is processed into the high-mannose type (8). In the Golgi complex, high-mannose carbohydrate may be further processed into complex or hybrid oligosaccharides (58). Incomplete processing of N-linked carbohydrate results in the production of high-mannose carbohydrate chains, which terminate in mannose (58). Fully processed complex carbohydrate chains terminate in galactose, N-acetylglucosamine, sialic acid, or glucose (33, 57). Hybrid carbohydrate chains have two branches from the core, one that terminates in mannose and one that terminates in a sugar of the complex type (63).Glycoproteins exist as a heterogeneous population, exhibiting heterogeneity with respect to the proportion of potential glycosylation sites that are occupied and to the oligosaccharide structure observed at each site. Factors that influence the type of carbohydrate chain that is attached at any one N-linked site are the accessibility of the carbohydrate chain to processing enzymes (49), protein sequences surrounding the site (5, 40), and the type of cell from which the protein is produced (19).The N-linked carbohydrate chains of HIV and SIV Env are critical for the proper folding and cleavage of the fusion-competent envelope spike (20, 59, 61). After Env is assembled, enzymatic removal of N-linked carbohydrate does not dramatically affect the functional conformation (2, 6, 7, 13, 24, 38). It is generally accepted that the carbohydrate attached to Env limits the ability of the underlying protein to be recognized by B cells (11, 48, 62). This carbohydrate also shields protein epitopes that would otherwise be the direct targets of antibodies that neutralize viral infection (41, 48, 62, 64). Furthermore, the high-mannose carbohydrates of HIV and SIV Env bind dynamically to an array of lectin proteins that are part of the host lymphoreticular system. The interaction of viral high-mannose carbohydrate with host lectin proteins has been associated with the enhancement (9, 16, 17, 43-45) or suppression (42, 56) of viral infection of CD4-positive T cells. The high-mannose carbohydrate of Env is also known to activate the release of immune-modulatory proteins from a subset of host antigen-presenting cells (12, 54).The plant lectin proteins from Galanthus nivalis (GNA) and Hippeastrum hybrid (HHA) specifically bind terminal α-1,3- and/or α-1,6-mannose of high-mannose oligosaccharides but not hybrid oligosaccharides (28, 55). GNA and HHA inhibit the replication of HIV-1 and SIVmac251, and uncloned, resistant populations of virus have been selected (3, 14). In this report, we define two N-linked sites in the external surface glycoprotein gp120 and one in the transmembrane glycoprotein gp41 whose mutation imparts high-level resistance to the inhibitory effects of GNA and HHA to cloned SIVmac239. Furthermore, using a GNA-binding enzyme-linked immunosorbent assay (ELISA), we show that assorted HIV-1 and SIVcpz gp120s consistently are considerably higher in mannose content than assorted gp120s from SIVmac, SIVsm, and HIV-2. These results shed new light on the impact of virus-host evolutionary dynamics on viral carbohydrate composition, and they may have important implications for the mechanisms by which long-standing natural hosts such as sooty mangabeys can resist generalized lymphoid activation and disease despite high levels of SIV replication.     

Utilization of Immunoglobulin G Fc Receptors by Human Immunodeficiency Virus Type 1: a Specific Role for Antibodies against the Membrane-Proximal External Region of gp41

Receptors (FcγRs) for the constant region of immunoglobulin G (IgG) are an important link between humoral immunity and cellular immunity. To help define the role of FcγRs in determining the fate of human immunodeficiency virus type 1 (HIV-1) immune complexes, cDNAs for the four major human Fcγ receptors (FcγRI, FcγRIIa, FcγRIIb, and FcγRIIIa) were stably expressed by lentiviral transduction in a cell line (TZM-bl) commonly used for standardized assessments of HIV-1 neutralization. Individual cell lines, each expressing a different FcγR, bound human IgG, as evidence that the physical properties of the receptors were preserved. In assays with a HIV-1 multisubtype panel, the neutralizing activities of two monoclonal antibodies (2F5 and 4E10) that target the membrane-proximal external region (MPER) of gp41 were potentiated by FcγRI and, to a lesser extent, by FcγRIIb. Moreover, the neutralizing activity of an HIV-1-positive plasma sample known to contain gp41 MPER-specific antibodies was potentiated by FcγRI. The neutralizing activities of monoclonal antibodies b12 and 2G12 and other HIV-1-positive plasma samples were rarely affected by any of the four FcγRs. Effects with gp41 MPER-specific antibodies were moderately stronger for IgG1 than for IgG3 and were ineffective for Fab. We conclude that FcγRI and FcγRIIb facilitate antibody-mediated neutralization of HIV-1 by a mechanism that is dependent on the Fc region, IgG subclass, and epitope specificity of antibody. The FcγR effects seen here suggests that the MPER of gp41 could have greater value for vaccines than previously recognized.Fc receptors (FcRs) are differentially expressed on a variety of cells of hematopoietic lineage, where they bind the constant region of antibody (Ab) and provide a link between humoral and cellular immunity. Humans possess two classes of FcRs for the constant region of IgG (FcγRs) that, when cross-linked, are distinguished by their ability to either activate or inhibit cell signaling (69, 77, 79). The activating receptors FcγRI (CD64), FcγRIIa (CD32), and FcγRIII (CD16) signal through an immunoreceptor tyrosine-based activation motif (ITAM), whereas FcγRIIb (CD32) contains an inhibitory motif (ITIM) that counters ITAM signals and B-cell receptor signals. It has been suggested that a balance between activating and inhibitory FcγRs coexpressed on the same cells plays an important role in regulating adaptive immunity (23, 68). Moreover, the inhibitory FcγRIIb, being the sole FcγR on B cells, appears to play an important role in regulating self-tolerance (23, 68). The biologic role of FcγRs may be further influenced by differences in their affinity for immunoglobulin G (IgG); thus, FcγRI is a high-affinity receptor that binds monomeric IgG (mIgG) and IgG immune complexes (IC), whereas FcγRIIa, FcγRIIb, and FcγRIIIa are medium- to low-affinity receptors that preferentially bind IgG IC (10, 49, 78). FcγRs also exhibit differences in their relative affinity for the four IgG subclasses (10), which has been suggested to influence the balance between activating and inhibitory FcγRs (67).In addition to their participation in acquired immunity, FcγRs can mediate several innate immune functions, including phagocytosis of opsonized pathogens, Ab-dependent cell cytotoxicity (ADCC), antigen uptake by professional antigen-presenting cells, and the production of inflammatory cytokines and chemokines (26, 35, 41, 48, 69). In some cases, interaction of Ab-coated viruses with FcγRs may be exploited by viruses as a means to facilitate entry into FcγR-expressing cells (2, 33, 47, 84). Several groups have reported FcγR-mediated Ab-dependent enhancement (ADE) of HIV-1 infection in vitro (47, 51, 58, 63, 94, 96), whereas other reports have implicated FcγRs in efficient inhibition of the virus in vitro (19, 21, 29, 44-46, 62, 98) and possibly as having beneficial effects against HIV-1 in vivo (5, 27, 28, 42). These conflicting results are further complicated by the fact that HIV-1-susceptible cells, such as monocytes and macrophages, can coexpress more than one FcγR (66, 77, 79).HIV-1 entry requires sequential interactions between the viral surface glycoprotein, gp120, and its cellular receptor (CD4) and coreceptor (usually CCR5 or CXCR4), followed by membrane fusion that is mediated by the viral transmembrane glycoprotein gp41 (17, 106). Abs neutralize the virus by binding either gp120 or gp41 and blocking entry into cells. Several human monoclonal Abs that neutralize a broad spectrum of HIV-1 variants have attracted considerable interest for vaccine design. Epitopes for these monoclonal Abs include the receptor binding domain of gp120 in the case of b12 (71, 86), a glycan-specific epitope on gp120 in the case of 2G12 (13, 85, 86), and two adjacent epitopes in the membrane-proximal external region (MPER) of g41 in the cases of 2F5 and 4E10 (3, 11, 38, 93). At least three of these monoclonal Abs have been shown to interact with FcRs and to mediate ADCC (42, 43).A highly standardized and validated assay for neutralizing Abs against HIV-1 that quantifies reductions in luciferase (Luc) reporter gene expression after a single round of virus infection in TZM-bl cells has been developed (60, 104). TZM-bl (also called JC53BL-13) is a CXCR4-positive HeLa cell line that was engineered to express CD4 and CCR5 and to contain integrated reporter genes for firefly Luc and Escherichia coli β-galactosidase under the control of the HIV-1 Tat-regulated promoter in the long terminal repeat terminal repeat sequence (74, 103). TZM-bl cells are permissive to infection by a wide variety of HIV-1, simian immunodeficiency virus, and human-simian immunodeficiency virus strains, including molecularly cloned Env-pseudotyped viruses. Here we report the creation and characterization of four new TZM-bl cell lines, each expressing one of the major human FcγRs. These new cell lines were used to gain a better understanding of the individual roles that FcγRs play in determining the fate of HIV-1 IC. Two FcγRs that potentiated the neutralizing activity of gp41 MPER-specific Abs were identified.     

