A critical proteolytic cleavage site near the C terminus of the yeast retrotransposon Ty1 Gag protein.

Cleavage of the Gag and Gag-Pol polyprotein precursors is a critical step in proliferation of retroviruses and retroelements. The Ty1 retroelement of Saccharomyces cerevisiae forms virus-like particles (VLPs) made of the Gag protein. Ty1 Gag is not obviously homologous to the Gag proteins of retroviruses. The apparent molecular mass of Gag is reduced from 58 to 54 kDa during particle maturation. Antibodies raised against the C-terminal peptide of Gag react with the 58-kDa polypeptide but not with the 54-kDa one, indicating that Gag is proteolytically processed at the C terminus. A protease cleavage site between positions 401 and 402 of the Gag precursor was defined by carboxy-terminal sequencing of the processed form of Gag. Certain deletion and substitution mutations in the C terminus of the Gag precursor result in particles that are two-thirds the diameter of the wild-type VLPs. While the Ty1 protease is active in these mutants, their transposition rates are decreased 20-fold compared with that of wild-type Ty1. Thus, the Gag C-terminal portion, released in the course of particle maturation, probably plays a significant role in VLP morphogenesis and Ty1 transposition.     

Mass Determination of Rous Sarcoma Virus Virions by Scanning Transmission Electron Microscopy

The internal structural protein of retroviruses, Gag, comprises most of the mass of the virion, and Gag itself can give rise to virus-like particles when expressed in appropriate cells. Previously the stoichiometry of Gag in virions was inferred from indirect measurements carried out 2 decades ago. We now have directly determined the masses of individual particles of the prototypic avian retrovirus, Rous sarcoma virus (RSV), by using scanning transmission electron microscopy. In this technique, the number of scattered electrons in the dark-field image integrated over an individual freeze-dried virus particle on a grid is directly proportional to its mass. The RSV virions had a mean mass of 2.5 x 10(8) Da, corresponding to about 1,500 Gag molecules per virion. The population of virions was not homogeneous, with about one-third to two-thirds of the virions deviating from the mean by more than 10% of the mass in two respective preparations. The mean masses for virions carrying genomes of 7.4 or 9.3 kb were indistinguishable, suggesting that mass variability is not due to differences in RNA incorporation.     

Functional replacement of a retroviral late domain by ubiquitin fusion

Retroviral Gag polyprotein precursors are both necessary and sufficient for the assembly and release of virus-like particles (VLPs) from infected cells. It is well established that small Gag-encoded motifs, known as late domains, promote particle release by interacting with components of the cellular endosomal sorting and ubiquitination machinery. The Gag proteins of a number of different retroviruses are ubiquitinated; however, the role of Gag ubiquitination in particle egress remains undefined. In this study, we investigated this question by using a panel of equine infectious anemia virus (EIAV) Gag derivatives bearing the wild-type EIAV late domain, heterologous retroviral late domains or no late domain. Ubiquitin was fused in cis to the C-termini of these Gag polyproteins, and the effects on VLP budding were measured. Remarkably, fusion of ubiquitin to EIAV Gag lacking a late domain (EIAV/DeltaYPDL-Ub) largely rescued VLP release. We also determined the effects of ubiquitin fusion on the sensitivity of particle release to budding inhibitors and to depletion of key endosomal sorting factors. Ubiquitin fusion rendered EIAV/DeltaYPDL-Ub sensitive to depletion of cellular endosomal sorting factors Tsg101 and Alix and to overexpression of dominant-negative fragments of Tsg101 and Alix. These findings demonstrate that ubiquitin can functionally compensate for the absence of a retroviral late domain and provide insights into the host-cell machinery engaged by ubiquitin during particle egress.     

