Impact of HLA in Mother and Child on Disease Progression of Pediatric Human Immunodeficiency Virus Type 1 Infection

A broad Gag-specific CD8⁺ T-cell response is associated with effective control of adult human immunodeficiency virus (HIV) infection. The association of certain HLA class I molecules, such as HLA-B*57, -B*5801, and -B*8101, with immune control is linked to mutations within Gag epitopes presented by these alleles that allow HIV to evade the immune response but that also reduce viral replicative capacity. Transmission of such viruses containing mutations within Gag epitopes results in lower viral loads in adult recipients. In this study of pediatric infection, we tested the hypothesis that children may tend to progress relatively slowly if either they themselves possess one of the protective HLA-B alleles or the mother possesses one of these alleles, thereby transmitting a low-fitness virus to the child. We analyzed HLA type, CD8⁺ T-cell responses, and viral sequence changes for 61 mother-child pairs from Durban, South Africa, who were monitored from birth. Slow progression was significantly associated with the mother or child possessing one of the protective HLA-B alleles, and more significantly so when the protective allele was not shared by mother and child (P = 0.007). Slow progressors tended to make CD8⁺ T-cell responses to Gag epitopes presented by the protective HLA-B alleles, in contrast to progressors expressing the same alleles (P = 0.07; Fisher''s exact test). Mothers expressing the protective alleles were significantly more likely to transmit escape variants within the Gag epitopes presented by those alleles than mothers not expressing those alleles (75% versus 21%; P = 0.001). Reversion of transmitted escape mutations was observed in all slow-progressing children whose mothers possessed protective HLA-B alleles. These data show that HLA class I alleles influence disease progression in pediatric as well as adult infection, both as a result of the CD8⁺ T-cell responses generated in the child and through the transmission of low-fitness viruses by the mother.Human immunodeficiency virus (HIV)-specific CD8⁺ T cells play a central role in controlling viral replication (12). It is the specificity of the CD8⁺ T-cell response, particularly the response to Gag, that is associated with low viral loads in HIV infection (7, 17, 34). Although immune control is undermined by the selection of viral mutations that prevent recognition by the CD8⁺ T cells, evasion of Gag-specific responses mediated by protective class I HLA-B alleles typically brings a reduction in viral replicative capacity, facilitating subsequent immune control of HIV (2, 20, 21). The same principle has been demonstrated in studies of simian immunodeficiency virus infection (18, 22).Recent studies showed that the class I HLA-B alleles that protect against disease progression present more Gag-specific CD8⁺ T-cell epitopes and drive the selection of more Gag-specific escape mutations than those alleles that are associated with high viral loads (23). These protective HLA-B alleles not only are beneficial to infected individuals expressing those alleles but also benefit a recipient following transmission, since the transmitted virus carrying multiple Gag escape mutations may have substantially reduced fitness (3, 4, 8). However, there is no benefit to the recipient if he or she shares the same protective allele as the donor because the transmitted virus carries escape mutations in the Gag epitopes that would otherwise be expected to mediate successful immune control in the recipient (8, 11).The sharing of HLA alleles between donor and recipient occurs frequently in mother-to-child transmission (MTCT). The risk of MTCT is related to viral load in the mother, and a high viral load is associated with nonprotective alleles, such as HLA-B*18 and -B*5802. This may contribute in two distinct ways to the more rapid progression observed in pediatric HIV infection (24, 26, 27). First, because infected children share 50% or more of their HLA alleles with the transmitting mother, they are less likely than adults to carry protective HLA alleles (16). Thus, infected children as a group carry fewer protective HLA alleles and more nonprotective HLA alleles. Second, even when the child has a protective allele, such as HLA-B*27, this allele does not offer protection if the maternally transmitted virus carries escape mutations within the key Gag epitopes that are presented by the protective allele (11, 19).However, it is clear that infected children who possess protective alleles, such as HLA-B*27 or HLA-B*57, can achieve durable immune control of HIV infection if the virus transmitted from the mother is not preadapted to those alleles (6, 10). HIV-specific CD8⁺ T-cell responses are detectable from birth in infected infants (32). Furthermore, as in adult infection (3, 8), HIV-infected children have the potential to benefit from transmission of low-fitness viruses in the situation where the mother possesses protective HLA alleles and the child does not share those protective alleles. MTCT of low-fitness viruses carrying CD8⁺ T-cell escape mutations was recently documented (28; J. Prado et al., unpublished data).In this study, undertaken in Durban, South Africa, we set out to test the hypothesis that HIV-infected children are less likely to progress rapidly to disease if either the infected child or the transmitting mother possesses a protective HLA allele that is not shared. The HLA alleles most strongly associated with low viral loads and high CD4 counts in a cohort of >1,200 HIV-infected adults in Durban are HLA-B*57 (-B*5702 and -B*5703), HLA-B*5801, and HLA-B*8101 (16; A. Leslie et al., unpublished data). These four alleles all present Gag-specific CD8⁺ T-cell epitopes, and in each case the escape mutations selected in these epitopes reduce viral replicative capacity (2-4, 8, 21, 23).Analyzing a previously described cohort of 61 HIV-infected children in Durban (24, 26, 32), South Africa, who were all monitored from birth, we first addressed the question of whether possession of any of these four alleles by either mother or child is associated with slower disease progression in the child and then determined whether sharing of protective alleles by mother and child affects the ability of the child to make the Gag-specific CD8⁺ T-cell responses restricted by the shared allele.     

Quantitative Fluorescence Resonance Energy Transfer Microscopy Analysis of the Human Immunodeficiency Virus Type 1 Gag-Gag Interaction: Relative Contributions of the CA and NC Domains and Membrane Binding

The human immunodeficiency virus type 1 structural polyprotein Pr55^Gag is necessary and sufficient for the assembly of virus-like particles on cellular membranes. Previous studies demonstrated the importance of the capsid C-terminal domain (CA-CTD), nucleocapsid (NC), and membrane association in Gag-Gag interactions, but the relationships between these factors remain unclear. In this study, we systematically altered the CA-CTD, NC, and the ability to bind membrane to determine the relative contributions of, and interplay between, these factors. To directly measure Gag-Gag interactions, we utilized chimeric Gag-fluorescent protein fusion constructs and a fluorescence resonance energy transfer (FRET) stoichiometry method. We found that the CA-CTD is essential for Gag-Gag interactions at the plasma membrane, as the disruption of the CA-CTD has severe impacts on FRET. Data from experiments in which wild-type (WT) and CA-CTD mutant Gag molecules are coexpressed support the idea that the CA-CTD dimerization interface consists of two reciprocal interactions. Mutations in NC have less-severe impacts on FRET between normally myristoylated Gag proteins than do CA-CTD mutations. Notably, when nonmyristoylated Gag interacts with WT Gag, NC is essential for FRET despite the presence of the CA-CTD. In contrast, constitutively enhanced membrane binding eliminates the need for NC to produce a WT level of FRET. These results from cell-based experiments suggest a model in which both membrane binding and NC-RNA interactions serve similar scaffolding functions so that one can functionally compensate for a defect in the other.The human immunodeficiency virus type 1 (HIV-1) structural precursor polyprotein Pr55^Gag is necessary and sufficient for the assembly of virus-like particles (VLPs). Gag is composed of four major structural domains, matrix (MA), capsid (CA), nucleocapsid (NC), and p6, as well as two spacer peptides, SP1 and SP2 (3, 30, 94). Following particle assembly and release, cleavage by HIV-1 protease separates these domains. However, these domains must work together in the context of the full-length Gag polyprotein to drive particle assembly.Previous studies have mapped two major functional domains involved in the early steps of assembly: first, Gag associates with cellular membranes via basic residues and N-terminal myristoylation of the MA domain (10, 17, 20, 35, 39, 87, 91, 106); second, the Gag-Gag interaction domains that span the CA C-terminal domain (CA-CTD) and NC domain promote Gag multimerization (3, 11, 14, 16, 18, 23, 27, 29, 30, 33, 36, 46, 64, 88, 94, 102, 103). Structural and genetic studies have identified two residues (W184 and M185) within a dimerization interface in the CA-CTD that are critical to CA-CA interactions (33, 51, 74, 96). Analytical ultracentrifugation of heterodimers formed between wild-type (WT) Gag and Gag mutants with changes at these residues suggests that the dimerization interface consists of two reciprocal interactions, one of which can be disrupted to form a “half-interface” (22).In addition to the CA-CTD, NC contributes to assembly via 15 basic residues (8, 9, 11, 14, 18, 23, 25, 28, 34, 40, 43, 54, 57, 58, 74, 79, 88, 97, 104, 105), although some researchers have suggested that NC instead contributes to the stability of mature virions after assembly (75, 98, 99). It is thought that the contribution of NC to assembly is due to its ability to bind RNA, since the addition of RNA promotes the formation of particles in vitro (14-16, 37, 46), and RNase treatment disrupts Gag-Gag interactions (11) and immature viral cores (67). However, RNA is not necessary per se, since dimerization motifs can substitute for NC (1, 4, 19, 49, 105). This suggests a model in which RNA serves a structural role, such as a scaffold, to promote Gag-Gag interactions through NC. Based on in vitro studies, it has been suggested that this RNA scaffolding interaction facilitates the low-order Gag multimerization mediated by CA-CTD dimerization (4, 37, 49, 62, 63, 85). Despite a wealth of biochemical data, the relative contributions of the CA-CTD and NC to Gag multimerization leading to assembly are yet to be determined in cells.Mutations in Gag interaction domains alter membrane binding in addition to affecting Gag multimerization. In particular, mutations or truncations of CA reduce membrane binding (21, 74, 82), and others previously reported that mutations or truncations of NC affect membrane binding (13, 78, 89, 107). These findings are consistent with a myristoyl switch model of membrane binding in which Gag can switch between high- and low-membrane-affinity states (38, 71, 76, 83, 86, 87, 92, 95, 107). Many have proposed, and some have provided direct evidence (95), that Gag multimerization mediated by CA or NC interactions promotes the exposure of the myristoyl moiety to facilitate membrane associations.Gag membrane binding and multimerization appear to be interrelated steps of virus assembly, since membrane binding also facilitates Gag multimerization. Unlike betaretroviruses that fully assemble prior to membrane targeting and envelopment (type B/D), lentiviruses, such as HIV, assemble only on cellular membranes at normal Gag expression levels (type C), although non-membrane-bound Gag complexes exist (45, 58, 60, 61, 65). Consistent with this finding, mutations that reduce Gag membrane associations cause a defect in Gag multimerization (59, 74). Therefore, in addition to their primary effects on Gag-Gag interactions, mutations in Gag interaction domains cause a defect in membrane binding, which, in turn, causes a secondary multimerization defect. To determine the relative contributions of the CA-CTD and the NC domain to Gag-Gag interactions at the plasma membrane, it is essential to eliminate secondary effects due to a modulation of membrane binding.Except for studies using a His-tag-mediated membrane binding system (5, 46), biochemical studies of C-type Gag multimerization typically lack membranes. Therefore, these studies do not fully represent particle assembly, which occurs on biological membranes in cells. Furthermore, many biochemical and structural approaches are limited to isolated domains or truncated Gag constructs. Thus, some of these studies are perhaps more relevant to the behavior of protease-cleaved Gag in mature virions. With few exceptions (47, 74), cell-based studies of Gag multimerization have typically been limited to measuring how well mutant Gag is incorporated into VLPs when coexpressed or not with WT Gag. Since VLP production is a complex multistep process, effects of mutations on other steps in the process can confound this indirect measure. For example, NC contributes to VLP production by both promoting multimerization and interacting with the host factor ALIX to promote VLP release (26, 80). To directly assay Gag multimerization in cells, several groups (24, 45, 52, 56) developed microscopy assays based on fluorescence resonance energy transfer (FRET). These assays measure the transfer of energy between donor and acceptor fluorescent molecules that are brought within ∼5 nm by the association of the proteins to which they are attached (41, 48, 90). However, these microscopy-based Gag FRET assays have not been used to fully elucidate several fundamental aspects of HIV-1 Gag multimerization at the plasma membrane of cells, such as the relative contributions of the CA-CTD and NC and the effect of membrane binding on Gag-Gag interactions. In this study, we used a FRET stoichiometry method based on calibrated spectral analysis of fluorescence microscopy images (41). This algorithm determines the fractions of both donor and acceptor fluorescent protein-tagged Gag molecules participating in FRET. For cells expressing Gag molecules tagged with donor (cyan fluorescent protein [CFP]) and acceptor (yellow fluorescent protein [YFP]) molecules, this method measures the apparent FRET efficiency, which is proportional to the mole fraction of Gag constructs in complex. By measuring apparent FRET efficiencies, quantitative estimates of the mole fractions of interacting proteins can be obtained.Using this FRET-based assay, we aim to answer two questions: (i) what are the relative contributions of CA-CTD and NC domains to Gag multimerization when secondary effects via membrane binding are held constant, and (ii) what is the effect of modulating membrane binding on the ability of Gag mutants to interact with WT Gag?Our data demonstrate that the CA-CTD dimerization interface is essential for Gag multimerization at the plasma membrane, as fully disrupting the CA-CTD interaction abolishes FRET, whereas a modest level of FRET is still detected in the absence of NC. We also present evidence that the CA-CTD dimerization interface consists of two reciprocal interactions, allowing the formation of a half-interface that can still contribute to Gag multimerization. Notably, when Gag derivatives with an intact CA-CTD were coexpressed with WT Gag, either membrane binding ability or NC was required for the Gag mutants to interact with WT Gag, suggesting functional compensation between these factors.     