Effect of Mutations in the Human Immunodeficiency Virus Type 1 Protease on Cleavage of the gp41 Cytoplasmic Tail

We previously reported that human immunodeficiency virus type 1 (HIV-1) develops resistance to the cholesterol-binding compound amphotericin B methyl ester (AME) by acquiring mutations (P203L and S205L) in the cytoplasmic tail of the transmembrane envelope glycoprotein gp41 that create cleavage sites for the viral protease (PR). In the present study, we observed that a PR inhibitor-resistant (PIR) HIV-1 mutant is unable to efficiently cleave the gp41 cytoplasmic tail in P203L and S205L virions, resulting in loss of AME resistance. To define the pathway to AME resistance in the context of the PIR PR, we selected for resistance with an HIV-1 isolate expressing the mutant enzyme. We identified a new gp41 mutation, R236L, that results in cleavage of the gp41 tail by the PIR PR. These results highlight the central role of gp41 cleavage as the primary mechanism of AME resistance.Cholesterol-enriched membrane microdomains, often referred to as lipid rafts (4, 18, 24), play an important role in the replication of many enveloped viruses, including human immunodeficiency virus type 1 (HIV-1) (22, 30). Lipid rafts are involved in both HIV-1 entry and egress (reviewed in references 6, 22, and 30), and the lipid bilayer of HIV-1 virions is significantly enriched in cholesterol and highly saturated lipids characteristic of lipid rafts (3, 5, 8). We recently demonstrated that the cholesterol-binding polyene fungal antibiotic amphotericin B methyl ester (AME) potently inhibits HIV-1 replication. The antiviral activity of AME is due to a profound inhibition of viral entry (27, 28) and impairment of virus particle production (29).In our previous studies, we showed that the propagation of HIV-1 in the presence of AME leads to viral escape from this compound. The mutations that confer resistance map to the cytoplasmic tail (CT) of the gp41 transmembrane envelope (Env) glycoprotein (27, 28). AME-resistant mutants (P203L and S205L) overcome the defect in viral entry imposed by AME by a novel mechanism of resistance whereby the gp41 CT is cleaved by the viral protease (PR) after incorporation of Env into virions (28). The introduction of stop codons into the gp41-coding region that prematurely truncate the CT also renders virions AME resistant. In the present study, we evaluated the interplay between protease inhibitor resistance (PIR) mutations and AME resistance.     

Acquisition of Complement Resistance through Incorporation of CD55/Decay-Accelerating Factor into Viral Particles Bearing Baculovirus GP64