Dominant negative inhibition of human immunodeficiency virus particle production by the nonmyristoylated form of gag

Myristoylation of human immunodeficiency virus (HIV) Gag protein is essential for membrane targeting of Gag and production of viral particles. We show here that coexpression of wild-type and nonmyristoylated forms of HIV Gag resulted in severe inhibition of viral particle production, indicating that the nonmyristoylated counterpart had a dominant negative effect on particle release. When coexpressed, the nonmyristoylated Gag partially incorporated into membrane and lipid raft fractions, likely through coassembly with the wild-type Gag. The membrane and raft associations of the wild-type Gag appeared unaffected, and yet particle production was severely impaired. When viral particles produced from the coexpressing cells were analyzed, the wild-type Gag was more abundant than the nonmyristoylated Gag. Confocal microscopy showed that both forms of Gag were diffusely distributed in the cytoplasm of coexpressing cells but that a portion of the wild-type Gag population was accumulated in EEA1- and CD63-positive endosomes. The intracellular accumulation of Gag was more frequently observed at late time points. The Gag accumulation was also observed on the cell surface protrusion. Electron microscopy of the coexpressing cells revealed budding arrest phenotypes, including the occurrence of interconnected virions on the plasma membrane, and intracellular budding. We also show that the inhibition of particle production and the Gag accumulation to endosomes were suppressed when the nucleocapsid (NC) domain was deleted from the nonmyristoylated Gag, although the NC-deleted Gag was still capable of coassembly. Overall, our data indicate that coassembly with the nonmyristoylated Gag impairs HIV particle release, a phenomenon that may involve NC-mediated Gag-Gag interaction.     

Interactions of HIV-1 Gag with assembly cofactors

HIV-1 Gag is the only protein required for retroviral particle assembly. There is evidence suggesting that phosphatidylinositol phosphate and nucleic acid are essential for viruslike particle assembly. To elucidate structural foundations of interactions of HIV-1 Gag with the assembly cofactors PI(4,5)P2 and RNA, we employed mass spectrometric protein footprinting. In particular, the NHS-biotin modification approach was used to identify the lysine residues that are exposed to the solvent in free Gag and are protected from biotinylation by direct protein-ligand or protein-protein contacts in Gag complexes with PI(4,5)P2 and/or RNA. Of 21 surface lysines readily modified in free Gag, only K30 and K32, located in the matrix domain, were strongly protected in the Gag-PI(4,5)P2 complex. Nucleic acid also protected these lysines, but only at significantly higher concentrations. In contrast, nucleic acids and not PI(4,5)P2 exhibited strong protection of two nucleocapsid domain residues: K391 and K424. In addition, K314, located in the capsid domain, was specifically protected only in the presence of both PI(4,5)P2 and nucleic acid. We suggest that concerted binding of PI(4,5)P2 and nucleic acid to the matrix and nucleocapsid domains, respectively, promotes protein-protein interactions involving capsid domains. These protein-protein interactions must be involved in virus particle assembly.     

Human Immunodeficiency Virus Type 2 Capsid Protein Mutagenesis Reveals Amino Acid Residues Important for Virus Particle Assembly

Human immunodeficiency virus (HIV) Gag drives virus particle assembly. The capsid (CA) domain is critical for Gag multimerization mediated by protein–protein interactions. The Gag protein interaction network defines critical aspects of the retroviral lifecycle at steps such as particle assembly and maturation. Previous studies have demonstrated that the immature particle morphology of HIV-2 is intriguingly distinct relative to that of HIV-1. Based upon this observation, we sought to determine the amino acid residues important for virus assembly that might help explain the differences between HIV-1 and HIV-2. To do this, we conducted site-directed mutagenesis of targeted locations in the HIV-2 CA domain of Gag and analyzed various aspects of virus particle assembly. A panel of 31 site-directed mutants of residues that reside at the HIV-2 CA inter-hexamer interface, intra-hexamer interface and CA inter-domain linker were created and analyzed for their effects on the efficiency of particle production, particle morphology, particle infectivity, Gag subcellular distribution and in vitro protein assembly. Seven conserved residues between HIV-1 and HIV-2 (L19, A41, I152, K153, K157, N194, D196) and two non-conserved residues (G38, N127) were found to significantly impact Gag multimerization and particle assembly. Taken together, these observations complement structural analyses of immature HIV-2 particle morphology and Gag lattice organization as well as provide important comparative insights into the key amino acid residues that can help explain the observed differences between HIV immature particle morphology and its association with virus replication and particle infectivity.     