Early Selection in Gag by Protective HLA Alleles Contributes to Reduced HIV-1 Replication Capacity That May Be Largely Compensated for in Chronic Infection

Mutations that allow escape from CD8 T-cell responses are common in HIV-1 and may attenuate pathogenesis by reducing viral fitness. While this has been demonstrated for individual cases, a systematic investigation of the consequence of HLA class I-mediated selection on HIV-1 in vitro replication capacity (RC) has not been undertaken. We examined this question by generating recombinant viruses expressing plasma HIV-1 RNA-derived Gag-Protease sequences from 66 acute/early and 803 chronic untreated subtype B-infected individuals in an NL4-3 background and measuring their RCs using a green fluorescent protein (GFP) reporter CD4 T-cell assay. In acute/early infection, viruses derived from individuals expressing the protective alleles HLA-B*57, -B*5801, and/or -B*13 displayed significantly lower RCs than did viruses from individuals lacking these alleles (P < 0.05). Furthermore, acute/early RC inversely correlated with the presence of HLA-B-associated Gag polymorphisms (R = −0.27; P = 0.03), suggesting a cumulative effect of primary escape mutations on fitness during the first months of infection. At the chronic stage of infection, no strong correlations were observed between RC and protective HLA-B alleles or with the presence of HLA-B-associated polymorphisms restricted by protective alleles despite increased statistical power to detect these associations. However, RC correlated positively with the presence of known compensatory mutations in chronic viruses from B*57-expressing individuals harboring the Gag T242N mutation (n = 50; R = 0.36; P = 0.01), suggesting that the rescue of fitness defects occurred through mutations at secondary sites. Additional mutations in Gag that may modulate the impact of the T242N mutation on RC were identified. A modest inverse correlation was observed between RC and CD4 cell count in chronic infection (R = −0.17; P < 0.0001), suggesting that Gag-Protease RC could increase over the disease course. Notably, this association was stronger for individuals who expressed B*57, B*58, or B*13 (R = −0.27; P = 0.004). Taken together, these data indicate that certain protective HLA alleles contribute to early defects in HIV-1 fitness through the selection of detrimental mutations in Gag; however, these effects wane as compensatory mutations accumulate in chronic infection. The long-term control of HIV-1 in some persons who express protective alleles suggests that early fitness hits may provide lasting benefits.The host immune response elicited by CD8⁺ cytotoxic T lymphocytes (CTLs) is a major contributor to viral control following human immunodeficiency virus type 1 (HIV-1) infection (6, 39), but antiviral pressure exerted by CTLs is diminished by the selection of escape mutations in targeted regions throughout the viral proteome (7, 18, 29, 35, 41, 45, 57). A comprehensive identification of HLA-associated viral polymorphisms has recently been achieved through population-based analyses of HIV-1 sequences and HLA class I types from different cohorts worldwide (3, 8, 13-15, 34, 43, 50, 56, 63). However, despite improved characterization of the sites and pathways of immune escape, effective ways to incorporate these findings into immunogen design remain an area of debate. A better understanding of the impact of escape mutations on viral fitness may provide novel directions for HIV-1 vaccines that are designed to attenuate pathogenesis.The development of innovative vaccine strategies that can overcome the extreme diversity of HIV is a key priority (4). One proposed approach is to target the most conserved T-cell epitopes, which presumably cannot escape from CTL pressure easily due to structural or functional constraints on the viral protein (55). Complementary approaches include the design of polyvalent and/or mosaic immunogens that incorporate commonly observed viral diversity (4, 38) or the specific targeting of vulnerable regions of the viral proteome that do escape but only at a substantial cost to viral replication capacity (RC) (1, 40). A chief target of such vaccine approaches is the major HIV-1 structural protein Gag, which is known to be highly immunogenic and to elicit CTL responses that correlate with the natural control of infection (22, 36, 66). Indeed, several lines of evidence support a relationship between the selection of CTL escape mutations and reduced HIV-1 fitness. These include the reversion of escape mutations following transmission to an HLA-mismatched recipient who cannot target the epitope (19, 24, 41) as well as reduced plasma viral load (pVL) set point following the transmission of certain escape variants from donors who expressed protective HLA alleles (17, 27). Notably, these in vivo observations have been made most often for variations within Gag that are attributed to CTL responses restricted by the protective alleles HLA-B*57 and -B*5801 (17, 19, 27, 41). Most recently, reduced in vitro RCs of clinical isolates and/or engineered strains encoding single or multiple escape mutations in Gag selected in the context of certain protective HLA alleles, including B*57, B*5801, B*27, and B*13, have been demonstrated (9, 10, 42, 53, 59, 62). Despite these efforts, the goal of a T-cell vaccine that targets highly conserved and attenuation-inducing sites is hampered by a lack of knowledge concerning the contribution of most escape mutations to HIV-1 fitness as well as a poor understanding of the relative influence of HLA on the viral RC at different stages of infection.The mutability of HIV-1 permits the generation of progeny viruses encoding compensatory mutations that restore normal protein function and/or viral fitness. Detailed studies have demonstrated that the in vitro RC of escape variants in human and primate immunodeficiency viruses can be enhanced by the addition of secondary mutations outside the targeted epitope (10, 20, 52, 59, 65). Thus, vaccine strategies aimed at attenuating HIV-1 must also consider, among other factors, the frequency, time course, and extent to which compensation might overcome attenuation mediated by CTL-induced escape. Despite its anticipated utility for HIV-1 vaccine design, systematic studies to examine the consequences of naturally occurring CTL escape and compensatory mutations on viral RC have not been undertaken.We have described previously an in vitro recombinant viral assay to examine the impact of Gag-Protease mutations on HIV-1 RC (47, 49). Gag and protease have been included in each virus to minimize the impact of sequence polymorphisms at Gag cleavage sites, which coevolve with changes in protease (5, 37). Using this approach, we have demonstrated that viruses derived from HIV-1 controllers replicated significantly less well than those derived from noncontrollers and that these differences were detectable at both the acute/early (49) and chronic (47) stages. Escape mutations in Gag associated with the protective HLA-B*57 allele, as well as putative compensatory mutations outside known CTL epitopes, contributed to this difference in RC (47). However, substantial variability was observed for viruses from controllers and noncontrollers, indicating that additional factors were likely to be involved. Benefits of this assay include its relatively high-throughput capacity as well as the fact that clinically derived HIV-1 sequences are used in their entirety. Thus, it is possible to examine a large number of “real-world” Gag-Protease sequences, to define an RC value for each one, and to identify sequences within the population of recombinant strains that are responsible for RC differences.Here, we use this recombinant virus approach to examine the contribution of HLA-associated immune pressure on Gag-Protease RC during acute/early (n = 66) and chronic (n = 803) infections in the context of naturally occurring HIV-1 subtype B isolates from untreated individuals. In a recent report (64), we employed this system to examine the Gag-Protease RC in a similar cohort of chronic HIV-1 subtype C-infected individuals. The results of these studies provide important insights into the roles of immune pressure and fitness constraints on HIV-1 evolution that may contribute to the rational design of an effective vaccine.     