A major obstacle to gene transduction by viral vectors is inactivation by human complement in vivo. One way to overcome this is to incorporate complement regulatory proteins, such as CD55/decay accelerating factor (DAF), into viral particles. Lentivirus vectors pseudotyped with the baculovirus envelope protein GP64 have been shown to acquire more potent resistance to serum inactivation and longer transgene expression than those pseudotyped with the vesicular stomatitis virus (VSV) envelope protein G. However, the molecular mechanisms underlying resistance to serum inactivation in pseudotype particles bearing the GP64 have not been precisely elucidated. In this study, we generated pseudotype and recombinant VSVs bearing the GP64. Recombinant VSVs generated in human cell lines exhibited the incorporation of human DAF in viral particles and were resistant to serum inactivation, whereas those generated in insect cells exhibited no incorporation of human DAF and were sensitive to complement inactivation. The GP64 and human DAF were detected on the detergent-resistant membrane and were coprecipitated by immunoprecipitation analysis. A pseudotype VSV bearing GP64 produced in human DAF knockdown cells reduced resistance to serum inactivation. In contrast, recombinant baculoviruses generated in insect cells expressing human DAF or carrying the human DAF gene exhibited resistance to complement inactivation. These results suggest that the incorporation of human DAF into viral particles by interacting with baculovirus GP64 is involved in the acquisition of resistance to serum inactivation.Gene therapy is a potential treatment option for genetic diseases, malignant diseases, and other acquired diseases. To this end, safe and efficient gene transfer into specific target cells is a central requirement, and a variety of nonviral and viral vector systems have been developed (6, 44). Recombinant viruses can be used for efficient gene transfer. Retroviruses, adeno-associated viruses, and lentiviruses are able to integrate foreign genes into host genomes and are suitable for gene therapeutics by virtue of their permanent expression of the therapeutic genes, whereas adenoviruses, herpesviruses, and baculoviruses can transiently express foreign genes (6, 12, 44). Pseudotype particles bearing other viral envelope proteins have been developed to improve transduction efficiency and the safety of viral vectors, including retrovirus (4, 7), lentivirus (25), vesicular stomatitis virus (VSV) (29), and baculovirus (17, 42). Pseudotype retroviruses and lentiviruses bearing the baculovirus envelope protein GP64 of Autographa californica nucleopolyhedrosis virus (AcNPV) have been shown to exhibit efficient gene transduction into a wide variety of cells with a lower cytotoxicity compared to those bearing the VSV envelope protein G (VSVG), which is commonly used for pseudotyping (18, 32, 35, 36).However, a drawback of gene transduction by viral vectors is that human sera inactivate the vectors (11, 40). Complement is a major element of the innate immune response and serves to link innate and adaptive immunity (8). Complement activation can occur via classical, lectin, and alternative pathways (2, 8). All pathways invoke several responses, such as virus opsonization, virolysis, anaphylatoxin, and chemotaxin production, as well as others (2, 8). VSV and baculovirus are inactivated by human sera via the classical pathway (1, 11). Because complement activation also induces potential damage to host cells, the complement system is tightly regulated by the complement regulatory proteins (CRPs), including CD55/decay-accelerating factor (DAF), CD46/membrane cofactor protein (MCP), and CD59 (2, 8, 15). DAF and CD46 inhibit activation of C3/C5-converting enzymes, which regulate the activation of classical and alternative pathways, whereas CD59 regulates the assembly of the membrane attack complex (2, 8, 15).Viral vectors can be manipulated to confer resistance to the complement inactivation. Human immunodeficiency virus (HIV) is known to develop resistance to human complement through the incorporation of DAF, CD46, and CD59 to the viral particles (22, 30, 31, 38). Moloney murine leukemia virus vectors produced in HT1080 cells are resistant to complement inactivation (5). Baculovirus and lentivirus vectors bearing DAF or the fusion protein between the functional domains of human DAF and the GP64 were resistant to complement inactivation (9, 13). It has been shown that lentivirus vectors pseudotyped with the GP64 are more resistant to inactivation in the sera of mice and rats (14, 32) and are capable of executing longer expression of the transgenes in nasal epithelia compared to those pseudotyped with the VSVG (35, 36). However, the precise mechanisms underlying the resistance to complement inactivation by pseudotyping of the GP64 is not known.To clarify the molecular mechanisms underlying the resistance of the viral vectors pseudotyped with the GP64 to the complement inactivation, we produced pseudotype and recombinant VSVs bearing the GP64. The recombinant VSVs carrying the gp64 gene generated in human cells but not in insect cells exhibited incorporation of human DAF on the viral particles and were resistant to the complement inactivation. Furthermore, production of the gp64 pseudotype VSV in the DAF knockdown human cells impaired serum resistance, whereas production of the gp64 recombinant VSV in the CHO cell lines stably expressing human DAF and the recombinant baculoviruses in the insect cells stably expressing human DAF or encoding the DAF gene in the genome conferred resistance to the complement inactivation. These results suggest that DAF incorporation into viral particles bearing baculovirus GP64 confers resistance to serum inactivation.     

Evidence for Mucin-Like Glycoproteins That Tether Sporozoites of Cryptosporidium parvum to the Inner Surface of the Oocyst Wall

Cryptosporidium parvum oocysts, which are spread by the fecal-oral route, have a single, multilayered wall that surrounds four sporozoites, the invasive form. The C. parvum oocyst wall is labeled by the Maclura pomifera agglutinin (MPA), which binds GalNAc, and the C. parvum wall contains at least two unique proteins (Cryptosporidium oocyst wall protein 1 [COWP1] and COWP8) identified by monoclonal antibodies. C. parvum sporozoites have on their surface multiple mucin-like glycoproteins with Ser- and Thr-rich repeats (e.g., gp40 and gp900). Here we used ruthenium red staining and electron microscopy to demonstrate fibrils, which appear to attach or tether sporozoites to the inner surface of the C. parvum oocyst wall. When disconnected from the sporozoites, some of these fibrillar tethers appear to collapse into globules on the inner surface of oocyst walls. The most abundant proteins of purified oocyst walls, which are missing the tethers and outer veil, were COWP1, COWP6, and COWP8, while COWP2, COWP3, and COWP4 were present in trace amounts. In contrast, MPA affinity-purified glycoproteins from C. parvum oocysts, which are composed of walls and sporozoites, included previously identified mucin-like glycoproteins, a GalNAc-binding lectin, a Ser protease inhibitor, and several novel glycoproteins (C. parvum MPA affinity-purified glycoprotein 1 [CpMPA1] to CpMPA4). By immunoelectron microscopy (immuno-EM), we localized mucin-like glycoproteins (gp40 and gp900) to the ruthenium red-stained fibrils on the inner surface wall of oocysts, while antibodies to the O-linked GalNAc on glycoproteins were localized to the globules. These results suggest that mucin-like glycoproteins, which are associated with the sporozoite surface, may contribute to fibrils and/or globules that tether sporozoites to the inner surface of oocyst walls.Cryptosporidium parvum and the related species Cryptosporidium hominis are apicomplexan parasites, which are spread by the fecal-oral route in contaminated water and cause diarrhea, particularly in immunocompromised hosts (1, 12, 39, 47). The infectious and diagnostic form of C. parvum is the oocyst, which has a single, multilayered, spherical wall that surrounds four sporozoites, the invasive forms (14, 27, 31). The outermost layer of the C. parvum oocyst wall is most often absent from electron micrographs, as it is labile to bleach used to remove contaminating bacteria from C. parvum oocysts (27). We will refer to this layer as the outer veil, which is the term used for a structure with an identical appearance on the surface of the oocyst wall of another apicomplexan parasite, Toxoplasma gondii (10). At the center of the C. parvum oocyst wall is a protease-resistant and rigid bilayer that contains GalNAc (5, 23, 43). When excysting sporozoites break through the oocyst wall, the broken edges of this bilayer curl in, while the overall shape of the oocyst wall remains spherical.The inner, moderately electron-dense layer of the C. parvum oocyst wall is where the Cryptosporidium oocyst wall proteins (Cryptosporidium oocyst wall protein 1 [COWP1] and COWP8) have been localized with monoclonal antibodies (4, 20, 28, 32). COWPs, which have homologues in Toxoplasma, are a family of nine proteins that contain polymorphic Cys-rich and His-rich repeats (37, 46). Finally, on the inner surface of C. parvum oocyst walls are knob-like structures, which cross-react with an anti-oocyst monoclonal antibody (11).Like other apicomplexa (e.g., Toxoplasma and Plasmodium), sporozoites of C. parvum are slender, move by gliding motility, and release adhesins from apical organelles when they invade host epithelial cells (1, 8, 12, 39). Unlike other apicomplexa, C. parvum parasites are missing a chloroplast-derived organelle called the apicoplast (1, 47, 49). C. parvum sporozoites have on their surface unique mucin-like glycoproteins, which contain Ser- and Thr-rich repeats that are polymorphic and may be modified by O-linked GalNAc (4-7, 21, 25, 26, 30, 32, 34, 35, 43, 45). These C. parvum mucins, which are highly immunogenic and are potentially important vaccine candidates, include gp900 and gp40/gp15 (4, 6, 7, 25, 26). gp40/gp15 is cleaved by furin-like proteases into two peptides (gp40 and gp15), each of which is antigenic (42). gp900, gp40, and gp15 are shed from the surface of the C. parvum sporozoites during gliding motility (4, 7, 35).The studies presented here began with electron microscopic observations of C. parvum oocysts stained with ruthenium red (23), which revealed novel fibrils or tethers that extend radially from the inner surface of the oocyst wall to the outer surface of sporozoites. We hypothesized that at least some of these fibrillar tethers might be the antigenic mucins, which are abundant on the surface of C. parvum sporozoites. To test this hypothesis, we used mass spectroscopy to identify oocyst wall proteins and sporozoite glycoproteins and used deconvolving and immunoelectron microscopy (immuno-EM) with lectins and anti-C. parvum antibodies to directly label the tethers.     