AP-3 directs the intracellular trafficking of HIV-1 Gag and plays a key role in particle assembly

Gag proteins direct the process of retroviral particle assembly and form the major protein constituents of the viral core. The matrix region of the HIV-1 Gag polyprotein plays a critical role in the transport of Gag to the plasma membrane assembly site. Recent evidence indicates that Gag trafficking to late endosomal compartments, including multivesicular bodies, occurs prior to viral particle budding from the plasma membrane. Here we demonstrate that the matrix region of HIV-1 Gag interacts directly with the delta subunit of the AP-3 complex, and that this interaction plays an important functional role in particle assembly. Disruption of this interaction eliminated Gag trafficking to multivesicular bodies and diminished HIV particle formation. These studies illuminate an early step in retroviral particle assembly and provide evidence that the trafficking of Gag to late endosomes is part of a productive particle assembly pathway.     

Role of the human T-cell leukemia virus type 1 PTAP motif in Gag targeting and particle release

Human T-cell leukemia virus type 1 (HTLV-1) Gag is targeted to the plasma membrane for particle assembly and release. How HTLV-1 Gag targeting occurs is not well understood. The PPPY and PTAP motifs were previously shown to be involved in HTLV-1 particle release with PTAP playing a more subtle role in virus budding. These L domains function through the interaction with host cellular proteins normally involved in multivesicular body (MVB) morphogenesis. The plasma membrane pathway rather than the MVB pathway was found to be the primary pathway for HTLV-1 particle release in HeLa cells. Intriguingly, disruption of the PTAP motif led to a defect in the targeting of Gag from the plasma membrane to CD63-positive MVBs. Particles or particle buds were observed to be associated with MVBs by electron microscopy, implying that Gag targeting to the MVB resulted in particle budding. Blocking clathrin-dependent endocytosis was found not to influence localization of the HTLV-1 Gag PTAP mutant, indicating that Gag did not reach the MVBs through clathrin-dependent endocytosis. Our observations imply that the interaction between Gag and TSG101 is not required for Gag targeting to the MVB. Overexpression of dynamitin p50 increased particle release, suggesting that there was an increase in the intracellular transport of MVBs to the cell periphery by the utilization of the dynein-dynactin motor complex. Intriguingly, virus particle release with this mutant was reduced by 20-fold compared to that of wild type in HeLa cells, which is in marked contrast to the less-than-twofold defect observed for particle production of the HTLV-1 Gag PTAP mutant from 293T cells. These results indicate that the role of the PTAP motif in L domain function is cell type dependent.     

Loss of Viral Fitness Associated with Multiple Gag and Gag-Pol Processing Defects in Human Immunodeficiency Virus Type 1 Variants Selected for Resistance to Protease Inhibitors In Vivo

We examined the viral replicative capacity and protease-mediated processing of Gag and Gag-Pol precursors of human immunodeficiency virus (HIV) variants selected for resistance to protease inhibitors. We compared recombinant viruses carrying plasma HIV RNA protease sequences obtained from five patients before protease inhibitor therapy and after virus escape from the treatment. Paired pretherapy-postresistance reconstructed viruses were evaluated for HIV infectivity in a quantitative single-cycle titration assay and in a lymphoid cell propagation assay. We found that all reconstructed resistant viruses had a reproducible decrease in their replicative capacity relative to their parental pretherapy counterparts. The extent of this loss of infectivity was pronounced for some viruses and more limited for others, irrespective of the inhibitor used and of the level of resistance. In resistant viruses, the efficiency of Gag and Gag-Pol precursor cleavage by the protease was impaired to different extents, as shown by the accumulation of several cleavage intermediates in purified particle preparations. We conclude that protease inhibitor-resistant HIV variants selected during therapy have an impaired replicative capacity related to multiple defects in the processing of Gag and Gag-Pol polyprotein precursors by the protease.     