Late Domain-Independent Rescue of a Release-Deficient Moloney Murine Leukemia Virus by the Ubiquitin Ligase Itch

Moloney murine leukemia virus (MoMLV) Gag utilizes its late (L) domain motif PPPY to bind members of the Nedd4-like ubiquitin ligase family. These interactions recruit components of the cell''s budding machinery that are critical for virus release. MoMLV Gag contains two additional L domains, PSAP and LYPAL, that are believed to drive residual MoMLV release via interactions with cellular proteins Tsg101 and Alix, respectively. We found that overexpression of Tsg101 or Alix failed to rescue the release of PPPY-deficient MoMLV via these other L domains. However, low-level expression of the ubiquitin ligase Itch potently rescued the release and infectivity of MoMLV lacking PPPY function. In contrast, other ubiquitin ligases such as WWP1, Nedd4.1, Nedd4.2, and Nedd4.2s did not rescue this release-deficient virus. Efficient rescue required the ubiquitin ligase activity of Itch and an intact C2 domain but not presence of the endophilin-binding site. Additionally, we found Itch to immunoprecipitate with MoMLV Gag lacking the PPPY motif and to be incorporated into rescued MoMLV particles. The PSAP and LYPAL motifs were dispensable for Itch-mediated virus rescue, and their absence did not affect the incorporation of Itch into the rescued particles. Itch-mediated rescue of release-defective MoMLV was sensitive to inhibition by dominant-negative versions of ESCRT-III components and the VPS4 AAA ATPase, indicating that Itch-mediated correction of MoMLV release defects requires the integrity of the host vacuolar sorting protein pathway. RNA interference knockdown of Itch suppressed the residual release of the MoMLV lacking the PPPY motif. Interestingly, Itch stimulation of the PPPY-deficient MoMLV release was accompanied by the enhancement of Gag ubiquitination and the appearance of new ubiquitinated Gag proteins in virions. Together, these results suggest that Itch can facilitate MoMLV release in an L domain-independent manner via a mechanism that requires the host budding machinery and involves Gag ubiquitination.Retroviruses require access to the host budding machinery to exit the cell (5, 13, 40). To this end, retroviral Gag polyproteins use short sequences called late (L) domains to promote virus release by recruiting members of the host vacuolar protein sorting (vps) machinery. In the cell, vps proteins are involved in membrane dynamics that facilitate the separation of daughter cells at the completion of cytokinesis (9, 39) and the budding of vesicles into endosomal compartments or multivesicular bodies (MVB) (2, 23), a process topologically similar to virus budding (57). Class E vps proteins are organized into three heteromeric endosomal complexes (called endosomal sorting complexes) required for transport, namely, ESCRT-I, -II, and -III (2). In the current model for budding, sequential recruitment of ESCRT components on the cytoplasmic face of the membrane facilitates vesicle invagination into MVB compartments and viral egress from the cell (2). The disassembly of ESCRT-III components is catalyzed by the activity of VPS4 AAA-type ATPase, which in turn is presumed to trigger membrane fission events (3, 50). Any disruption in this sequence, such as mutations in L domain motifs or dominant-negative interference with the function of ESCRT-III members or the VPS4 ATPase, adversely affects virus release. This indicates that Gag interactions with the ESCRT machinery are necessary for virus budding and separation from the cell (19, 21, 34, 49, 57).Currently, three types of L domain motifs have been identified: PT/SAP, LYPX_nL, and PPPY. All retroviral Gag molecules contain at least one of these motifs, as multiple L domains are believed to synergistically function to ensure efficient viral release. Moloney murine leukemia virus (MoMLV) Gag carries all three L domain motifs, PSAP, LYPAL, and PPPY, which bind the vps protein Tsg101, the ESCRT-associated protein Alix (46), and members of the Nedd4-ubiquitin ligase family (33), respectively. In HIV-1, the PTAP motif in the p6 region of Gag binds Tsg101 (16, 56), which functions in viral budding (16, 35) as a member of ESCRT-I (16, 36, 57). The LYPX_nL motif is also located in p6 and is the binding site for Alix (49, 57), a protein that also interacts with the nucleocapsid domain of HIV-1 Gag (14, 43) and links Gag to components of ESCRT-III (14). Similarly, the human T-cell leukemia virus (HTLV-I) Gag carries PPPY and PTAP L domains, which both contribute to efficient HTLV-1 release (6, 7, 21). The PPPY L domain motif, which is found in numerous retroviral Gag polyproteins (6, 7, 19, 21, 27, 28, 61, 62), plays a critical role in MoMLV release, as mutations disrupting its sequence lead to significant decreases in virus budding and release (33, 62). PSAP and LYPAL, the additional L domain motifs, are believed to serve little to no role in the release of MoMLV Gag virus-like particles (45, 46).The role of Nedd4-like ubiquitin ligases in budding events was initially established by data obtained with the yeast Nedd4-like ligase Rsp5, an enzyme that ubiquitinates surface proteins, thus signaling their incorporation into the MVB pathway (26). From retroviral budding studies, multiple findings support the notion that Nedd4-like ubiquitin ligases link PPPY-containing Gag proteins to the host ESCRT machinery. For example, mutations in the PPPY motif or expression of dominant-negative versions of Nedd4-like ligases resulted in budding defects similar to those seen upon interference with the function of ESCRT-III members (7, 21, 27, 28, 33, 62). Overexpression of Nedd4-like ligases WWP1 and Itch corrected the budding defects of a MoMLV PPPY mutant that retained residual binding to both ligases (33). Also, when transplanted to a heterologous retroviral Gag, the PPPY L domain creates a requirement for Nedd4-like ubiqutin ligase activity to facilitate viral release that is dependent on the presence of a functional ESCRT pathway (63). Collectively, these observations support the notion that Nedd4-like ubiquitin ligases link retroviral Gag polyproteins to components of the ESCRT pathway necessary for budding.Both endosomal and viral budding require the ubiquitin conjugation properties of Nedd4-like ligases, indicating that ubiquitin transfer to a key protein(s) is necessary to promote budding. A role for Gag ubiquitination in viral budding has been suggested (8, 20, 22, 48). In fact, ubiquitin attachment to equine infectious anemia virus (EIAV) Gag can substitute for the lack of L domains and rescue viral budding (25), suggesting that ubiquitin molecules conjugated to Gag can signal the recruitment of the host ESCRT machinery. For feline immunodeficiency virus, efficient budding seems to require L domain-dependent ubiquitination of Gag proteins (8) that is independent of the L domain ability to directly recruit Nedd4-like ubiquitin ligases (i.e., by means of the PT/SAP L domain motif) (8). Similarly, ubiquitination of HTLV-1 Gag was also shown to play a significant role in viral release (22). Conversely, data arguing in favor of a role for the ubiquitination of transacting factors, but not Gag, in the facilitation of viral budding have also been reported (10, 63). Thus Gag polyproteins recruit, in a PPPY-dependent or -independent manner, enzymatically active Nedd4-like ubiquitin ligases that conjugate ubiquitin molecules to Gag or to Gag-binding host factors. Such interactions, whether direct or indirect, are believed to link the viral protein to the host ESCRT pathway and facilitate release.In addition to the well-characterized cellular proteins that bind primary L domain motifs, retroviral Gag can recruit other host factors, either via secondary L domains or independently of L domains (10, 24, 29, 55, 59). These cellular factors are believed to promote virus production by facilitating Gag protein trafficking to the plasma membrane and/or providing additional L domain-independent links to the host vps pathway. Examples of these parallel pathways are illustrated in the rescue of a budding-defective HIV-1 lacking the PTAP domain by overexpression of Alix (15, 54) and in the remarkably potent rescue of HIV-1 lacking all known L domains by the overexpression of Nedd4.2s, a Nedd4.2 isoform that belongs to the Nedd4-like ubiquitin ligase family (10, 55). In this study, we sought to identify host cell factors that rescue budding defects of the MoMLV mutant lacking the PPPY motif (MoMLV AAAY mutant). Our studies provide evidence that Itch overexpression rescued budding and infectivity defects of the MoMLV AAAY mutant virus, indicating that Gag can recruit the ubiquitin ligase Itch in an L domain-independent manner to facilitate MoMLV release via a mechanism that involves Gag ubiquitination.     

Human Immunodeficiency Virus Type 1 Nucleocapsid p1 Confers ESCRT Pathway Dependence