Role of a Putative gp41 Dimerization Domain in Human Immunodeficiency Virus Type 1 Membrane Fusion

The entry of human immunodeficiency virus type 1 (HIV-1) into a target cell entails a series of conformational changes in the gp41 transmembrane glycoprotein that mediates the fusion of the viral and target cell membranes. A trimer-of-hairpins structure formed by the association of two heptad repeat (HR) regions of the gp41 ectodomain has been implicated in a late step of the fusion pathway. Earlier native and intermediate states of the protein are postulated to mediate the antiviral activity of the fusion inhibitor enfuvirtide and of broadly neutralizing monoclonal antibodies (NAbs), but the details of these structures remain unknown. Here, we report the identification and crystal structure of a dimerization domain in the C-terminal ectodomain of gp41 (residues 630 to 683, or C54). Two C54 monomers associate to form an asymmetric, antiparallel coiled coil with two distinct C-terminal α-helical overhangs. This dimer structure is conferred largely by interactions within a central core that corresponds to the sequence of enfuvirtide. The mutagenic alteration of the dimer interface severely impairs the infectivity of Env-pseudotyped viruses. Moreover, the C54 structure binds tightly to both the 2F5 and 4E10 NAbs and likely represents a potential intermediate conformation of gp41. These results should enhance our understanding of the molecular basis of the gp41 fusogenic structural transitions and thereby guide rational, structure-based efforts to design new fusion inhibitors and vaccine candidates intended to induce broadly neutralizing antibodies.The entry of human immunodeficiency virus type 1 (HIV-1) into its target cell to establish an infection requires the fusion of viral and cellular membranes, a process that is mediated by the viral envelope glycoprotein (Env) through interactions with receptors on the target cell membrane (CD4 and a coreceptor, such as CCR-5 or CXCR-4) (14). HIV-1 Env is synthesized as the glycoprotein precursor gp160, which oligomerizes in the endoplasmic reticulum and subsequently is cleaved by the cellular furin endoprotease to create a metastable state that is primed for the induction of membrane fusion activity (19). The resulting Env complex is a trimeric structure comprising three gp120 surface glycoproteins, each associated noncovalently with one of three subunits of the gp41 transmembrane glycoprotein (24, 27, 47, 48). This native (prefusion) Env spike protrudes from the virus surface and is the target for neutralizing antibodies (NAbs) (reviewed in reference 3). It is generally accepted that HIV-1 membrane fusion is promoted by a series of receptor binding-triggered conformational changes in the Env complex, culminating in the formation of an energetically stable trimer of α-helical hairpins in gp41 (10, 14).The core structure of the trimer-of-hairpins is an antiparallel six-helix bundle: a central, three-stranded coiled coil formed by the first heptad repeat (HR_N) region of gp41 is sheathed by three α-helices derived from the second HR (HR_C) (5, 27, 42, 44). HR_N is immediately C terminal to the fusion peptide, while HR_C is adjacent to the transmembrane helix anchored in the viral membrane. The interaction of gp120 with CD4 and a chemokine receptor is thought to alter intersubunit interactions in the native Env complex, leading to gp41 reorganization into a postulated prehairpin intermediate (reviewed in references 10 and 14). At this point, the N-terminal HR_N coiled-coil trimer is formed, relocating the fusion peptides to allow them to insert into the cellular membrane. The HR_C region then is thought to jackknife so as to pack against the inner coiled-coil core and form the postfusion trimer-of-hairpin structure that brings the attached target cell and viral membranes together. Evidence for the existence of these different gp41 conformational states in the fusion pathway is indirect, being inferred from the antiviral activity of peptides derived from the two HR regions of gp41 (20, 45). These peptide inhibitors likely act in a dominant-negative manner by binding to the prehairpin intermediate, preventing the formation of the trimer-of-hairpins (6, 13, 27, 31). This intermediate is relatively stable, with a half-life of many minutes, as detected by the capacity of such peptides to inhibit fusion once prefusion gp41 has undergone a conformational transition (21, 31). Although mounting evidence indicates that the prefusogenic and intermediate states are important targets for drug- and vaccine-elicited NAbs (reviewed in references 3 and 10), little is known about their structures and how they modulate gp41 fusogenicity or serve as targets for inhibition.The C-terminal part of the gp41 ectodomain consists of HR_C (or C34) and the membrane-proximal external region (MPER) (Fig. ​(Fig.1).1). The C34 peptide is intrinsically disordered in isolation and forms an outer-layer α-helix only in the six-helix bundle (27, 29). Structural studies of the trimeric coiled-coil state of the MPER and of its bent helix conformation after binding to lipid membranes have begun to provide clues regarding the function of this unusual and important NAb-associated segment (25, 41). The MPER is the established target for two very rare but broadly reactive NAbs, 2F5 and 4E10/z13, which are elicited during natural human infection (50). These neutralizing epitopes seem to be poorly exposed on the surface of both HIV-1-infected cells and virions (reviewed in reference 3). Their exposure is enhanced or triggered by receptor binding but diminishes on the formation of the trimer-of-hairpins, suggesting that both of the NAbs target a more extended intermediate conformation rather than the native gp41 structure (8, 12). Despite extensive efforts, how structural aspects of the MPER explain its antigenicity and immunogenicity remains unclear. Here, we report the identification of the C-terminal dimerization domain of gp41 and present the 1.65-Å crystal structure of this domain. We characterize the role of this antiparallel two-stranded coiled-coil structure in NAb reactivity and viral function. Our study provides a potential structure for the fusion-intermediate state of gp41 and for the future design of new HIV-1 immunogens that may elicit broad and potent NAbs.Open in a separate windowFIG. 1.Structural and functional domains of HIV-1 gp41. (Upper) Schematic view of gp41 showing the location of the fusion peptide (FP), the two HR regions, the MPER, the transmembrane segment (TM), and the cytoplasmic region (CP). HR_C and MPER are depicted in blue and green, respectively. (Lower) Sequences of the C56, C54, C54_N656L, and C39 peptides employed in the study. The Asn-656→Leu mutation in C54_N656L is shown in red. The sequences of T-20 and core epitopes recognized by the human 2F5 and 4E10 MAbs are indicated.     