Kinesin KIF4 regulates intracellular trafficking and stability of the human immunodeficiency virus type 1 Gag polyprotein

Retroviral Gag proteins are synthesized as soluble, myristoylated precursors that traffic to the plasma membrane and promote viral particle production. The intracellular transport of human immunodeficiency virus type 1 (HIV-1) Gag to the plasma membrane remains poorly understood, and cellular motor proteins responsible for Gag movement are not known. Here we show that disrupting the function of KIF4, a kinesin family member, slowed temporal progression of Gag through its trafficking intermediates and inhibited virus-like particle production. Knockdown of KIF4 also led to increased Gag degradation, resulting in reduced intracellular Gag protein levels; this phenotype was rescued by reintroduction of KIF4. When KIF4 function was blocked, Gag transiently accumulated in discrete, perinuclear, nonendocytic clusters that colocalized with endogenous KIF4, with Ubc9, an E2 SUMO-1 conjugating enzyme, and with SUMO. These studies identify a novel transit station through which Gag traffics en route to particle assembly and highlight the importance of KIF4 in regulating HIV-1 Gag trafficking and stability.     

Particle Size Determinants in the Human Immunodeficiency Virus Type 1 Gag Protein

The retroviral Gag protein plays the central role in the assembly process and can form membrane-enclosed, virus-like particles in the absence of any other viral products. These particles are similar to authentic virions in density and size. Three small domains of the human immunodeficiency virus type 1 (HIV-1) Gag protein have been previously identified as being important for budding. Regions that lie outside these domains can be deleted without any effect on particle release or density. However, the regions of Gag that control the size of HIV-1 particles are less well understood. In the case of Rous sarcoma virus (RSV), the size determinant maps to the CA (capsid) and adjacent spacer sequences within Gag, but systematic mapping of the HIV Gag protein has not been reported. To locate the size determinants of HIV-1, we analyzed a large collection of Gag mutants. To our surprise, all mutants with defects in the MA (matrix), CA, and the N-terminal part of NC (nucleocapsid) sequences produced dense particles of normal size, suggesting that oncoviruses (RSV) and lentiviruses (HIV-1) have different size-controlling elements. The most important region found to be critical for determining HIV-1 particle size is the p6 sequence. Particles lacking all or small parts of p6 were uniform in size distribution but very large as measured by rate zonal gradients. Further evidence for this novel function of p6 was obtained by placing this sequence at the C terminus of RSV CA mutants that produce heterogeneously sized particles. We found that the RSV-p6 chimeras produced normally sized particles. Thus, we present evidence that the entire p6 sequence plays a role in determining the size of a retroviral particle.     

Identification of an intracellular trafficking and assembly pathway for HIV-1 gag

Retroviral Gag proteins are membrane-bound polyproteins that are necessary and sufficient for virus-like particle (VLP) formation. It is not known how Gag traffics through the cell or how the site of particle production is determined. Here we use two techniques, biarsenical/tetracysteine (TC) labeling and release from a cycloheximide block, to follow the trafficking of newly synthesized HIV-1 Gag. Gag first appears diffusely distributed in the cytosol, accumulates in perinuclear clusters, passes transiently through a multivesicular body (MVB)-like compartment, and then travels to the plasma membrane (PM). Sequential passage of Gag through these temporal intermediates was confirmed by live cell imaging. Induction of a transient rise in cytoplasmic calcium increased the amounts of Gag, Gag assembly intermediates and VLPs in MVBs, and resulted in a dramatic increase in VLP release. These results define an intracellular trafficking pathway for HIV-1 Gag that uses perinuclear compartments and the MVB as trafficking intermediates. We propose that the regulation of Gag association with MVB-like compartments regulates the site of HIV-1 budding and particle formation.     

Human immunodeficiency virus type 1 MA deletion mutants expressed in baculovirus-infected cells: cis and trans effects on the Gag precursor assembly pathway.

