Coding sequences upstream of the human immunodeficiency virus type 1 reverse transcriptase domain in Gag-Pol are not essential for incorporation of the Pr160(gag-pol) into virus particles

Effects of reduced gag cleavage efficiency on HIV-1 Gag-Pol package

BACKGROUND

HIV-1 pol, which encodes enzymes required for virus replication, is initially translated as a Gag-Pol fusion protein. Gag-Pol is incorporated into virions via interactions with Gag precursor Pr55^gag. Protease (PR) embedded in Gag-Pol mediates the proteolytic processing of both Pr55gag and Gag-Pol during or soon after virus particle release from cells. Since efficient Gag-Pol viral incorporation depends on interaction with Pr55^gag via its N-terminal Gag domain, the prevention of premature Gag cleavage may alleviate Gag-Pol packaging deficiencies associated with cleavage enhancement from PR.

RESULTS

We engineered PR cleavage-blocking Gag mutations with the potential to significantly reduce Gag processing efficiency. Such mutations may mitigate the negative effects of enhanced PR activation on virus assembly and Gag-Pol packaging due to an RT dimerization enhancer or leucine zipper dimerization motif. When co-expressed with Pr55^gag, we noted that enhanced PR activation resulted in reduced Gag-Pol cis or trans incorporation into Pr55^gag particles, regardless of whether or not Gag cleavage sites within Gag-Pol were blocked.

CONCLUSIONS

Our data suggest that the amount of HIV-1 Gag-Pol or Pol viral incorporation is largely dependent on virus particle production, and that cleavage blocking in the Gag-Pol N-terminal Gag domain does not exert significant impacts on Pol packaging.

HIV-1 Mutant Assembly, Processing and Infectivity Expresses Pol Independent of Gag

The pol retrovirus gene encodes required enzymes for virus replication and maturation. Unlike HIV-1 Pol (expressed as a Gag–Pol fusion protein), foamy virus (described as an ancient retrovirus) expresses Pol without forming Gag–Pol polyproteins. We placed a “self-cleaving” 2A peptide between HIV-1 Gag and Pol. This construct, designated G2AP, is capable of producing virions with the same density as a wild-type (wt) HIV-1 particle. The 2A peptide allows for Pol to be packaged into virions independently from Gag following co-translationally cleaved from Gag. We found that G2AP exhibited only one-third the virus infectivity of the wt, likely due, at least in part, to defects in Pol packaging. Attenuated protease (PR) activity, or a reduction in Pol expression due to the placement of 2A-mediated Pol in a normal Gag–Pol frameshift context, resulted in significant increases in virus yields and/or titers. This suggests that reduced G2AP virus yields were largely due to increased PR activity associated with overexpressed Pol. Our data suggest that HIV-1 adopts a gag/pol ribosomal frameshifting mechanism to support virus assembly via the efficient modulation of Gag–Pol/Gag expression, as well as to promote viral enzyme packaging. Our results help clarify the molecular basis of HIV-1 gene expression and assembly.

HIV-1 protease with leucine zipper fused at N-terminus exhibits enhanced linker amino acid-dependent activity

Background

HIV-1 protease (PR) activation is triggered by Gag-Pol dimerization. Premature PR activation results in reduced virion yields due to enhanced Gag cleavage. A p6* transframe peptide located directly upstream of protease is believed to play a modulating role in PR activation. Previous reports indicate that the C-terminal p6* tetra-peptide prevents premature PR activation triggered by a leucine zipper (LZ) dimerization motif inserted in the deleted p6* region. To clarify the involvement of C-terminal p6* residues in mitigating enhanced LZ-incurred Gag processing, we engineered constructs containing C-terminal p6* residue substitutions with and without a mutation blocking the p6*/PR cleavage site, and created other Gag or p6* domain-removing constructs. The capabilities of these constructs to mediate virus maturation were assessed by Western blotting and single-cycle infection assays.