To facilitate the release of infectious progeny virions, human immunodeficiency virus type 1 (HIV-1) exploits the Endosomal Sorting Complex Required for Transport (ESCRT) pathway by engaging Tsg101 and ALIX through late assembly (L) domains in the C-terminal p6 domain of Gag. However, the L domains in p6 are known to be dispensable for efficient particle production by certain HIV-1 Gag constructs that have the nucleocapsid (NC) domain replaced by a foreign dimerization domain to substitute for the assembly function of NC. We now show that one such L domain-independent HIV-1 Gag construct (termed Z_WT) that has NC-p1-p6 replaced by a leucine zipper domain is resistant to dominant-negative inhibitors of the ESCRT pathway that block HIV-1 particle production. However, Z_WT became dependent on the presence of an L domain when NC-p1-p6 was restored to its C terminus. Furthermore, when the NC domain was replaced by a leucine zipper, the p1-p6 region, but not p6 alone, conferred sensitivity to inhibition of the ESCRT pathway. In an authentic HIV-1 Gag context, the effect of an inhibitor of the ESCRT pathway on particle production could be alleviated by deleting a portion of the NC domain together with p1. Together, these results indicate that the ESCRT pathway dependence of HIV-1 budding is determined, at least in part, by the NC-p1 region of Gag.Human immunodeficiency virus type 1 (HIV-1) and other retroviruses hijack the cellular Endosomal Sorting Complex Required for Transport (ESCRT) pathway to promote the detachment of virions from the cell surface and from each other (3, 21, 42, 44, 47). The ESCRT pathway was initially identified based on its requirement for the sorting of ubiquitinated cargo into multivesicular bodies (MVB) (50, 51). During MVB biogenesis, the ESCRT pathway drives the membrane deformation and fission events required for the inward vesiculation of the limiting membrane of this organelle (26, 29, 50, 51). More recently, it emerged that the ESCRT pathway is also essential for the normal abscission of daughter cells during the final stage of cell division (10, 43). Most of the components of the ESCRT pathway are involved in the formation of four heteromeric protein complexes termed ESCRT-0, ESCRT-I, ESCRT-II, and ESCRT-III. Additional components include ALIX, which interacts both with ESCRT-I and ESCRT-III, and the AAA ATPase Vps4, which mediates the disassembly of ESCRT-III (29, 42).The deformation and scission of endocytic membranes is thought to be mediated by ESCRT-III, which, together with Vps4, constitutes the most conserved element of the pathway (23, 26, 42). Indeed, it was recently shown that purified yeast ESCRT-III induces membrane deformation (52), and in another study three subunits of yeast ESCRT-III were sufficient to promote the formation of intralumenal vesicles in an in vitro assay (61). In mammals, ESCRT-III is formed by the charged MVB proteins (CHMPs), which are structurally related and tightly regulated through autoinhibition (2, 33, 46, 53, 62). The removal of an inhibitory C-terminal domain induces polymerization and association with endosomal membranes and converts CHMPs into potent inhibitors of retroviral budding (34, 46, 53, 60, 62). Alternatively, CHMPs can be converted into strong inhibitors of the ESCRT pathway and of HIV-1 budding through the addition of a bulky tag such as green fluorescent protein (GFP) or red fluorescent protein (RFP) (27, 36, 39, 54). Retroviral budding in general is also strongly inhibited by catalytically inactive Vps4 (22, 41, 55), or upon Vsp4B depletion (31), confirming the crucial role of ESCRT-III.Retroviruses engage the ESCRT pathway through the activity of so-called late assembly (L) domains in Gag. In the case of HIV-1, the primary L domain maps to a conserved PTAP motif in the C-terminal p6 domain of Gag (24, 28) and interacts with the ESCRT-I component Tsg101 (15, 22, 40, 58). HIV-1 p6 also harbors an auxiliary L domain of the LYPx_nL type, which interacts with the V domain of ALIX (20, 35, 39, 54, 59, 63). Interestingly, Tsg101 binding site mutants of HIV-1 can be fully rescued through the overexpression of ALIX, and this rescue depends on the ALIX binding site in p6 (20, 56). In contrast, the overexpression of a specific splice variant of the ubiquitin ligase Nedd4-2 has been shown to rescue the release and infectivity of HIV-1 mutants lacking all known L domains in p6 (12, 57). Nedd4 family ubiquitin ligases had previously been implicated in the function of PPxY-type L domains, which also depend on an intact ESCRT pathway for function (4, 32, 38). However, HIV-1 Gag lacks PPxY motifs, and the WW domains of Nedd4-2, which mediate its interaction with PPxY motifs, are dispensable for the rescue of HIV-1 L domain mutants (57).ALIX also interacts with the nucleocapsid (NC) region of HIV-1 Gag (18, 49), which is located upstream of p6 and the p1 spacer peptide. ALIX binds HIV-1 NC via its Bro1 domain, and the capacity to interact with NC and to stimulate the release of a minimal HIV-1 Gag construct is shared among widely divergent Bro1 domain proteins (48). Based on these findings and the observation that certain mutations in NC cause a phenotype that resembles that of L domain mutants, it has been proposed that NC cooperates with p6 to recruit the machinery required for normal HIV-1 budding (18, 49).NC also plays a role in Gag polyprotein multimerization, and this function of NC depends on its RNA-binding activity (5-8). It has been proposed that the role of the NC-nucleic acid interaction during assembly is to promote the formation of Gag dimers (37), and HIV-1 assembly in the absence of NC can indeed be efficiently rescued by leucine zipper dimerization domains (65). Surprisingly, in this setting the L domains in p6 also became dispensable, since particle production remained efficient even when the entire NC-p1-p6 region of HIV-1 Gag was replaced by a leucine zipper (1, 65). These findings raised the possibility that the reliance of wild-type (WT) HIV-1 Gag on a functional ESCRT pathway is, at least in part, specified by NC-p1-p6. However, it also remained possible that the chimeric Gag constructs engaged the ESCRT pathway in an alternative manner.In the present report, we provide evidence supporting the first of those two possibilities. Particle production became independent of ESCRT when the entire NC-p1-p6 region was replaced by a leucine zipper, and reversion to ESCRT dependence was shown to occur as a result of restoration of p1-p6 but not of p6 alone. Furthermore, although the deletion of p1 alone had little effect in an authentic HIV-1 Gag context, the additional removal of a portion of NC improved particle production in the presence of an inhibitor of the ESCRT pathway. Together, these data imply that the NC-p1 region plays an important role in the ESCRT-dependence of HIV-1 particle production.     

Activation of the Inositol (1,4,5)-Triphosphate Calcium Gate Receptor Is Required for HIV-1 Gag Release

The structural precursor polyprotein, Gag, encoded by all retroviruses, including the human immunodeficiency virus type 1 (HIV-1), is necessary and sufficient for the assembly and release of particles that morphologically resemble immature virus particles. Previous studies have shown that the addition of Ca²⁺ to cells expressing Gag enhances virus particle production. However, no specific cellular factor has been implicated as mediator of Ca²⁺ provision. The inositol (1,4,5)-triphosphate receptor (IP3R) gates intracellular Ca²⁺ stores. Following activation by binding of its ligand, IP3, it releases Ca²⁺ from the stores. We demonstrate here that IP3R function is required for efficient release of HIV-1 virus particles. Depletion of IP3R by small interfering RNA, sequestration of its activating ligand by expression of a mutated fragment of IP3R that binds IP3 with very high affinity, or blocking formation of the ligand by inhibiting phospholipase C-mediated hydrolysis of the precursor, phosphatidylinositol-4,5-biphosphate, inhibited Gag particle release. These disruptions, as well as interference with ligand-receptor interaction using antibody targeted to the ligand-binding site on IP3R, blocked plasma membrane accumulation of Gag. These findings identify IP3R as a new determinant in HIV-1 trafficking during Gag assembly and introduce IP3R-regulated Ca²⁺ signaling as a potential novel cofactor in viral particle release.Assembly of the human immunodeficiency virus (HIV) is determined by a single gene that encodes a structural polyprotein precursor, Gag (71), and may occur at the plasma membrane or within late endosomes/multivesicular bodies (LE/MVB) (7, 48, 58; reviewed in reference 9). Irrespective of where assembly occurs, the assembled particle is released from the plasma membrane of the host cell. Release of Gag as virus-like particles (VLPs) requires the C-terminal p6 region of the protein (18, 19), which contains binding sites for Alix (60, 68) and Tsg101 (17, 37, 38, 41, 67, 68). Efficient release of virus particles requires Gag interaction with Alix and Tsg101. Alix and Tsg101 normally function to sort cargo proteins to LE/MVB for lysosomal degradation (5, 15, 29, 52). Previous studies have shown that addition of ionomycin, a calcium ionophore, and CaCl₂ to the culture medium of cells expressing Gag or virus enhances particle production (20, 48). This is an intriguing observation, given the well-documented positive role for Ca²⁺ in exocytotic events (33, 56). It is unclear which cellular factors might regulate calcium availability for the virus release process.Local and global elevations in the cytosolic Ca²⁺ level are achieved by ion release from intracellular stores and by influx from the extracellular milieu (reviewed in reference 3). The major intracellular Ca²⁺ store is the endoplasmic reticulum (ER); stores also exist in MVB and the nucleus. Ca²⁺ release is regulated by transmembrane channels on the Ca²⁺ store membrane that are formed by tetramers of inositol (1,4,5)-triphosphate receptor (IP3R) proteins (reviewed in references 39, 47, and 66). The bulk of IP3R channels mediate release of Ca²⁺ from the ER, the emptying of which signals Ca²⁺ influx (39, 51, 57, 66). The few IP3R channels on the plasma membrane have been shown to be functional as well (13). Through proteomic analysis, we identified IP3R as a cellular protein that was enriched in a previously described membrane fraction (18) which, in subsequent membrane floatation analyses, reproducibly cofractionated with Gag and was enriched in the membrane fraction only when Gag was expressed. That IP3R is a major regulator of cytosolic calcium concentration (Ca²⁺) is well documented (39, 47, 66). An IP3R-mediated rise in cytosolic Ca²⁺ requires activation of the receptor by a ligand, inositol (1,4,5)-triphosphate (IP3), which is produced when phospholipase C (PLC) hydrolyzes phosphatidylinositol-4,5-bisphosphate [PI(4,5)P₂] at the plasma membrane (16, 25, 54). Paradoxically, PI(4,5)P₂ binds to the matrix (MA) domain in Gag (8, 55, 59), and the interaction targets Gag to PI(4,5)P₂-enriched regions on the plasma membrane; these events are required for virus release (45). We hypothesized that PI(4,5)P₂ binding might serve to target Gag to plasma membrane sites of localized Ca²⁺ elevation resulting from PLC-mediated PI(4,5)P₂ hydrolysis and IP3R activation. This idea prompted us to investigate the role of IP3R in Gag function.Here, we show that HIV-1 Gag requires steady-state levels of IP3R for its efficient release. Three isoforms of IP3R, types 1, 2, and 3, are encoded in three independent genes (39, 47). Types 1 and 3 are expressed in a variety of cells and have been studied most extensively (22, 39, 47, 73). Depletion of the major isoforms in HeLa or COS-1 cells by small interfering RNA (siRNA) inhibited viral particle release. Moreover, we show that sequestration of the IP3R activating ligand or blocking ligand formation also inhibited Gag particle release. The above perturbations, as well as interfering with receptor expression or activation, led to reduced Gag accumulation at the cell periphery. The results support the conclusion that IP3R activation is required for efficient HIV-1 viral particle release.     