The role of the matrix protein (MA) of human immunodeficiency virus type 1 in intracellular transport, assembly, and extracellular release of Gag polyprotein precursor (Pr55gag) was investigated by deletion mutagenesis of the MA domain of recombinant Gag precursor expressed in baculovirus-infected cells. In addition, three carboxy-terminally truncated forms of the Gag precursor, representing mainly the MA, were constructed. One corresponded to an MA with a deletion of its last 12 residues (amb120), while the others corresponded to the entire MA with an additional sequence from the N-terminal portion of the CA (amb143 and och180). Deletions within the MA central region (residues 41 to 78) appeared to be detrimental to Gag particle assembly and budding from the plasma membrane. A slightly narrower domain, between amino acids 41 and 68, was found to be critical for soluble Gag secretion. Mutations which totally or partially deleted one or the other of the two polybasic signals altered the transport of N-myristylated Gag precursor to the plasma membrane. In coexpression with wild-type Gag precursor, a discrete trans-dominant negative effect on wild-type Gag particle assembly and release was observed with deletion mutants located in the central MA region (residues 41 to 78). A more significant negative effect was obtained with the two recombinant proteins of amb120 and och180, which redirected the Gag particle assembly pathway from the plasma membrane compartment to intracellular vesicles (amb120) and to the nuclear compartment (och180).     

Phenotypic characterization of insertion mutants of the human immunodeficiency virus type 1 Gag precursor expressed in recombinant baculovirus-infected cells.

A panel of 28 insertion mutants of the human immunodeficiency virus type 1 (HIV-1) Gag precursor (Pr55Gag) was constructed by linker-insertion mutagenesis and expressed in recombinant baculovirus-infected insect cells. One set of 14 mutants carried the normal N-myristylation signal; the other set constituted their non-N-myristylated counterparts. The mutants were characterized with respect to (i) assembly and extracellular release of membrane-enveloped budding Gag particles, (ii) intracellular assembly and nuclear transport of Gag cores, (iii) specific processing of Pr55Gag by HIV-1 protease in vivo, and (iv) binding of Pr55Gag to an HIV-1 genomic RNA probe in Northwestern blotting. Insertions within the region between amino acid residues 209 and 334 in the CA domain appeared to be the most detrimental to Gag particle assembly and release of Gag into the external medium, whereas a narrower window, between residues 209 and 241, was found to be critical for secretion of soluble Pr55Gag. Differences in Pr55Gag processing in vivo and RNA binding in vitro between N-myristylated and non-N-myristylated Gag mutants suggested a major conformational role for the myristylated N terminus of Gag precursor. In coinfection experiments using wild-type Gag- and mutant Gag-expressing recombinants, a transdominant negative effect on Gag particle assembly and release was observed for insertions located in two separate domains, the matrix and nucleocapsid.     

Association of human immunodeficiency virus type 1 gag with membrane does not require highly basic sequences in the nucleocapsid: use of a novel Gag multimerization assay

Human immunodeficiency virus type 1 (HIV-1) particle production, a process driven by the Gag polyprotein precursor, occurs on the plasma membrane in most cell types. The plasma membrane contains cholesterol-enriched microdomains termed lipid rafts, which can be isolated as detergent-resistant membrane (DRM). Previously, we and others demonstrated that HIV-1 Gag is associated with DRM and that disruption of Gag-raft interactions impairs HIV-1 particle production. However, the determinants of Gag-raft association remain undefined. In this study, we developed a novel epitope-based Gag multimerization assay to examine whether Gag assembly is essential for its association with lipid rafts. We observed that membrane-associated, full-length Gag is poorly detected by immunoprecipitation relative to non-membrane-bound Gag. This poor detection is due to assembly-driven masking of Gag epitopes, as denaturation greatly improves immunoprecipitation. Gag mutants lacking the Gag-Gag interaction domain located in the N terminus of the nucleocapsid (NC) were efficiently immunoprecipitated without denaturation, indicating that the epitope masking is caused by higher-order Gag multimerization. We used this assay to examine the relationship between Gag assembly and Gag binding to total cellular membrane and DRM. Importantly, a multimerization-defective NC mutant displayed wild-type levels of membrane binding and DRM association, indicating that NC-mediated Gag multimerization is dispensable for association of Gag with membrane or DRM. We also demonstrate that different properties of sucrose and iodixanol membrane flotation gradients may explain some discrepancies regarding Gag-raft interactions. This report offers new insights into the association of HIV-1 Gag with membrane and with lipid rafts.     