Results

p6*-PR cleavage blocking did not significantly reduce the LZ enhancement effect on Gag cleavage when only four amino acid residues were present between the p6* and PR. This suggests that the potent LZ dimerization motif may enhance PR activation by facilitating PR dimer formation, and that PR precursors may trigger sufficient enzymatic activity without breaking off from the PR N-terminus. Enhanced LZ-induced activation of PR embedded in Gag-Pol was found to be independent of the Gag assembly domain. In contrast, the LZ enhancement effect was markedly reduced when six amino acids were present at the p6*-PR junction, in part due to impaired PR maturation by substitution mutations. We also observed that a proline substitution at the P3 position eliminated the ability of p6*-deleted Gag-Pol to mediate virus maturation, thus emphasizing the importance of C-terminal p6* residues to modulating PR activation.

Conclusions

The ability of HIV-1 C-terminal p6* amino acid residues to modulate PR activation contributes, at least in part, to their ability to counteract enhanced Gag cleavage induced by a leucine zipper substituted for a deleted p6*. Changes in C-terminal p6* residues between LZ and PR may affect PR-mediated virus maturation, thus providing a possible method for assessing HIV-1 protease precursor activation in the context of virus assembly.

FRET analysis of HIV-1 Gag and GagPol interactions

The Gag protein of HIV multimerizes to form viral particles. The GagPol protein encoding virus‐specific enzymes, such as protease, reverse transcriptase, and integrase, is incorporated into HIV particles via interactions with Gag. The catalytically active forms of these enzymes are dimeric or tetrameric. We employed Förster resonance energy transfer (FRET) assays to evaluate Gag–Gag, Gag–GagPol, and GagPol–GagPol interactions and investigated Gag and Pol interdomains tolerant to fluorescent protein insertion for FRET assays. Our data indicated that the matrix (MA)–capsid (CA) domain junction in the Gag region and the Gag C terminus were equally available for Gag–Gag and Gag–GagPol interaction assays. For GagPol dimerization assays, insertion at the MA–CA domain junction was most favorable.

p6gag domain confers cis HIV-1 Gag-Pol assembly and release capability

During virus assembly, HIV-1 Gag-Pol is packaged into virions via interaction with Pr55gag. Studies suggest that Gag-Pol by itself is incapable of virus particle assembly or cell release, perhaps due to the lack of a budding domain in the form of p6gag, which is truncated within Gag-Pol because of a ribosomal frameshift during Gag translation. Additionally (or alternatively), large molecular size may not support Gag-Pol assembly into virus-like particles (VLPs) or release from cells. To test these hypotheses, we constructed Gag-Pol expression vectors retaining and lacking p6gag, and then reduced Gag-Pol molecular size by removing various lengths of the Pol sequence. Results indicate that Gag-Pol constructs retaining p6gag were capable of forming VLPs with a WT HIV-1 particle density. Gag-Pol molecular size reduction via partial removal of the Pol sequence mitigated the Gag-Pol assembly defect to a moderate degree. Our results suggest that the Gag-Pol assembly and budding defects are largely due to a lack of p6gag, but also in part due to size limitation.

Gag-Pol Transframe Domain p6* Is Essential for HIV-1 Protease-Mediated Virus Maturation

HIV-1 protease (PR) is encoded by pol, which is initially translated as a Pr160^gag-pol polyprotein by a ribosomal frameshift event. Within Gag-Pol, truncated p6gag is replaced by a transframe domain (referred to as p6* or p6pol) located directly upstream of PR. p6* has been proposed as playing a role in modulating PR activation. Overlapping reading frames between p6* and p6gag present a challenge to researchers using genetic approaches to studying p6* biological functions. To determine the role of p6* in PR activation without affecting the gag reading frame, we constructed a series of Gag/Gag-Pol expression vectors by duplicating PR with or without p6* between PR pairs, and observed that PR duplication eliminated virus production due to significant Gag cleavage enhancement. This effect was mitigated when p6* was placed between the two PRs. Further, Gag cleavage enhancement was markedly reduced when either one of the two PRs was mutationally inactivated. Additional reduction in Gag cleavage efficiency was noted following the removal of p6* from between the two PRs. The insertion of a NC domain (wild-type or mutant) directly upstream of PR or p6*PR did not significantly improve Gag processing efficiency. With the exception of those containing p6* directly upstream of an active PR, all constructs were either noninfectious or weakly infectious. Our results suggest that (a) p6* is essential for triggering PR activation, (b) p6* has a role in preventing premature virus processing, and (c) the NC domain within Gag-Pol is not a major determinant of PR activation.