Potent and Broadly Reactive HIV-2 Neutralizing Antibodies Elicited by a Vaccinia Virus Vector Prime-C2V3C3 Polypeptide Boost Immunization Strategy

Human immunodeficiency virus type 2 (HIV-2) infection affects about 1 to 2 million individuals, the majority living in West Africa, Europe, and India. As for HIV-1, new strategies for the prevention of HIV-2 infection are needed. Our aim was to produce new vaccine immunogens that elicit the production of broadly reactive HIV-2 neutralizing antibodies (NAbs). Native and truncated envelope proteins from the reference HIV-2ALI isolate were expressed in vaccinia virus or in bacteria. This source isolate was used due to its unique phenotype combining CD4 independence and CCR5 usage. NAbs were not elicited in BALB/c mice by single immunization with a truncated and fully glycosylated envelope gp125 (gp125t) or a recombinant polypeptide comprising the C2, V3, and C3 envelope regions (rpC2-C3). A strong and broad NAb response was, however, elicited in mice primed with gp125t expressed in vaccinia virus and boosted with rpC2-C3. Serum from these animals potently neutralized (median 50% neutralizing titer, 3,200) six of six highly divergent primary HIV-2 isolates. Coreceptor usage and the V3 sequence of NAb-sensitive isolates were similar to that of the vaccinating immunogen (HIV-2ALI). In contrast, NAbs were not reactive on three X4 isolates that displayed major changes in V3 loop sequence and structure. Collectively, our findings demonstrate that broadly reactive HIV-2 NAbs can be elicited by using a vaccinia virus vector-prime/rpC2-C3-boost immunization strategy and suggest a potential relationship between escape to neutralization and cell tropism.Human immunodeficiency virus type 2 (HIV-2) infection affects 1 to 2 million individuals, most of whom live in India, West Africa, and Europe (17). HIV-2 has diversified into eight genetic groups named A to H, of which group A is by far the most prevalent worldwide. Nucleotide sequences of Env can differ up to 21% within a particular group and by over 35% between groups.The mortality rate in HIV-2-infected patients is at least twice that of uninfected individuals (26). Nonetheless, the majority of HIV-2-infected individuals survive as elite controllers (17). In the absence of antiretroviral therapy, the numbers of infected cells (39) and viral loads (36) are much lower among HIV-2-infected individuals than among those who are HIV-1 infected. This may be related to a more effective immune response produced against HIV-2. In fact, most HIV-2-infected individuals have proliferative T-cell responses and strong cytotoxic responses to Env and Gag proteins (17, 31). Moreover, autologous and heterologous neutralizing antibodies (NAbs) are raised in most HIV-2-infected individuals (8, 32, 48, 52), and the virus seems unable to escape from these antibodies (52). As for HIV-1, the antibody specificities that mediate HIV-2 neutralization and control are still elusive. The V3 region in the envelope gp125 has been identified as a neutralizing target by some but not by all investigators (3, 6, 7, 11, 40, 47, 54). Other weakly neutralizing epitopes were identified in the V1, V2, V4, and C5 regions in gp125 and in the COOH-terminal region of the gp41 ectodomain (6, 7, 41). A better understanding of the neutralizing determinants in the HIV-2 Env will provide crucial information regarding the most relevant targets for vaccine design.The development of immunogens that elicit the production of broadly reactive NAbs is considered the number one priority for the HIV-1 vaccine field (4, 42). Most current HIV-1 vaccine candidates intended to elicit such broadly reactive NAbs are based on purified envelope constructs that mimic the structure of the most conserved neutralizing epitopes in the native trimeric Env complex and/or on the expression of wild-type or modified envelope glycoproteins by different types of expression vectors (4, 5, 29, 49, 58). With respect to HIV-2, purified gp125 glycoprotein or synthetic peptides representing selected V3 regions from HIV-2 strain SBL6669 induced autologous and heterologous NAbs in mice or guinea pigs (6, 7, 22). However, immunization of cynomolgus monkeys with a subunit vaccine consisting of gp130 (HIV-2BEN) micelles offered little protection against autologous or heterologous challenge (34). Immunization of rhesus (19, 44, 45) and cynomolgus (1) monkeys with canarypox or attenuated vaccinia virus expressing several HIV-2 SBL6669 proteins, including the envelope glycoproteins, in combination with booster immunizations with gp160, gp125, or V3 synthetic peptides, elicited a weak neutralizing response and partial protection against autologous HIV-2 challenge. Likewise, vaccination of rhesus monkeys with immunogens derived from the historic HIV-2ROD strain failed to generate neutralizing antibodies and to protect against heterologous challenge (55). Finally, baboons inoculated with a DNA vaccine expressing the tat, nef, gag, and env genes of the HIV-2UC2 group B isolate were partially protected against autologous challenge without the production of neutralizing antibodies (33). These studies illustrate the urgent need for new vaccine immunogens and/or vaccination strategies that elicit the production of broadly reactive NAbs against HIV-2. The present study was designed to investigate in the mouse model the immunogenicity and neutralizing response elicited by novel recombinant envelope proteins derived from the reference primary HIV-2ALI isolate, when administered alone or in different prime-boost combinations.     

HIV-1 gp120 Determinants Proximal to the CD4 Binding Site Shift Protective Glycans That Are Targeted by Monoclonal Antibody 2G12

HIV-1 R5 envelopes vary considerably in their capacities to exploit low CD4 levels on macrophages for infection and in their sensitivities to the CD4 binding site (CD4bs) monoclonal antibody (MAb) b12 and the glycan-specific MAb 2G12. Here, we show that nonglycan determinants flanking the CD4 binding loop, which affect exposure of the CD4bs, also modulate 2G12 neutralization. Our data indicate that such residues act via a mechanism that involves shifts in the orientation of proximal glycans, thus modulating the sensitivity of 2G12 neutralization and affecting the overall presentation and structure of the glycan shield.The trimeric envelope (Env) spikes on HIV-1 virions are comprised of gp120 and gp41 heterodimers. gp120 is coated extensively with glycans (9, 11, 15) that are believed to protect the envelope from neutralizing antibodies. The extents and locations of glycosylation are variable and evolving (15). Thus, while some glycans are conserved, others appear or disappear in a host over the course of infection. Such changes may result in exposure or protection of functional envelope sites and can result from selection by different environmental pressures in vivo, including neutralizing antibodies.We previously reported that HIV-1 R5 envelopes varied considerably in tropism and neutralization sensitivity (3, 4, 12-14). We showed that highly macrophage-tropic R5 envelopes were more frequently detected in brain than in semen, blood, and lymph node (LN) samples (12, 14). The capacity of R5 envelopes to infect macrophages correlated with their ability to exploit low levels of cell surface CD4 for infection (12, 14). Determinants within and proximal to the CD4 binding site (CD4bs) were shown to modulate macrophage infectivity (3, 4, 5, 12, 13) and presumably acted by altering the avidity of the trimer for cell surface CD4. These determinants include residues proximal to the CD4 binding loop, which is likely the first part of the CD4bs contacted by CD4 (1). We also observed that macrophage-tropic R5 envelopes were frequently more resistant to the glycan-specific monoclonal antibody (MAb) 2G12 than were non-macrophage-tropic R5 Envs (13).Here, we investigated the envelope determinants of 2G12 sensitivity by using two HIV-1 envelopes that we used previously to map macrophage tropism determinants (4), B33 from brain and LN40 from lymph node tissue of an AIDS patient with neurological complications. While B33 imparts high levels of macrophage infectivity and is resistant to 2G12, LN40 Env confers very inefficient macrophage infection and is 2G12 sensitive (12-14).     