Repositioning basic residues in the M domain of the Rous sarcoma virus gag protein

The first 86 residues of the Rous sarcoma virus (RSV) Gag protein form a membrane-binding (M) domain that directs Gag to the plasma membrane during budding. Unlike other retroviral Gag proteins, RSV Gag is not myristylated; however, the RSV M domain does contain 11 basic residues that could potentially interact with acidic phospholipids in the plasma membrane. To investigate this possibility, we analyzed mutants in which basic residues in the M domain were replaced with asparagines or glutamines. The data show that neutralizing as few as two basic residues in the M domain blocked particle release and prevented Gag from localizing to the plasma membrane. Though not as severe, single neutralizations also diminished budding and, when expressed in the context of proviral clones, reduced the ability of RSV to spread in cell cultures. To further explore the role of basic residues in particle production, we added lysines to new positions in the M domain. Using this approach, we found that the budding efficiency of RSV Gag can be improved by adding pairs of lysines and that the basic residues in the M domain can be repositioned without affecting particle release. These data provide the first gain-of-function evidence for the importance of basic residues in a retroviral M domain and support a model in which RSV Gag binds to the plasma membrane via electrostatic interactions.     

Intracellular localization of human immunodeficiency virus type 1 Gag and GagPol products and virus particle release: relationship with the Gag-to-GagPol ratio

Human immunodeficiency virus (HIV) Gag precursor protein is cleaved by viral protease (PR) within GagPol precursor protein to produce the mature matrix (MA), capsid, nucleocapsid, and p6 domains. This processing is termed maturation and required for HIV infectivity. In order to understand the intracellular sites and mechanisms of HIV maturation, HIV molecular clones in which Gag and GagPol were tagged with FLAG and hemagglutinin epitope sequences at the C-termini, respectively were made. When coexpressed, both Gag and GagPol were incorporated into virus particles. Temporal analysis by confocal microscopy showed that Gag and GagPol were relocated from the cytoplasm to the plasma membrane. Mature cleaved MA was observed only at sites on the plasma membrane where both Gag and GagPol had accumulated, indicating that Gag processing occurs during Gag/GagPol assembly at the plasma membrane, but not during membrane trafficking. Fluorescence resonance energy transfer imaging suggested that these were the primary sites of GagPol dimerization. In contrast, with overexpression of GagPol alone an absence of particle release was observed, and this was associated with diffuse distribution of mature cleaved MA throughout the cytoplasm. Alteration of the Gag-to-GagPol ratio similarly impaired virus particle release with aberrant distributions of mature MA in the cytoplasm. However, when PR was inactive, it seemed that the Gag-to-GagPol ratio was not critical for virus particle release but virus particles encasing unusually large numbers of GagPol molecules were produced, these particles displaying aberrant virion morphology. Taken together, it was concluded that the Gag-to-GagPol ratio has significant impacts on either intracellular distributions of mature cleaved MA or the morphology of virus particles produced.     

Characterization of a small (25-kilodalton) derivative of the Rous sarcoma virus Gag protein competent for particle release.