Balancing Reversion of Cytotoxic T-Lymphocyte and Neutralizing Antibody Escape Mutations within Human Immunodeficiency Virus Type 1 Env upon Transmission

Human immunodeficiency virus type 1 (HIV-1) envelope protein (Env) is subject to both neutralizing antibody (NAb) and CD8 T-cell (cytotoxic T-lymphocyte [CTL]) immune pressure. We studied the reversion of the Env CTL escape mutant virus to the wild type and the relationship between the reversion of CTL mutations with N-linked glycosylation site (NLGS)-driven NAb escape in pigtailed macaques. Env CTL mutations either did not revert to the wild type or only transiently reverted 5 to 7 weeks after infection. The CTL escape mutant reversion was coincident, for the same viral clones, with the loss of NLGS mutations. At one site studied, both CTL and NLGS mutations were needed to confer NAb escape. We conclude that CTL and NAb escape within Env can be tightly linked, suggesting opportunities to induce effective multicomponent anti-Env immunity.CD8 T-cell responses against human immunodeficiency virus (HIV) have long been observed to select for viral variants that avoid cytotoxic T-lymphocyte (CTL) recognition (2, 5, 15, 18, 27). These immune escape mutations may, however, result in reduced replication competence (“fitness cost”) (11, 20, 26). CTL escape variants have been shown to revert to the wild type (WT) upon passage to major histocompatibility complex-mismatched hosts, both in macaques with simian immunodeficiency virus (SIV) or chimeric SIV/HIV (SHIV) infection (11, 12) and in humans with HIV type 1 (HIV-1) infection (1, 19).Most analyses of CTL escape and reversion have studied Gag CTL epitopes known to facilitate control of viremia (7, 14, 21, 30). Fewer analyses have studied Env-specific CTL epitopes. Recent sequencing studies suggest the potential for mutations within predicted HIV-1 Env-specific CTL epitopes to undergo reversion to the WT (16, 23). Env-specific CTL responses may, however, have less impact on viral control of both HIV-1 and SIV/SHIV than do Gag CTL responses (17, 24, 25), presumably reflecting either less-potent inhibition of viral replication or minimal fitness cost of escape (9).Serial viral escape from antibody pressure also occurs in both macaques and humans (3, 13, 28). Env is extensively glycosylated, and this “evolving glycan shield” can sterically block antibody binding without mutation at the antibody-binding site (8, 16, 31). Mutations at glycosylation sites, as well as other mutations, are associated with escape from neutralizing antibody (NAb) responses (4, 13, 29). Mutations in the amino acid sequences of N-linked glycosylation sites (NLGS) can alter the packing of the glycan cloud that surrounds the virion, by a loss, gain, or shift of an NLGS (32), thus facilitating NAb escape.Env is the only viral protein targeted by both CTL and NAb responses. The serial viral escape from both Env-specific CTL and NAb responses could have implications for viral fitness and the reversion of multiple mutations upon transmission to naïve hosts.We previously identified three common HIV-1 Env-specific CD8 T cell epitopes, RY8_788-795, SP9_110-118, and NL9_671-679, and their immune escape patterns in pigtail macaques (Macaca nemestrina) infected with SHIV_mn229 (25). SHIV_mn229 is a chimeric virus constructed from an SIV_mac239 backbone and an HIV-1_HXB2 env fragment that was passaged through macaques to become pathogenic (11). This earlier work provided an opportunity for detailed studies of how viruses with Env-specific CTL escape mutations, as well as mutations in adjacent NLGS, evolve when transmitted to naïve pigtail macaques.     

The ESCRT-Associated Protein Alix Recruits the Ubiquitin Ligase Nedd4-1 To Facilitate HIV-1 Release through the LYPXnL L Domain Motif

The p6 region of HIV-1 Gag contains two late (L) domains, PTAP and LYPX_nL, that bind Tsg101 and Alix, respectively. Interactions with these two cellular proteins recruit members of the host''s fission machinery (ESCRT) to facilitate HIV-1 release. Other retroviruses gain access to the host ESCRT components by utilizing a PPXY-type L domain that interacts with cellular Nedd4-like ubiquitin ligases. Despite the absence of a PPXY motif in HIV-1 Gag, interaction with the ubiquitin ligase Nedd4-2 was recently shown to stimulate HIV-1 release. We show here that another Nedd4-like ubiquitin ligase, Nedd4-1, corrected release defects resulting from the disruption of PTAP (PTAP⁻), suggesting that HIV-1 Gag also recruits Nedd4-1 to facilitate virus release. Notably, Nedd4-1 remediation of HIV-1 PTAP⁻ budding defects is independent of cellular Tsg101, implying that Nedd4-1''s function in HIV-1 release does not involve ESCRT-I components and is therefore distinct from that of Nedd4-2. Consistent with this finding, deletion of the p6 region decreased Nedd4-1-Gag interaction, and disruption of the LYPX_nL motif eliminated Nedd4-1-mediated restoration of HIV-1 PTAP⁻. This result indicated that both Nedd4-1 interaction with Gag and function in virus release occur through the Alix-binding LYPX_nL motif. Mutations of basic residues located in the NC domain of Gag that are critical for Alix''s facilitation of HIV-1 release, also disrupted release mediated by Nedd4-1, further confirming a Nedd4-1-Alix functional interdependence. In fact we found that Nedd4-1 binds Alix in both immunoprecipitation and yeast-two-hybrid assays. In addition, Nedd4-1 requires its catalytic activity to promote virus release. Remarkably, RNAi knockdown of cellular Nedd4-1 eliminated Alix ubiquitination in the cell and impeded its ability to function in HIV-1 release. Together our data support a model in which Alix recruits Nedd4-1 to facilitate HIV-1 release mediated through the LYPX_nL/Alix budding pathway via a mechanism that involves Alix ubiquitination.Retroviral Gag polyproteins bear short conserved sequences that control virus budding and release. As such, these motifs have been dubbed late or L domains (49). Three types of L domains have thus far been characterized: PT/SAP, LYPX_nL, and PPPY motifs (5, 9, 32). They recruit host proteins known to function in the vacuolar protein sorting (vps) of cargo proteins and the generation of multivesicular bodies (MVB) compartments (2). It is currently accepted that budding of vesicles into MVB involves the sequential recruitment of endosomal sorting complexes required for transport (ESCRT-I, -II, and -III) and the activity of the VPS4 AAA-ATPase (22). These sorting events are believed to be triggered by recognition of ubiquitin molecules conjugated to cargo proteins (20, 24, 41). For retrovirus budding, L domain motifs are the primary signals in Gag that elicit the recruitment of ESCRT components to facilitate viral budding. Consequently, mutations in L domain motifs or dominant-negative interference with the function of ESCRT-III members or the VPS4 ATPase adversely affect virus release. This indicates that Gag interactions with the ESCRT machinery are necessary for virus budding and separation from the cell (7, 10, 15, 16, 21, 28, 44).Two late domains have been identified within the p6 region of human immunodeficiency virus type 1 (HIV-1) Gag protein: the PTAP and LYPX_nL motifs. The PTAP motif binds the cellular protein Tsg101 (15, 39, 40, 47), whereas the LYPX_nL motif is the docking site for Alix (44). Tsg101 functions in HIV-1 budding (15) as a member of ESCRT-I (30, 48), a soluble complex required for the generation of MVB. This process is topologically similar to HIV-1 budding and requires the recruitment of ESCRT-III members called the charged-multivesicular body proteins (3, 29, 48) and the activity of the VPS4 AAA-ATPase (4, 48). In addition to binding the LYPX_nL motif, Alix also interacts with the nucleocapsid (NC) domain of HIV-1 Gag (13, 38), thus linking Gag to components of ESCRT-III that are critical for virus release (13).Other retroviruses, including the human T-cell leukemia virus (HTLV) and the Moloney murine leukemia virus (MoMLV), utilize the PPPY-type L domain to efficiently release virus (7, 26, 51). The PPPY motif binds members of the Nedd4-like ubiquitin ligase family (6, 7, 16, 19, 25, 43), whose normal cellular function is to ubiquitinate cargo proteins and target them into the MVB sorting pathway (11, 12, 20). Members of the Nedd4-like ubiquitin ligase family include Nedd4-1, Nedd4-2 (also known as Nedd4L), WWP-1/2, and Itch. They contain three distinct domains: an N-terminal membrane binding C2 domain (12), a central PPPY-interacting WW domain (43), and a C-terminal HECT domain that contains the ubiquitin ligase active site (42). The functional requirement for the binding of Nedd4-like ubiquitin ligases to the PPPY motif in virus budding has been demonstrated (7, 16, 18, 19, 25, 26, 28, 50, 51). Overexpression of dominant-negative mutants of Nedd4-like ligases, ESCRT-III components, or VPS4 cause a potent inhibition of PPPY-dependent virus release (7, 19, 29, 31, 52) and induce assembly and budding defects similar to those observed after perturbation of the PPPY motif (26, 51). These observations demonstrated that Nedd4-like ligases connect Gag encoding PPPY motif to ESCRT-III and VPS4 proteins to facilitate virus release.Whereas the role of Nedd4-like ubiquitin ligases in virus budding has been established, the protein interactions that link them to the cell''s ESCRT-III pathway are still unknown. Evidence for associations of Nedd4-like ligases with ESCRT proteins have been previously reported and include: the binding of Nedd4-like ubiquitin ligases LD1 and Nedd4-1 to ESCRT-I member Tsg101 (6, 31), the colocalization of multiple Nedd4-like ubiquitin ligases with endosomal compartments (1, 28), the requirement of the cell''s ESCRT pathway for Itch mediated L domain independent stimulation of MoMLV release (23), and the ubiquitination of ESCRT-I components with a shorter isoform, Nedd4-2s (8). Therefore, Nedd4-like ubiquitin ligase interactions with members of the cell''s ESCRT pathway may provide retroviral Gag with access to the host budding machinery required for virus release.Although HIV-1 Gag does not carry the PPPY canonical sequence known to interact with Nedd4-like ubiquitin ligases, both Nedd4-1 and Nedd4-2 were shown to restore the release of the HIV-1 PTAP⁻ mutant, albeit Nedd4-1 with less efficiency than Nedd4-2 (8, 46). These findings suggested that HIV-1 might utilize cellular Nedd4-like ubiquitin ligases to increase virus release. We present here evidence demonstrating that Nedd4-1 interacts with Gag and enhances HIV-1 PTAP⁻ virus release. Furthermore, we show that Nedd4-1''s function in HIV-1 release is distinct from that of Nedd4-2 in both its viral and cellular requirements. Notably, we found that Nedd4-1 enhancement of HIV-1 release requires the Alix-binding LYPX_nL L domain motif in the p6 region and basic residues in the NC domain. In addition, Alix''s facilitation of HIV-1 release requires cellular Nedd4-1, since mutations in NC that prevented Alix-mediated HIV-1 release also eliminated release by overexpression of Nedd4-1. This suggested a Nedd4-1-Alix physical and functional interdependence. In agreement with this, we found Nedd4-1 to bind and ubiquitinate Alix in the cell. Taken together, these results support a model in which Alix recruits Nedd4-1 to facilitate late steps of HIV-1 release through the LYPX_nL L domain motif via a mechanism that involves Alix ubiquitination.     