Placement of leucine zipper motifs at the carboxyl terminus of HIV-1 protease significantly reduces virion production

Natural HIV-1 protease (PR) is homodimeric. Some researchers believe that interactions between HIV-1 Gag-Pol molecules trigger the activation of embedded PR (which mediates Gag and Gag-Pol cleavage), and that Gag-Pol assembly domains outside of PR may contribute to PR activation by influencing PR dimer interaction in a Gag-Pol context. To determine if the enhancement of PR dimer interaction facilitates PR activation, we placed single or tandem repeat leucine zippers (LZ) at the PR C-terminus, and looked for a correlation between enhanced Gag processing efficiency and increased Gag-PR-LZ multimerization capacity. We found significant reductions in virus-like particles (VLPs) produced by HIV-1 mutants, with LZ fused to the end of PR as a result of enhanced Gag cleavage efficiency. Since VLP production can be restored to wt levels following PR activity inhibition, this assembly defect is considered PR activity-dependent. We also found a correlation between the LZ enhancement effect on Gag cleavage and enhanced Gag-PR multimerization. The results suggest that PR dimer interactions facilitated by forced Gag-PR multimerization lead to premature Gag cleavage, likely a result of premature PR activation. Our conclusion is that placement of a heterologous dimerization domain downstream of PR enhances PR-mediated Gag cleavage efficiency, implying that structural conformation, rather than the primary sequence outside of PR, is a major determinant of HIV-1 PR activation.

Mutations in the HIV-1 reverse transcriptase tryptophan repeat motif affect virion maturation and Gag-Pol packaging

Our goal was to determine the contribution of HIV-1 reverse transcriptase tryptophan repeat motif residues to virion maturation. With the exception of W402A, we found none of the single substitution mutations exerted major impacts on virus assembly or processing. However, all mutants except for W410A exhibited significant decreases in virus-associated RT, presumably a result of unstable RT mutant degradation. Mutations W398A, W401A and W406A decreased the enhancement effect of efavirenz on PR-mediated Gag processing efficiency, which is in agreement with their destabilizing RT effects. Furthermore, combined double or triple W398, W401 and W406 mutations significantly affected virus processing and Gag-Pol packaging. Further analyses suggest that inefficient PR-mediated Gag cleavage partly accounts for the virion processing defect. Our results support the idea that in addition to playing a role in RT heterodimer stabilization, the RT Trp repeat motif in the Gag-Pol context is also involved in PR activation via Gag-Pol/Gag-Pol interaction.

Sequential deletion of the integrase (Gag-Pol) carboxyl terminus reveals distinct phenotypic classes of defective HIV-1

A requisite step in the life cycle of human immunodeficiency virus type 1 (HIV-1) is the insertion of the viral genome into that of the host cell, a process catalyzed by the 288-amino-acid (32-kDa) viral integrase (IN). IN recognizes and cleaves the ends of reverse-transcribed viral DNA and directs its insertion into the chromosomal DNA of the target cell. IN function, however, is not limited to integration, as the protein is required for other aspects of viral replication, including assembly, virion maturation, and reverse transcription. Previous studies demonstrated that IN is comprised of three domains: the N-terminal domain (NTD), catalytic core domain (CCD), and C-terminal domain (CTD). Whereas the CCD is mainly responsible for providing the structural framework for catalysis, the roles of the other two domains remain enigmatic. This study aimed to elucidate the primary and subsidiary roles that the CTD has in protein function. To this end, we generated and tested a nested set of IN C-terminal deletion mutants in measurable assays of virologic function. We discovered that removal of up to 15 residues (IN 273) resulted in incremental diminution of enzymatic function and infectivity and that removal of the next three residues resulted in a loss of infectivity. However, replication competency was surprisingly reestablished with one further truncation, corresponding to IN 269 and coinciding with partial restoration of integration activity, but it was lost permanently for all truncations extending N terminal to this position. Our analyses of these replication-competent and -incompetent truncation mutants suggest potential roles for the IN CTD in precursor protein processing, reverse transcription, integration, and IN multimerization.