A Conformational Switch in Human Immunodeficiency Virus gp41 Revealed by the Structures of Overlapping Epitopes Recognized by Neutralizing Antibodies

The membrane-proximal external region (MPER) of the human immunodeficiency virus (HIV) envelope glycoprotein (gp41) is critical for viral fusion and infectivity and is the target of three of the five known broadly neutralizing HIV type 1 (HIV-1) antibodies, 2F5, Z13, and 4E10. Here, we report the crystal structure of the Fab fragment of Z13e1, an affinity-enhanced variant of monoclonal antibody Z13, in complex with a 12-residue peptide corresponding to the core epitope (W⁶⁷⁰NWFDITN⁶⁷⁷) at 1.8-Å resolution. The bound peptide adopts an S-shaped conformation composed of two tandem, perpendicular helical turns. This conformation differs strikingly from the α-helical structure adopted by an overlapping MPER peptide bound to 4E10. Z13e1 binds to an elbow in the MPER at the membrane interface, making relatively few interactions with conserved aromatics (Trp672 and Phe673) that are critical for 4E10 recognition. The comparison of the Z13e1 and 4E10 epitope structures reveals a conformational switch such that neutralization can occur by the recognition of the different conformations and faces of the largely amphipathic MPER. The Z13e1 structure provides significant new insights into the dynamic nature of the MPER, which likely is critical for membrane fusion, and it has significant implications for mechanisms of HIV-1 neutralization by MPER antibodies and for the design of HIV-1 immunogens.The continued spread of human immunodeficiency virus (HIV) worldwide and, in particular, in sub-Saharan Africa, where an estimated 22 million people currently are living with HIV/AIDS, underscores the urgent need for a preventative vaccine. However, despite nearly 25 years of intense international research, a vaccine is not yet available. Passive immunization with broadly neutralizing antibodies can confer sterilizing protection against infection in animal models (4, 12, 39-41, 51, 64), providing encouragement for the development of an antibody-inducing component of an HIV type 1 (HIV-1) vaccine. Such a vaccine should elicit neutralizing antibodies with activity against the broadest range of primary circulating isolates. However, a lack of understanding of how to raise potent, cross-reactive antibodies by immunization, the so-called neutralizing antibody problem, is a major hurdle in this effort (6, 24, 72). Thus, an understanding of the structure and presentation of neutralizing epitopes on the virus and the antibodies that recognize them is vital for vaccine development.The targets of antibody neutralization are the surface envelope (Env) glycoprotein trimers (gp120/gp41) that mediate the fusion of the viral membrane with that of the host. The majority of antibodies elicited during natural infection or immunization show limited or no cross-reactivity against diverse isolates. However, a few rare, broadly neutralizing, monoclonal antibodies have been isolated from HIV-1-infected individuals and exhibit activity against a wide range of isolates by binding to functionally conserved epitopes exposed on native gp120/gp41 trimers. These epitopes include the CD4 binding site, recognized by antibody b12, and a relatively well-conserved cluster of N-linked glycans, located on the outer domain of gp120, that is recognized by antibody 2G12 (12, 13, 71, 76). V3-directed antibodies, which are common in natural infection, also are able to sporadically neutralize across clades, as exemplified by 447-52D and F425-B4e8 (7, 16, 49, 66). The identification of three broadly neutralizing antibodies, 2F5, Z13, and 4E10, that target the conserved tryptophan-rich membrane-proximal external region (MPER) of gp41 has implicated this region as a highly promising vaccine target and has, therefore, spurred interest in its structural characterization (15, 35, 45, 47, 48, 50, 80).The MPER plays a critical, but not fully understood, role in membrane fusion and is situated between the C-terminal heptad repeat (CHR) and the transmembrane domain (TM) of gp41 (Fig. ​(Fig.1).1). Following the binding of gp120 to the cell surface receptors CD4 and CXCR4/CCR5, the gp41 glycoprotein undergoes a series of conformational changes that trigger the membrane fusion activity. Notably, a relatively long-lived prehairpin intermediate of gp41 is formed, in which the coiled-coil of the N-terminal heptad repeats (NHR) extends so as to enable the fusion peptides to embed into the target membrane. In the postfusion or fusogenic state, the CHR and NHR reassemble into an antiparallel 6-helix bundle in a process that drives membrane fusion (18). The MPER contains several functionally conserved tryptophan residues that are critical for membrane fusion and viral entry, although the structural basis for their specific role has not been firmly established (22, 44, 58). Their mutation to alanine leads to the attenuation of viral infectivity, which is most pronounced for Trp666 and Trp672 (numbered according to the HXB2 isolate) (46, 58, 78). In addition, peptides based on the MPER can induce membrane leakage (68). Such membrane-disrupting properties of the MPER have been suggested to be functionally important in the expansion of the fusion pore created after receptor engagement (42, 44, 58, 68, 77).Open in a separate windowFIG. 1.Major features of gp41 include the fusion peptide (FP), NHR, CHR, TM, and cytoplasmic domain (CD). The MPER is located between the CHR and TM regions of gp41. The core epitopes of 2F5 (green), Z13e1 (yellow), and 4E10 (orange) are indicated. The epitope of Z13e1 is located between those of 2F5 and 4E10, but it overlaps more closely with 4E10.From initial explorations using solution nuclear magnetic resonance, the structure of a 19-residue MPER peptide (residues 665 to 683) was found to be helical in dodecylphosphocholine micelles, with the hydrophobic and hydrophilic residues distributed evenly around the helix axis (62). Another study found that an MPER peptide comprising residues 659 to 671 adopts a 3₁₀-helix in water (10). More recently, the structure of an MPER peptide (residues 662 to 683) in liposomes was elucidated by a combination of nuclear magnetic resonance and spin-label electron paramagnetic resonance (69), and it was found to adopt a kinked, amphipathic structure composed of two helices connected by a short hinge (Phe673 and Asn674). Crystal structures of Fab 2F5 in complex with a 7-mer (E⁶⁶²LDKWAS⁶⁶⁸) and 17-mer encompassing residues 654 to 670 previously had revealed a mostly extended conformation characterized by a central β-turn involving Asp664, Lys665, and Trp666 (47, 48). This motif is the key recognition determinant for 2F5 and becomes deeply buried in the antibody combining site, suggesting that it is exposed at some stage in viral entry (45, 47, 78). The crystal structure of Fab 4E10 in complex with peptide-spanning residues W⁶⁷⁰NWFDITNW⁶⁷⁸ revealed an amphipathic α-helical structure with a narrow hydrophilic face (15). The N terminus of the 4E10 epitope forms a 3₁₀-helix that transitions into a regular α-helix at residue Asp674 and continues to Lys683, which constitutes the end of the gp41 ectodomain (14). Thus, while the structure of the MPER within functional, membrane-embedded Env trimers is not known, the observation that unconstrained peptides are able to adopt more than one defined structure suggests an inherent degree of flexibility.Like 4E10, Z13 was identified from an HIV-1-infected individual, the former being isolated from an immortalized B-cell line and the latter from a bone marrow RNA phage display library (80). The epitope of MAb Z13 spans residues S⁶⁶⁸LWNWFDITN⁶⁷⁷, as determined by peptide mapping, scanning mutagenesis, and antibody competition studies (46, 80). This region lies between the 2F5 and 4E10 epitopes but overlaps more closely with 4E10 (Fig. ​(Fig.1).1). 4E10 and Z13 are both able to neutralize primary as well as laboratory-adapted isolates; nevertheless, Z13 is not as broadly neutralizing as 4E10, which has the greatest breadth of any HIV-1 antibody described to date (9). Z13e1 is an affinity-enhanced variant of Z13 and was evolved by randomizing the complementarity determining region (CDR) L3 loop sequence to identify tighter-binding mutants using phage display (46). Z13e1 displays higher affinity for both peptide and recombinant gp41 substrates, as well as increased neutralization potency, suggesting that the L3 mutations optimize binding to the linear MPER epitope. The neutralization breadth of Z13e1 is limited by the requirement for Asn671 and Asp674 in the MPER, which are approximately 71 and 58% conserved, respectively, among sequences in the Los Alamos HIV sequence database (80). Based on the clear relationship between Env trimer binding and neutralization, the neutralizing activity of Z13e1 derives from binding to a functional trimer (8, 20, 25, 43, 52, 55, 60, 73, 74). While Z13e1 and 4E10 have identical affinities for optimized linear peptides, Z13e1 is still about an order of magnitude less potent than 4E10 against a variety of primary isolates. Although the occlusion of the Z13e1 epitope on virion-associated trimers is thought to be the major limitation (46), the structural basis for the lower potency of Z13e1 relative to those of 2F5 and 4E10 is unclear.Whereas neutralization by 4E10 depends critically on Trp672 and Phe673, Z13e1 instead requires the flanking Asn671 and Asp674 residues (46). Based on a helical model of the MPER, it was predicted that Z13e1 binds the narrow hydrophilic face that displays Asn671, Asp674, and Asn677 that is opposite that recognized by 4E10. As Z13e1 and 4E10 bind to functional trimers, both epitopes must be exposed at some stage before membrane fusion (20). To examine how Z13e1 recognizes its MPER epitope, we determined the crystal structure of Fab Z13e1 in complex with a 12-residue peptide corresponding to the core epitope with C-terminal flanking lysines to aid peptide solubility (W⁶⁷⁰NWFDITN⁶⁷⁷KKKK). The crystal structure at 1.8-Å resolution uncovers a conformation of the MPER that is distinct from that visualized in complex with 4E10. Our findings show that Z13e1 and 4E10 recognize different conformers of the MPER and reveal a novel conformational switch that is relevant for HIV-1 neutralization and membrane fusion.     