Vaccination reduces simian-human immunodeficiency virus sequence reversion through enhanced viral control

It has been suggested that vaccination prior to infection may direct the mutational evolution of human immunodeficiency virus type 1 (HIV-1) to a less fit virus, resulting in an attenuated course of disease. The present study was initiated to explore whether prior immunization might prevent the reversion of the virus to the wild-type form. Mamu-A*01 monkeys were vaccinated to generate a cytotoxic T-lymphocyte response to the immunodominant Gag p11C epitope and were then challenged with a cloned pathogenic CXCR4-tropic simian-human immunodeficiency virus (SHIV) expressing a mutant Gag p11C sequence (Δp11C SHIV). The epitopic and extraepitopic compensatory mutations introduced into gag of Δp11C SHIV resulted in attenuated replicative capacity and eventual reversions to the wild-type Gag p11C sequence in naïve rhesus monkeys. However, in vaccinated rhesus monkeys, no reversions of the challenge virus were observed, an effect that may have been a consequence of significantly decreased viral replication rather than a redirection of the mutational evolution of the virus. These findings highlight the multifactorial pressures that affect the evolution of primate immunodeficiency viruses.CD8⁺ cytotoxic T-lymphocyte (CTL) responses are important for controlling replication of human immunodeficiency virus type 1 (HIV-1) in humans and simian immunodeficiency virus (SIV) in rhesus monkeys (6, 15, 19, 25, 32, 37, 39-41). However, the accumulation of mutations in dominant epitopes of these viruses can undermine this immune control (1, 8, 13, 18, 28). It has been proposed that a preexisting memory-specific CTL response elicited by vaccination prior to HIV-1/SIV infection might change the epitope specificity or the mutational pattern of the infecting virus (9). It is also possible that vaccine-induced cellular immunity might diminish the level of virus replication in individuals following infection and in doing so decrease the rate of accumulation of viral mutations and the likelihood of emergence of viruses that can escape CTL recognition.Our laboratory has previously described a rare SHIV-89.6P escape virus that contains a mutation in the dominant Mamu-A*01-restricted Gag p11C C-M (CTPYDINQM) epitope (3, 4). The emergence of this viral variant was associated with an increase in viral load and the eventual death of the previously vaccinated rhesus monkey 798. Analysis of the escape virus demonstrated a threonine-to-isoleucine mutation at amino acid position 47 (T47I) of the SIV capsid protein, which corresponds to position 2 of the Gag p11C epitope. This T47I mutation abrogated binding to the Mamu-A*01 class I molecule, allowing the virus to escape from recognition by the dominant epitope-specific CTL population (4). In addition to the T47I mutation, a downstream isoleucine-to-valine (I71V) substitution was found to be required for the viability of the escape virus in vitro (12, 29, 30, 42).The present studies were initiated to study the effects of prior vaccination on Gag p11C sequence reversion by infecting monkeys with a simian-human immunodeficiency virus (SHIV) clone containing the gag mutations found in the escape virus that evolved in monkey 798. We first explored the effects of these mutations in vivo by infecting naïve Mamu-A*01⁺ rhesus monkeys with a cloned SHIV (Δp11C SHIV) containing both the Gag p11C T47I mutation and the downstream I71V compensatory substitutions. We then determined whether vaccination prior to infection could generate a cellular immune response that might alter the expected pattern of virus mutation in the immunodominant Mamu-A*01-restricted Gag p11C epitope of Δp11C SHIV.     

Protective HLA Class I Alleles That Restrict Acute-Phase CD8+ T-Cell Responses Are Associated with Viral Escape Mutations Located in Highly Conserved Regions of Human Immunodeficiency Virus Type 1

The control of human immunodeficiency virus type 1 (HIV-1) associated with particular HLA class I alleles suggests that some CD8⁺ T-cell responses may be more effective than others at containing HIV-1. Unfortunately, substantial diversities in the breadth, magnitude, and function of these responses have impaired our ability to identify responses most critical to this control. It has been proposed that CD8 responses targeting conserved regions of the virus may be particularly effective, since the development of cytotoxic T-lymphocyte (CTL) escape mutations in these regions may significantly impair viral replication. To address this hypothesis at the population level, we derived near-full-length viral genomes from 98 chronically infected individuals and identified a total of 76 HLA class I-associated mutations across the genome, reflective of CD8 responses capable of selecting for sequence evolution. The majority of HLA-associated mutations were found in p24 Gag, Pol, and Nef. Reversion of HLA-associated mutations in the absence of the selecting HLA allele was also commonly observed, suggesting an impact of most CTL escape mutations on viral replication. Although no correlations were observed between the number or location of HLA-associated mutations and protective HLA alleles, limiting the analysis to mutations selected by acute-phase immunodominant responses revealed a strong positive correlation between mutations at conserved residues and protective HLA alleles. These data suggest that control of HIV-1 may be associated with acute-phase CD8 responses capable of selecting for viral escape mutations in highly conserved regions of the virus, supporting the inclusion of these regions in the design of an effective vaccine.Despite substantial advances in antiretroviral therapies, development of an effective human immunodeficiency virus type 1 (HIV-1) vaccine remains a critical goal (6, 39, 82). Unfortunately, current vaccine efforts have failed to reduce infection rates in humans (9, 75) and have only achieved modest decreases in viral loads in the simian immunodeficiency virus (SIV)/SHIV macaque model (21, 44, 81). A majority of these vaccine approaches have focused on inducing T-cell responses, utilizing large regions of the virus in an attempt to induce a broad array of immune responses (6, 34, 44, 81). While it is well established that CD8⁺ T-cell responses play a critical role in the containment of HIV-1 (45, 49, 67), supported in part by the strong association of particular HLA class I alleles with control of HIV (20, 33, 42, 61), it remains unclear which particular CD8⁺ T-cell responses are best able to control the virus and thus should be preferentially targeted by a vaccine. Studies comparing the magnitude, breadth, and function of CD8⁺ T-cell responses in subjects exhibiting either enhanced or poor control of HIV-1 have yielded few clues as to the specific factors associated with an effective CD8⁺ T-cell response (2, 28, 64, 67). Various differences in the functional capacity of T-cell responses have been observed in long-term nonprogressors (1, 26, 64), although it is possible that these differences may be reflective of an intact immune response, as opposed to having had directly enhanced immune control. As such, efforts are needed to identify factors or phenotypes associated with protective CD8⁺ T-cell responses in order to enable vaccines to induce the most effective responses.Recent studies have begun to suggest that the specificity of the CD8⁺ T-cell response, or the targeting of specific regions of the virus, may be associated with control of HIV-1. Preferential targeting of Gag, a structurally conserved viral protein responsible for multiple functions, has been associated with lower viral loads (25, 43, 56, 60, 77, 85). Furthermore, Kiepiela et al. (43) recently illustrated in a large cohort of 578 clade C-infected subjects that Gag-specific responses were associated with lowered viremia, in contrast to Env-specific responses, which were associated with higher viremia. These data are in line with previous observations that many of the major histocompatibility complex (MHC) class I alleles most strongly associated with control of HIV-1 and SIV, namely, HLA-B57, HLA-B27, and Mamu-A*01, restrict immunodominant CD8⁺ T-cell responses against the Gag protein (8, 10, 24, 63, 68, 83). However, other alleles associated with slower disease progression, such as HLA-B51 in humans and Mamu-B08 and B-17 in the rhesus macaque, do not immunodominantly target Gag, suggesting that targeting of some other regions of the virus may also be capable of eliciting control (8, 52-54). In addition, recent studies investigating the pattern of HIV-1-specific CD8⁺ T-cell responses during acute infection reveal that only a small subset of CD8⁺ T-cell responses restricted by any given HLA allele arise during acute infection and that there exist clear immunodominance patterns to these responses (8, 77, 85). Since control of HIV-1 is likely to be established or lost during the first few weeks of infection, these data suggest that potentially only a few key CD8⁺ T-cell responses may be needed to adequately establish early control of HIV-1.One of the major factors limiting the effectiveness of CD8⁺ T-cell responses is the propensity for HIV-1 to evade these responses through sequence evolution or viral escape (3, 13, 66). Even single point mutations within a targeted CD8 epitope can effectively abrogate recognition by either the HLA allele or the T-cell receptor. However, recent studies have begun to highlight that many sequence polymorphisms will revert to more common consensus residues upon transmission of HIV-1 to a new host, including many cytotoxic T-lymphocyte (CTL) escape mutations (4, 30, 33, 48, 50). Notably, the more rapidly reverting mutations have been observed to preferentially occur at conserved residues, indicating that structurally conserved regions of the virus may be particularly refractory to sequence changes (50). In support of these data, many CTL escape mutations have now been observed to directly impair viral replication (15, 23, 55, 74), in particular those known to either revert or require the presence of secondary compensatory mutations (15, 23, 73, 74). Taken together, these data suggest that, whereas CTL escape mutations provide a benefit to the virus to enable the evasion of host immune pressures, some of these mutations may come at a substantial cost to viral replication. These data may also imply that the association between Gag-specific responses and control of HIV-1 may be due to the targeting of highly conserved regions of the virus that are difficult to evade through sequence evolution.The propensity by which HIV-1 escapes CD8⁺ T-cell responses, and the reproducibility by which mutations arise at precise residues in targeted CD8 epitopes (3, 48), also enables the utilization of sequence data to predict which responses may be most capable of exerting immune selection pressure on the virus. Studies in HIV-1, SIV, and hepatitis C virus (16, 58, 65, 78) are now rapidly identifying immune-driven CTL escape mutations across these highly variable pathogens at the population level by correlating sequence polymorphisms in these viruses with the expression of particular HLA alleles. We provide here an analysis of HLA-associated mutations across the entire HIV-1 genome using a set of sequences derived from clade B chronically infected individuals. Through full-length viral genome coverage, these data provide an unbiased analysis of the location of these mutations and suggest that the control of HIV-1 by particular HLA alleles correlates with their ability to preferentially restrict early CD8⁺ T-cell responses capable of selecting for viral escape mutations at highly conserved residues of the virus. These data provide support for the inclusion of specific highly conserved regions of HIV-1 into vaccine antigens.     