A single amino acid substitution in HIV-1 reverse transcriptase significantly reduces virion release

HIV-1 protease (PR) mediates the proteolytic processing of virus particles during or after virus budding. PR activation is thought to be triggered by appropriate Gag-Pol/Gag-Pol interaction; factors affecting this interaction either enhance or reduce PR-mediated cleavage efficiency, resulting in markedly reduced virion production or the release of inadequately processed virions. We previously showed that a Gag-Pol deletion mutation involving the reverse transcriptase tryptophan (Trp) repeat motif markedly impairs PR-mediated virus maturation and that an alanine substitution at W401 (W401A) or at both W401 and W402 (W401A/W402A) partially or almost completely negates the enhancement effect of efavirenz (a nonnucleoside reverse transcriptase inhibitor) on PR-mediated virus processing efficiency. These data suggest that the Trp repeat motif may contribute to the PR activation process. Here we demonstrate that due to enhanced Gag cleavage efficiency, W402 alanine or leucine substitution significantly reduces virus production. However, W402 replacement with phenylalanine does not significantly affect virus particle assembly or processing, but it does markedly impair viral infectivity in a single-cycle infection assay. Our results demonstrate that a single amino acid substitution at HIV-1 RT can radically affect virus assembly by enhancing Gag cleavage efficiency, suggesting that in addition to contributing to RT biological function during the early stages of virus replication, the HIV-1 RT tryptophan repeat motif in a Gag-Pol context may play an important role in suppressing the premature activation of PR during late-stage virus replication.

The impact of altered polyprotein ratios on the assembly and infectivity of Mason-Pfizer monkey virus

Most retroviruses employ a frameshift mechanism during polyprotein synthesis to balance appropriate ratios of structural proteins and enzymes. To investigate the requirements for individual precursors in retrovirus assembly, we modified the polyprotein repertoire of Mason-Pfizer monkey virus (M-PMV) by mutating the frameshift sites to imitate the polyprotein organization of Rous sarcoma virus (Gag-Pro and Gag-Pro-Pol) or Human immunodeficiency virus (Gag and Gag-Pro-Pol). For the "Rous-like" virus, assembly was impaired with no incorporation of Gag-Pro-Pol into particles and for the "HIV-like" virus an altered morphogenesis was observed. A mutant expressing Gag and Gag-Pro polyproteins and lacking Gag-Pro-Pol assembled intracellular particles at a level similar to the wild-type. Gag-Pro-Pol polyprotein alone neither formed immature particles nor processed the precursor. All the mutants were non-infectious except the "HIV-like", which retained fractional infectivity.

Mutations at human immunodeficiency virus type 1 reverse transcriptase tryptophan repeat motif attenuate the inhibitory effect of efavirenz on virus production

HIV-1 virus particle processing is mediated by protease (PR), with enzymatic activation triggered by Gag-Pol/Gag-Pol interaction. We previously reported that truncation mutations at the reverse transcriptase (RT) connection subdomain markedly impair virus particle processing, suggesting an important role for the RT subdomain in PR-mediated virus processing. A highly conserved tryptophan (Trp) repeat motif of the HIV-1 RT connection subdomain is involved in RT dimerization. Our goal in this study was to determine whether mutations at the Trp repeat motif have any effect on PR-mediated virus processing. Our results indicate that even though alanine substitutions at W401 (W401A) or at both W401 and W402 (W401A/W402A) have no major effect on steady-state virus processing, the combined W401A/W402A mutations partially negate and the W401A mutation almost completely negates an efavirenz (EFV)-imposed barrier to virus production. The combination of RT instability and poor enzymatic activity reflects a RT dimerization defect incurred by the mutations. We also found that an artificial p66RT carrying the W401A or W401A/W402A mutations was packaged into virions more efficiently than wild-type p66RT, and that the viral incorporation of p66RT is significantly reduced by EFV, implying a novel effect of EFV on RT-Gag interaction. Our results suggest that the Trp repeat motif may play a role in the Gag-Pol/Gag-Pol interaction that contributes to subsequent PR activation.