The Longin Domain Regulates the Steady-State Dynamics of Sec22 in Plasmodium falciparum

The specificity of vesicle-mediated transport is largely regulated by the membrane-specific distribution of SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteins. However, the signals and machineries involved in SNARE protein targeting to the respective intracellular locations are not fully understood. We have identified a Sec22 ortholog in Plasmodium falciparum (PfSec22) that contains an atypical insertion of the Plasmodium export element within the N-terminal longin domain. This Sec22 protein partially associates with membrane structures in the parasitized erythrocytes when expressed under the control of the endogenous promoter element. Our studies indicate that the atypical longin domain contains signals that are required for both endoplasmic reticulum (ER)/Golgi apparatus recycling of PfSec22 and partial export beyond the ER/Golgi apparatus interface. ER exit of PfSec22 is regulated by motifs within the α3 segment of the longin domain, whereas the recycling and export signals require residues within the N-terminal hydrophobic segment. Our data suggest that the longin domain of PfSec22 exhibits major differences from the yeast and mammalian orthologs, perhaps indicative of a novel mechanism for Sec22 trafficking in malaria parasites.Plasmodium falciparum exhibits a complex network of endomembrane organelles that are unique to this obligate intracellular parasite of human erythrocytes. They include parasite-induced tubules and vesicles in the infected host cell and specialized secretory structures collectively known as the apical complex. The asexual blood stages of the parasite develop within a parasitophorous vacuole (PV) and thus are separated from the external milieu by three lipid bilayers: the parasite plasma membrane (PPM), the PV membrane (PVM), and the erythrocyte plasma membrane. To survive inside these terminally differentiated human erythrocytes, P. falciparum remodels the host cell compartment by exporting numerous proteins into the erythrocyte cytoplasm (12, 15, 49, 50, 57). The mechanisms by which both soluble and membrane-bound proteins are transported, first into the PV lumen, followed by translocation across the PVM and transport within the erythrocyte cytosol, are not fully understood (9). A majority of the exported proteins contain bipartite signals that comprise a “recessed” N-terminal signal sequence and a Plasmodium export element/vacuolar translocation sequence (PEXEL/VTS) that is characterized by the consensus sequence RX(L/I)X(D/E/Q). These signals are predicted to facilitate the transport of proteins into the PV (using their recessed, or N-terminal, signal sequences) and translocation across the PVM (using their PEXEL/VTS motifs) (5, 23, 29, 34). However, a subset of the exported proteins lack either one or both signal elements and may require novel targeting motifs for transport beyond the PPM (20, 43). A majority of the proteins enter the parasite secretory system via the endoplasmic reticulum (ER), where they are incorporated into ER-derived vesicles and then transported through the “unstacked” Golgi bodies to their final destinations (45, 48, 55, 56). Membrane-bound vesicular elements have been detected in the infected host cell cytosol, suggesting the existence of an extraparasitic vesicle-mediated transport process in malaria parasites (22, 47, 52). How vesicle targeting is achieved in P. falciparum parasites remains elusive.Vesicle targeting and fusion in eukaryotic cells involves proteins of the SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) family (25, 41, 42, 44). SNAREs are “tail-anchored” proteins that function by forming complexes that bridge vesicle and target membranes during fusion (6, 7, 24). Distinct sets of SNARE proteins localize to different intracellular transport pathways using processes that are not well understood. Increasing evidence suggests that the N-terminal regions of SNARE proteins contain signals required for their subcellular localization (4, 31, 53). These N-terminal regions include the three-helical Habc bundles of syntaxin SNAREs and the “profilin-like” folds of long VAMPs (vesicle-associated membrane proteins), also known as longin domains (7, 17, 33, 40, 46). The Sec22 gene products in mammals and yeast are longin domain-containing SNAREs that cycle between the ER and Golgi compartments (3, 19, 31, 32). We have identified a Sec22 ortholog in P. falciparum (PfSec22) that contains a PEXEL/VTS sequence insertion between the α2 and α3 segments of the longin domain preceded by a stretch of hydrophobic residues that spans a region between the β5 and α2 segments (2). In this study, we examined the distribution of PfSec22 in P. falciparum-infected erythrocytes and investigated the role of the atypical longin domain in its steady-state localization. Our data show that the P. falciparum ortholog of Sec22 partially associates with noncanonical destinations (tubovesicular network and intraerythrocytic vesicles) in the infected erythrocytes and that the N-terminal longin domain exhibits a dual function, mediating ER-to-Golgi apparatus trafficking, as well as retrieval from the Golgi apparatus.     