Conserved and Variable Features of Gag Structure and Arrangement in Immature Retrovirus Particles

The assembly of retroviruses is driven by oligomerization of the Gag polyprotein. We have used cryo-electron tomography together with subtomogram averaging to describe the three-dimensional structure of in vitro-assembled Gag particles from human immunodeficiency virus, Mason-Pfizer monkey virus, and Rous sarcoma virus. These represent three different retroviral genera: the lentiviruses, betaretroviruses and alpharetroviruses. Comparison of the three structures reveals the features of the supramolecular organization of Gag that are conserved between genera and therefore reflect general principles of Gag-Gag interactions and the features that are specific to certain genera. All three Gag proteins assemble to form approximately spherical hexameric lattices with irregular defects. In all three genera, the N-terminal domain of CA is arranged in hexameric rings around large holes. Where the rings meet, 2-fold densities, assigned to the C-terminal domain of CA, extend between adjacent rings, and link together at the 6-fold symmetry axis with a density, which extends toward the center of the particle into the nucleic acid layer. Although this general arrangement is conserved, differences can be seen throughout the CA and spacer peptide regions. These differences can be related to sequence differences among the genera. We conclude that the arrangement of the structural domains of CA is well conserved across genera, whereas the relationship between CA, the spacer peptide region, and the nucleic acid is more specific to each genus.Retrovirus assembly is driven by the oligomerization of Gag, a multidomain protein, including an N-terminal membrane binding domain (MA), a two-domain structural component (CA), and an RNA binding domain (NC). The Gag proteins of all orthoretroviruses, including the alpha-, beta-, and lentiretroviruses discussed here, share this conserved modular architecture (Fig. ​(Fig.1).1). Despite very weak sequence conservation, the tertiary structures of MA, CA, and NC are conserved among retroviruses. Outside these conserved domains the Gag proteins of different retroviruses exhibit substantial variability. Other domains may be present or absent, and the length and sequence of linker peptides may also vary (12) (Fig. ​(Fig.11).Open in a separate windowFIG. 1.Modular architecture of the full-length Gag proteins of HIV, M-PMV, and RSV. White rectangles illustrate Gag polyprotein cleavage products. The extent of the constructs used in the electron microscopic analysis is specified under each protein as a black rectangle. Gray triangles specify cleavage sites. Residue numbers are counted from the beginning of Gag.Oligomerization of Gag in an infected cell leads to the formation of roughly spherical immature virus particles, where Gag is arranged in a radial fashion with the N-terminal MA domain associated with a surrounding lipid bilayer, and the more C-terminal NC pointing toward the center of the particle (15, 44, 46). Subsequent multiple cleavages of Gag by the viral protease lead to a rearrangement of the virus. NC and the RNA condense in the center of the particle, CA assembles into a capsid or shell around the nucleoprotein, and MA remains associated with the viral membrane. This proteolytic maturation is required to generate an infectious virion (2). In contrast to the mature CA lattice, which has been extensively studied (11, 16, 36), the Gag lattice in immature particles is incompletely understood.Gag itself contains all of the necessary determinants for particle assembly. For example, the expression of Gag alone in an insect cell expression system is sufficient to generate viruslike particles (3, 17, 22, 38). Retroviral Gag proteins also can be assembled in vitro in the presence of nucleic acids to form spherical particles (9, 19, 39, 43, 47). The arrangement of Gag within these in vitro-assembled Gag particles is indistinguishable from that found in immature virus particles (6), and the in vitro assembly systems have proved valuable for unraveling the principles of virus assembly (18, 28, 29, 39). Multiple layers of interaction promote the assembly of Gag in vivo, including MA-membrane-MA interactions, CA-CA interactions, and NC-RNA-NC interactions. An extensive body of literature has explored which regions of Gag are required for assembly and which can be replaced or deleted without compromising assembly. MA-membrane-MA interactions contribute but are not essential. NC-RNA-NC interactions appear to function to nonspecifically link Gag molecules together and can be replaced both in vivo and in vitro by other interaction domains such as leucine zippers (4, 13, 20, 32, 48). The C-terminal domain of CA (referred to here as C-CA) and the stretch of amino acids immediately following this domain (termed the spacer peptide [SP] region) are critical for assembly and sensitive to mutation (1, 22, 27, 30).We set out to understand how the substantial sequence variation among Gag proteins in different retroviruses is manifested in structural differences in the immature Gag lattice. To do this, we studied three retroviruses from different genera: the lentivirus human immunodeficiency virus type 1 (HIV-1), the betaretrovirus Mason-Pfizer monkey virus (M-PMV), and the alpharetrovirus Rous sarcoma virus (RSV). These retroviruses are those for which in vitro assembly was first established and has been most extensively studied (6, 19, 24, 28, 29, 35, 43, 47).The domain structures of the three retroviruses differ most substantially upstream of CA. Both M-PMV and RSV have domains located between MA and CA that are absent in HIV (Fig. ​(Fig.1).1). In M-PMV there are 198 residues forming the pp24 and p12 domains; in RSV there are 84 residues forming the p2a, p2b, and p10 domains. The three retroviruses have different requirements for regions upstream of CA during assembly. The C-terminal 25 residues of p10 are essential for proper immature RSV assembly, both in vitro and in vivo, and these residues are inferred to interact directly with N-CA to stabilize the hexamer by forming contacts between adjacent N-CA domains (35). An equivalent assembly domain has not been described for other retroviruses. Within M-PMV p12 is the so-called internal scaffolding domain that is not essential for assembly in vitro (43) but is required for particle assembly when the precursor is expressed under the control of the M-PMV promoter (41). It is a key domain for the membrane-independent assembly of immature capsids (40).In HIV, five residues upstream of CA must be present for assembly of immature virus-like spherical particles in vitro, although larger upstream extensions, including part of MA, are required for efficient assembly of regular particles, both for HIV and RSV. For HIV, if the entire MA domain is included, in vitro assembly requires the presence of inositol penta- or hexakis phosphate (8). If no sequences upstream of CA are present, the in vitro particles in both of these viruses adopt a mature-type tubular morphology (10, 18). It has been hypothesized that cleavage at the N terminus of N-CA during maturation leads to the N-terminal residues of CA folding back into the N-CA structure to form a β-hairpin. The β-hairpin is important for assembly of the mature CA lattice, whereas its absence is important for immature assembly (23, 42). These requirements explain why, in HIV and RSV, immature Gag lattice-like structures are formed only if regions upstream of CA are present (18). In M-PMV, an immature Gag lattice can be produced when the regions upstream of CA are deleted if this is combined with mutations (such as deleting the initial proline of CA), which prevent β-hairpin formation (43).During maturation, HIV and RSV Gag proteins are cleaved twice between CA and NC to release a small peptide called SP1 or SP. In RSV the most N-terminal of these two cleavages can occur at one of two possible positions such that the released peptide is either 9 or 12 amino acids long (33). In M-PMV only one cleavage occurs between CA and NC, and no short peptide is produced. The region between the final helix of CA and the Zn fingers has been proposed to adopt a helical bundle architecture in HIV and RSV based on bioinformatic prediction, on mutational analysis, and on structural studies (1, 22, 27, 45). In all three viruses, C-CA and the residues immediately downstream are critical for assembly and are sensitive to mutation. C-CA contains the major homology region, a group of residues that are highly conserved across the retroviruses.Cryo-electron tomography (cET) studies of immature virus particles (6, 45) have resolved the electron density of the HIV Gag lattice in three dimensions at low resolution. Using these methods, we have also described the three-dimensional architecture of in vitro-assembled HIV Gag particles (6). In immature viruses and in vitro-assembled particles, Gag is seen to adopt an 8 nm hexameric lattice, as was predicted from previous Fourier analysis of two-dimensional images (7, 46). The hexameric lattice is interrupted by irregularly shaped holes and cracks in the lattice (6, 45). A similar observation has been made using AFM of in vitro-assembled particles of M-PMV Gag (26). These holes and cracks allow an otherwise planar hexameric lattice to form the surface of an approximately spherical particle.The radial positions of the MA, CA, and NC domains had been assigned previously from cryo-electron micrographs (44, 46). Based on these assignments and the shape of the density, the position and relative orientations of CA domains can be modeled into the low-resolution structure of the HIV lattice (6, 45). Density ascribed to the N-terminal domain of CA (N-CA) forms rings around large holes at the 6-fold symmetry positions in the lattice. Below this layer, at the expected radius of the C-CA, are 2-fold densities, interpreted as corresponding to dimers of C-CA. These densities are linked by rodlike densities, which descend into the NC-nucleic acid layer.HIV is the only retrovirus for which the arrangement of Gag in the immature particle has been described in three dimensions. Prior to this work, important open questions were therefore: which features of the arrangement of Gag are conserved between genera and therefore reflect general principles of Gag-Gag interactions, and which features are specific to certain genera? We have applied subtomogram averaging of cryo-electron tomograms to generate reconstructions of in vitro-assembled Gag particles from HIV, M-PMV, and RSV. These allow identification of the general and variable features of the arrangement of Gag and the architecture of immature retroviruses.     