HIV-1 matrix protein repositioning in nucleocapsid region fails to confer virus-like particle assembly

The HIV-1 matrix (MA) protein is similar to nucleocapsid (NC) proteins in its propensity for self-interaction and association with RNA. Here we report on our finding that replacing MA with NC results in the production of wild type (wt)-level RNA and virus-like particles (VLPs). In contrast, constructs containing MA as a substitute for NC are markedly defective in VLP production and form virions with lower densities than wt, even though their RNA content is over 50% that of wt level. We also noted that a ΔMN mutant lacking both MA and NC produces a relatively higher amount of VLPs than those in which MA was substituted for NC. Although ΔMN contains approximately 30% the RNA of wt, it still exhibits virion densities equal (or very similar) to those of wt. The data suggest that neither NC nor RNA are major virion density determinants. Furthermore, we noted that NC(ZIP)—a NC replacement with a leucine zipper dimerization motif—produces VLPs as efficiently as wt. However, the markedly reduced assembly efficiency of NC(ZIP) is associated with the formation of VLPs with densities slightly lower than those of wt following MA removal, suggesting that (a) MA is required to help the inserted leucine zipper motif perform efficient Gag multimerization, and (b) MA plays a role in the virus assembly process.

Targeting human immunodeficiency virus type 1 assembly, maturation and budding

The targets for licensed drugs used for the treatment of human immunodeficiency virus type 1 (HIV-1) are confined to the viral reverse transcriptase (RT), protease (PR), and the gp41 transmembrane protein (TM). While currently approved drugs are effective in controlling HIV-1 infections, new drug targets and agents are needed due to the eventual emergence of drug resistant strains and drug toxicity. Our increased understanding of the virus life-cycle and how the virus interacts with the host cell has unveiled novel mechanisms for blocking HIV-1 replication. This review focuses on inhibitors that target the late stages of virus replication including the synthesis and trafficking of the viral polyproteins, viral assembly, maturation and budding. Novel approaches to blocking the oligomerization of viral enzymes and the interactions between viral proteins and host cell factors, including their feasibility as drug targets, are discussed.

Mutations in capsid major homology region affect assembly and membrane affinity of HIV-1 Gag

We introduced mutations into the HIV-1 major homology region (MHR; capsids 153-172) and adjacent C-terminal region to analyze their effects on virus-like particle (VLP) assembly, membrane affinity, and the multimerization of the Gag structural protein. Results indicate that alanine substitutions at K158, F168 or E175 significantly diminished VLP production. All assembly-defective Gag mutants had markedly reduced membrane-binding capacities, but results from a velocity sedimentation analysis suggest that most of the membrane-bound Gag proteins were present, primarily in a higher-order multimerized form. The membrane-binding capacity of the K158A, F168A, and E175A Gag proteins increased sharply upon removal of the MA globular domain. While demonstrating improved multimerization capability, the two MA-deleted versions of F168A and E175A did not show marked improvement in VLP production, presumably due to a defect in association with the raft-like membrane domain. However, K158A bound to detergent-resistant raft-like membrane; this was accompanied by noticeably improved VLP production following MA removal. Our results suggest that the HIV-1 MHR and adjacent downstream region facilitate multimerization and tight Gag packing. Enhanced Gag multimerization may help expose the membrane-binding domain and thus improve Gag membrane binding, thereby promoting Gag multimerization into higher-order assembly products.

The SIVmac239 Pr55Gag isoform, SIV p43, suppresses proteolytic cleavage of Pr55Gag

In human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus (SIV) the gag gene encodes the precursor polyprotein Pr55Gag, which is cleaved by the viral protease to produce the major structural proteins. Recently, it has been shown that HIV and SIV gag RNAs contain internal ribosome entry sites (IRESs) that mediate translation of Pr55Gag [Pr57Gag in HIV type 2 (HIV-2)] isoforms. Previously, we demonstrated that SIVmac239 p43(-), a mutant that does not express the Pr55Gag isoform, SIV p43, replicates more efficiently than wild-type (WT) SIVmac239 in cell culture. In this study, we characterize SIVmac239 p43(-) virion production and demonstrate that, in the absence of SIV p43, cleavage of Pr55Gag is increased in budded virions, resulting in a higher percentage of mature particles. Additionally, intracellular cleavage of Pr55Gag is increased in SIVmac239 p43(-), suggesting that SIV p43 suppresses premature cleavage of Pr55Gag by the viral protease.