Retroviral Gag proteins have the ability to induce budding and particle release from the plasma membrane when expressed in the absence of all of the other virus-encoded components; however, the locations of the functional domains within the Gag protein that are important for this process are poorly understood. It was shown previously that the protease sequence of the Rous sarcoma virus (RSV) Gag protein can be replaced with a foreign polypeptide, iso-1-cytochrome c from a yeast, without disrupting particle assembly (R. A. Weldon, Jr., C. R. Erdie, M. G. Oliver, and J. W. Wills, J. Virol. 64:4169-4179, 1990). An unexpected product of the chimeric gag gene is a small, Gag-related protein named p25C. This product was of interest because of its high efficiency of packaging into particles. The goal of the experiments described here was to determine the mechanism by which p25C is synthesized and packaged into particles. The results demonstrate that it is not the product of proteolytic processing of the Gag-cytochrome precursor but is derived from an unusual spliced mRNA. cDNA clones of the spliced mRNA were obtained, and each expressed a product of approximately 25 kDa, designated p25M1, which was released into the growth medium in membrane-enclosed particles that were much lighter than authentic retrovirions as measured in sucrose density gradients. DNA sequencing revealed that the clones encode the first 180 of the 701 amino acids of the RSV Gag protein and no residues from iso-1-cytochrome c. This suggested that a domain in the carboxy-terminal half of Gag is important for the packaging of Gag proteins into dense arrays within the particles. In support of this hypothesis, particles of the correct density were obtained when a small segment from the carboxy terminus of the RSV Gag protein (residues 417 to 584) was included on the end of p25.     

Mutations in the α-helix Directly C-terminal to the Major Homology Region of Human Immunodeficiency Virus Type 1 Capsid Protein Disrupt Gag Multimerization and Markedly Impair Virus Particle Production

The X-ray crystallographic structure of HIV-1 capsid protein suggests that the dimer interface of the dimerization domain is mainly formed from a putative α-helix structure of 14 amino acids (Gag residues 311–324) and lies directly C-terminal to the capsid major homology region. We found that a deletion mutation in the α-helix drastically reduces virus particle production. Alanine-scanning mutagenetic analysis indicated that substitution mutations at residues Q311, V313, K314, W316, and M317 all impair virus particle production markedly. Membrane flotation assays suggested that some mutations in the dimer interface have slight effects on the efficient binding of Gag to membranes. Indirect immunofluorescence studies revealed that mutants defective in virus production exhibit a subcellular distribution pattern similar to that of wild-type. However, velocity sedimentation analysis showed that mutations significantly impairing virus particle production were also detrimental to Gag multimerization, suggesting that the impaired virus production may be due to a defect in Gag multimerization. These results support the proposal that residues in the capsid dimer interface play a crucial role in promoting Gag multimerization, possibly by facilitating stable Gag–Gag interactions.     

Analysis of the initiating events in HIV-1 particle assembly and genome packaging

HIV-1 Gag drives a number of events during the genesis of virions and is the only viral protein required for the assembly of virus-like particles in vitro and in cells. Although a reasonable understanding of the processes that accompany the later stages of HIV-1 assembly has accrued, events that occur at the initiation of assembly are less well defined. In this regard, important uncertainties include where in the cell Gag first multimerizes and interacts with the viral RNA, and whether Gag-RNA interaction requires or induces Gag multimerization in a living cell. To address these questions, we developed assays in which protein crosslinking and RNA/protein co-immunoprecipitation were coupled with membrane flotation analyses in transfected or infected cells. We found that interaction between Gag and viral RNA occurred in the cytoplasm and was independent of the ability of Gag to localize to the plasma membrane. However, Gag:RNA binding was stabilized by the C-terminal domain (CTD) of capsid (CA), which participates in Gag-Gag interactions. We also found that Gag was present as monomers and low-order multimers (e.g. dimers) but did not form higher-order multimers in the cytoplasm. Rather, high-order multimers formed only at the plasma membrane and required the presence of a membrane-binding signal, but not a Gag domain (the CA-CTD) that is essential for complete particle assembly. Finally, sequential RNA-immunoprecipitation assays indicated that at least a fraction of Gag molecules can form multimers on viral genomes in the cytoplasm. Taken together, our results suggest that HIV-1 particle assembly is initiated by the interaction between Gag and viral RNA in the cytoplasm and that this initial Gag-RNA encounter involves Gag monomers or low order multimers. These interactions per se do not induce or require high-order Gag multimerization in the cytoplasm. Instead, membrane interactions are necessary for higher order Gag multimerization and subsequent particle assembly in cells.