Divergent Bro1 Domains Share the Capacity To Bind Human Immunodeficiency Virus Type 1 Nucleocapsid and To Enhance Virus-Like Particle Production

To promote the release of infectious virions, human immunodeficiency virus type 1 (HIV-1) exploits the endosomal sorting complex required for transport (ESCRT) pathway by engaging Tsg101 and ALIX through late assembly (L) domains in p6 Gag. An LYPx_nL motif in p6 serves as docking site for the central V domain of ALIX and is required for its ability to stimulate HIV-1 budding. Additionally, the nucleocapsid (NC) domain of Gag binds to the N-terminal Bro1 domain of ALIX, which connects ALIX to the membrane-deforming ESCRT-III complex via its CHMP4 subunits. Since the isolated Bro1 domain of ALIX is sufficient to markedly stimulate virus-like particle (VLP) production in a minimal Gag rescue assay, we examined whether the Bro1 domains of other human proteins possess a similar activity. We now show that the Bro1 domain-only protein Brox and the isolated Bro1 domains of HD-PTP and rhophilin all bind to HIV-1 NC. Furthermore, all shared the capacity to stimulate VLP production by a minimal HIV-1 Gag molecule, and Brox in particular was as potent as the Bro1 domain of ALIX in this assay. Unexpectedly, Brox retained significant activity even if its CHMP4 binding site was disrupted. Thus, the ability to assist in VLP production may be an intrinsic property of the boomerang-shaped Bro1 domain.Retroviruses engage an endosomal budding machinery via so-called late assembly (L) domains in Gag to promote virus budding at the plasma membrane (4, 17, 33). In the case of human immunodeficiency virus type 1 (HIV-1), the C-terminal p6 domain of Gag harbors a conserved P(T/S)AP motif, which binds to the host protein Tsg101 and functions as the primary L domain (18, 29, 44). Additionally, HIV-1 p6 contains an auxiliary L domain of the LYPx_nL type, which serves as a docking site for ALIX (28, 41, 45). Tsg101 and ALIX are both components of a protein network that is required for the biogenesis of multivesicular bodies (MVB) (22, 38). These compartments are formed through the budding of vesicles from the limiting membrane of endosomes into their lumen, a process that is topologically equivalent to virus budding at the plasma membrane. Recently, it emerged that the protein network essential for MVB formation also functions in cytokinesis, which requires a membrane fission event of similar topology (7, 32).Most of the components of the protein network that mediates these events are subunits of heteromeric endosomal sorting complexes required for transport (ESCRT) (3, 22, 38). For instance, Tsg101 is a subunit of the heterotetrameric ESCRT-I complex (22, 38). ESCRT-I and the downstream ESCRT-II are stable complexes, whereas ESCRT-III assembles only upon membrane binding (38). ESCRT-III is formed by the structurally related human CHMP proteins, which exist in an autoinhibited monomeric conformation in the cytosol (40, 46). A conformational change from a closed to an open conformation is thus likely required for the activation of CHMP proteins and the assembly of ESCRT-III. Interestingly, the uncontrolled activation of CHMP proteins through the removal of autoinhibitory C-terminal sequences results in the potent inhibition of HIV-1 budding, indicating a central role for ESCRT-III in retroviral release (46).ALIX consists of a boomerang-shaped N-terminal Bro1 domain, a central ligand binding domain that is shaped like a V, and a C-terminal proline-rich region (16). While ALIX is essential for equine anemia virus budding, its role in HIV-1 budding is less critical than that of Tsg101 (8, 16, 28, 41). However, ALIX can clearly support efficient HIV-1 budding, because its overexpression potently rescues the release defect of Tsg101 binding site mutants (16, 43). This effect of ALIX depends on the interaction between its central V domain and the LYPx_nL motif in HIV-1 p6 (16, 43), confirming that this motif constitutes a functional L domain.The Bro1 domain of ALIX interacts tightly with ESCRT-III subunit CHMP4B and less avidly with CHMP4A and CHMP4C (25, 28, 41, 45). The ability of ALIX to rescue HIV-1 L domain mutants depends on the interaction between its Bro1 domain and CHMP4, indicating that CHMP4 is of particular importance in viral budding (16, 43). Interestingly, human CHMP4A assembles into membrane-attached filaments if overexpressed in mammalian cells, and these filaments can be induced to form circular arrays that drive the formation of buds and tubules with the same topology as that of a retroviral bud (21). Also, the single yeast ortholog of the mammalian CHMP4 proteins forms homo-oligomeric filaments on endosomes that appear to drive MVB sorting and biogenesis (42).By binding to membranes with its convex surface, the Bro1 domain of ALIX could also contribute directly to the generation of negative curvature required for budding away from the cytosol. In support of this notion, we recently observed that the isolated Bro1 domain of ALIX can potently enhance the formation of virus-like particles (VLP) by a minimal HIV-1 Gag construct that retains the primary L domain but lacks certain assembly domains and thus is presumably defective in its ability to deform membranes (37). We also observed that the Bro1 domain of ALIX physically interacts with the nucleocapsid (NC) region of HIV-1 Gag and that mutations in NC that interfere with the interaction induce a phenotype that resembles that of L domain mutants (37).Despite limited sequence homology between human ALIX and a yeast counterpart, the structures of their Bro1 domains are largely superimposable (16, 26), suggesting that all Bro1 domains have a shape that would be compatible with a membrane-deforming function. We therefore asked whether the ability to stimulate VLP production is unique to the Bro1 domain of ALIX or a property of Bro1 domains in general. We now show that widely divergent Bro1 domains share the ability to associate with HIV-1 Gag in an NC-dependent manner and to enhance VLP production by a minimal Gag molecule. In particular, a human Bro1 domain-only protein termed Brox (23) was as potent as the ALIX Bro1 domain in stimulating VLP production, and even forms of Brox that did not bind to CHMP4 retained significant activity. We thus propose that Bro1 domains are inherently capable of promoting budding events away from the cytosol.     

Genetic Evidence for a Connection between Rous Sarcoma Virus Gag Nuclear Trafficking and Genomic RNA Packaging

The packaging of retroviral genomic RNA (gRNA) requires cis-acting elements within the RNA and trans-acting elements within the Gag polyprotein. The packaging signal ψ, at the 5′ end of the viral gRNA, binds to Gag through interactions with basic residues and Cys-His box RNA-binding motifs in the nucleocapsid. Although specific interactions between Gag and gRNA have been demonstrated previously, where and when they occur is not well understood. We discovered that the Rous sarcoma virus (RSV) Gag protein transiently localizes to the nucleus, although the roles of Gag nuclear trafficking in virus replication have not been fully elucidated. A mutant of RSV (Myr1E) with enhanced plasma membrane targeting of Gag fails to undergo nuclear trafficking and also incorporates reduced levels of gRNA into virus particles compared to those in wild-type particles. Based on these results, we hypothesized that Gag nuclear entry might facilitate gRNA packaging. To test this idea by using a gain-of-function genetic approach, a bipartite nuclear localization signal (NLS) derived from the nucleoplasmin protein was inserted into the Myr1E Gag sequence (generating mutant Myr1E.NLS) in an attempt to restore nuclear trafficking. Here, we report that the inserted NLS enhanced the nuclear localization of Myr1E.NLS Gag compared to that of Myr1E Gag. Also, the NLS sequence restored gRNA packaging to nearly wild-type levels in viruses containing Myr1E.NLS Gag, providing genetic evidence linking nuclear trafficking of the retroviral Gag protein with gRNA incorporation.The encapsidation of the RNA genome is essential for retrovirus replication. Because the viral genomic RNA (gRNA) constitutes only a small fraction of the total cellular mRNA, a specific Gag-RNA interaction is thought to be required for viral genome packaging (2). The determinants of virus-specific gRNA incorporation include the cis-acting element at the 5′end of the viral gRNA, known as the packaging signal (ψ), and the nucleocapsid (NC) domain of the Gag polyprotein (3, 14, 62). In Rous sarcoma virus (RSV), the NC domain contains basic residues that are required for the recognition of and binding to ψ, as well as two Cys-His motifs that maintain the overall conformation of NC and are essential for RNA packaging (30, 31).Packaging of gRNA into progeny virions requires that the unspliced viral mRNA be exported from the nucleus. However, cellular proofreading mechanisms ensure that unspliced or intron-containing mRNAs are retained in the nucleus until splicing occurs. Complex retroviruses like human immunodeficiency virus type 1 (HIV-1) overcome this export block of unspliced genomes by encoding the Rev protein, which interacts with a cis-acting sequence in the viral RNA (the Rev-responsive element [RRE]) to facilitate cytoplasmic accumulation of intron-containing viral mRNA (16, 35). The export of the Rev-viral RNA complex is mediated through the interaction of a leucine-rich nuclear export signal (NES) in Rev with the CRM1 nuclear export factor (17, 18, 37, 41). Simple retroviruses do not encode Rev-like regulatory proteins, so other strategies for the export of unspliced viral RNAs are needed. For Mason-Pfizer monkey virus, a cis-acting constitutive transport element induces nuclear export of the unspliced viral RNA in a process mediated by the cellular mRNA nuclear export factor TAP (5, 25, 46, 63). In RSV, an RNA element composed of either of the two direct repeats flanking the src gene mediates the cytoplasmic accumulation of unspliced viral RNA by using host export proteins TAP and Dpb5 (29, 42, 44).The findings of recent studies suggest that specific RNA export pathways direct viral gRNA to sites of virion assembly (56); for example, HIV-1 gRNA export out of the nucleus by the Rev-RRE-CRM1 complex is required for the proper subcellular localization of Gag and efficient virus particle production (26, 57). In the case of RSV, little is known about the trafficking of the viral RNA destined for virion encapsidation or the effects of the gRNA nuclear export pathway on Gag trafficking and virus particle production. However, we do know that RSV Gag enters the nucleus during infection, owing to nuclear localization signals (NLSs) in the matrix (MA) and NC domains. The nuclear localization of Gag is transient, and export is mediated by a CRM1-dependent NES in the p10 region (6, 52, 53). Thus, it is feasible that Gag may facilitate the nuclear export of the gRNA, either directly or indirectly, to promote particle assembly (53).In support of this idea, Gag mutants engineered to be more efficiently directed to the plasma membrane than wild-type Gag by the addition of the Src membrane-binding domain (in Myr1E virus) or by the insertion of extra basic residues (in SuperM virus) are not concentrated in nuclei when cells are treated with the CRM1 inhibitor leptomycin B (LMB) (8, 20, 53). Moreover, Myr1E and SuperM virus particles incorporate reduced levels of viral gRNA compared to the levels incorporated by wild-type particles. Thus, there is a correlation between the nuclear transit of Gag and gRNA packaging, although the Myr1E and SuperM viruses may be deficient in gRNA encapsidation because they are transported to the plasma membrane too rapidly (8). To test the hypothesis that the loss of Gag nuclear trafficking is responsible for the gRNA packaging defect, we used a gain-of-function genetic approach whereby a heterologous NLS was inserted into Myr1E Gag, yielding mutant virus Myr1E.NLS. Our results revealed that restoring the nuclear trafficking of Myr1E Gag also restored the incorporation of gRNA into mutant virus particles.