Role of Phosphatidylinositol 3-Kinase in Friend Spleen Focus-Forming Virus-Induced Erythroid Disease

Infection of erythroid cells by Friend spleen focus-forming virus (SFFV) leads to acute erythroid hyperplasia in mice due to expression of its unique envelope glycoprotein, gp55. Erythroid cells expressing SFFV gp55 proliferate in the absence of their normal regulator, erythropoietin (Epo), because of interaction of the viral envelope protein with the erythropoietin receptor and a short form of the receptor tyrosine kinase Stk (sf-Stk), leading to constitutive activation of several signal transduction pathways. Our previous in vitro studies showed that phosphatidylinositol 3-kinase (PI3-kinase) is activated in SFFV-infected cells and is important in mediating the biological effects of the virus. To determine the role of PI3-kinase in SFFV-induced disease, mice deficient in the p85α regulatory subunit of class IA PI3-kinase were inoculated with different strains of SFFV. We observed that p85α status determined the extent of erythroid hyperplasia induced by the sf-Stk-dependent viruses SFFV-P (polycythemia-inducing strain of SFFV) and SFFV-A (anemia-inducing strain of SFFV) but not by the sf-Stk-independent SFFV variant BB6. Our data also indicate that p85α status determines the response of mice to stress erythropoiesis, consistent with a previous report showing that SFFV uses a stress erythropoiesis pathway to induce erythroleukemia. We further showed that sf-Stk interacts with p85α and that this interaction depends upon sf-Stk kinase activity and tyrosine 436 in the multifunctional docking site. Pharmacological inhibition of PI3-kinase blocked proliferation of primary erythroleukemia cells from SFFV-infected mice and the erythroleukemia cell lines derived from them. These results indicate that p85α may regulate sf-Stk-dependent erythroid proliferation induced by SFFV as well as stress-induced erythroid hyperplasia.The Friend spleen focus-forming virus (SFFV) is a highly pathogenic retrovirus that induces rapid erythroblastosis in susceptible strains of mice (for a review, see reference 42). Friend SFFV is a replication-defective virus with deletions in its env gene, giving rise to a unique glycoprotein, SFFV gp55. This unique glycoprotein confers pathogenicity to the virus; a vector encoding SFFV gp55 alone is sufficient to induce erythroblastosis in susceptible strains of mice (49). The Fv-2 gene encodes one of the key susceptibility factors for SFFV-induced erythroid disease (18, 37), as follows: the receptor tyrosine kinase Stk/RON, a member of the Met family of receptor tyrosine kinases (11-12). Susceptibility to SFFV-induced disease is associated with expression of a short form of the receptor tyrosine kinase Stk, termed sf-Stk, that is transcribed from an internal promoter within the Stk gene of Fv-2-susceptible (Fv-2^ss) mice but not Fv-2-resistant (Fv-2^rr) mice (37) and is abundantly expressed in erythroid cells (11). Infection of erythroid cells with the polycythemia-inducing strain of SFFV (SFFV-P) induces erythropoietin (Epo)-independent proliferation and differentiation, whereas erythroid cells infected with the anemia-inducing strain of SFFV (SFFV-A) proliferate in the absence of Epo but still require Epo for differentiation (42). Previous studies demonstrated that this Epo-independent erythroblastosis is due to the cell surface interaction of the SFFV envelope protein with the Epo receptor (EpoR) and sf-Stk (31). While interaction with the EpoR appears to be responsible mainly for the induction of Epo-independent differentiation (52), Epo-independent erythroid cell proliferation depends upon activation of sf-Stk. We recently demonstrated that sf-Stk covalently interacts with SFFV-P gp55 in hematopoietic cells that express the EpoR and that this interaction induces sf-Stk activation (31). Furthermore, exogenous expression of sf-Stk, but not a kinase-inactive mutant of sf-Stk, in bone marrow cells from sf-Stk null mice can restore Epo-independent erythroid colony formation in response to SFFV infection (5, 41). Thus, the SFFV envelope glycoprotein induces Epo-independent proliferation of erythroid cells mainly by activating sf-Stk. While sf-Stk is a key susceptibility factor for erythroblastosis induced by both SFFV-P and SFFV-A (18), it is not required for the induction of erythroblastosis by the SFFV mutant BB6, which encodes an envelope glycoprotein, gp42, that is deleted in the membrane-proximal extracellular domain (19) and does not induce sf-Stk activation (31). gp42 of SFFV-BB6 appears to exert its biological effects on erythroid cells by efficiently interacting with the EpoR (9). Compared with wild-type SFFV, SFFV-BB6 causes a relatively indolent and slowly developing disease in mice (19).A number of signaling pathways normally activated in erythroid cells after erythropoietin (Epo) binds to its cell surface receptor (40) are constitutively activated in erythroid cells infected with SFFV. These include JAK/STAT, Ras/Raf/mitogen-activated protein kinase (MAPK), Jun N-terminal kinase, and the phosphatidylinositol 3-kinase (PI3-kinase)/Akt pathways (24, 25, 28-30, 32). SFFV gp55 is thought to activate these pathways by interacting with either the EpoR or sf-Stk (17, 31, 43). In several in vitro systems, class IA PI3-kinase has been shown to be activated by Epo through the EpoR (8, 20, 21) or by SFFV through sf-Stk (5, 14). We and others have shown that the PI3-kinase pathway is important for the induction of Epo independence by SFFV (5, 29). The class IA subclass of PI3-kinase is a heterodimer comprising the p110 (α, β, δ) catalytic unit and one of five regulatory subunits (85α, p55α, p50α, 85β, and 55γ) (15). The first 3 regulatory subunits are all splice variants of the same gene (pik3r1). Deletion of pik3r1, which encodes p85α, p55α, and p50α, is lethal (6, 7), and these regulatory subunits of PI3-kinase are required for normal murine fetal erythropoiesis in mice (10).To determine the role of p85α in SFFV-induced erythroleukemia, we used a distinct nonlethal pik3r1 knockout mouse which lacks only the p85α regulatory subunit of PI3-kinase (45, 47), allowing the study of SFFV-induced erythroleukemia in adult mice. Our results indicate that p85α regulates SFFV-induced erythroid hyperplasia induced in vivo by sf-Stk-dependent, but not sf-Stk-independent, isolates of the virus as well as stress-induced erythropoiesis and suggest that this regulation may occur through the interaction of sf-Stk with p85α.