Incorporation of human immunodeficiency virus type 1 reverse transcriptase into virus-like particles

We demonstrate that a genetically engineered human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) composed mainly of p66 or p51 subunits can be incorporated into virus-like particles (VLPs) when coexpressed with HIV-1 Pr55(gag). VLP-associated RT exhibited a detergent-resistant association with immature cores during sucrose gradient equilibrium centrifugation, suggesting that RT is incorporated into VLPs. However, RT that retains downstream integrase (IN) is severely inhibited in terms of incorporation into VLPs. Results from immunofluorescence tests reveal that RT-IN is primarily localized at the perinuclear area and exhibits poor colocalization with Gag. IN removal leads to a redistribution of RT throughout the cytoplasm and improved RT incorporation into VLPs. Similar results were observed for RT-IN in which alanine was substituted for 186-Lys-Arg-Lys-188 residues of the IN putative nuclear localization signal, suggesting that IN karyophilic properties may partly account for the inhibitory effect of IN on RT incorporation. Although the membrane-binding capacity of RT was markedly reduced compared to that of wild-type Gag or Gag-Pol, the correlation of membrane-binding ability with particle incorporation efficiency was incomplete. Furthermore, we observed that membrane-binding-defective myristylation-minus RT can be packaged into VLPs at the same level as its normal myristylated counterpart. This suggests that the incorporation of RT into VLPs is independent of membrane affinity but very dependent on RT-Gag interaction. Results from a genetic analysis suggest that the Gag-interacting regions of RT mainly reside in the thumb subdomain and that the RT-binding domains of Gag are located in the matrix (MA) and p6 regions.

Effects of human immunodeficiency virus type 1 transframe protein p6* mutations on viral protease-mediated Gag processing

The proteolytic processing of human immunodeficiency virus (HIV) particles mediated by the viral pol-encoded protease (PR) is essential for viral infectivity. The pol coding sequence partially overlaps with the gag coding sequence and is translated as a Gag-Pol polyprotein precursor. Within Gag-Pol, the C-terminal p6(gag) domain is replaced by a transframe peptide referred to as p6*, which separates the Gag nucleocapsid domain from PR. Several previous in vitro studies have ascribed a PR-suppression regulatory function to p6*. Here, it was demonstrated that an HIV-1 Gag-Pol lacking p6* is efficiently incorporated into virions when coexpressed with HIV-1 Gag precursor. However, the released virions are not processed appropriately and show a greatly reduced viral infectivity. This suggests that the p6* is indispensable during the process of PR-mediated virus particle maturation.

Mutations in the alpha-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 alpha-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 alpha-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.

A domain directly C-terminal to the major homology region of human immunodeficiency type 1 capsid protein plays a crucial role in directing both virus assembly and incorporation of Gag-Pol

We demonstrate here that a deletion of 14 amino acid residues directly C-terminal to the major homology region (MHR) of the HIV-1 capsid (CA) in Gag-Pol markedly affects the incorporation of Gag-Pol into virions. The 14-amino acid deletion also significantly impaired virus assembly. In agreement with previous reports, mutations at the very C-terminus of CA resulted in a remarkable reduction in virus production. However, HIV-1 Gag-Pol precursors containing the C-terminal CA mutation were still capable of being incorporated into virions at a level of about 50% that of the wild-type. These results suggest that the domain immediately C-terminal to the MHR is functionally involved in Gag-Gag and Gag/Gag-Pol interaction, and this supports the notion that Gag or Gag-Pol mutants blocked in assembly into virus particles can be rescued into virions provided they retain the domains that are able to interact with the Gag precursor. An HIV-1 Gag-Pol deletion mutant retaining a minimal sequence consisting of the MHR and the adjacent CA-SP1 was efficiently incorporated into virions. Analysis by immunofluorescence staining indicated that the subcellular localization patterns shown by the Gag-Pol mutants were not fully compatible with their efficiency in being incorporated into virions, suggesting that the ability of Gag-Pol mutants to be incorporated into virions largely depends on their interactions with the Gag precursor.

The human immunodeficiency virus type 1 carboxyl-terminal third of capsid sequence in Gag-Pol is essential but not sufficient for efficient incorporation of Pr160(gag-pol) into virus particles

To elucidate the role of the C-terminal portion of Gag in the incorporation of human immunodeficiency virus type 1 (HIV-1) Gag-Pol into virus particles, a series of HIV-1 Gag-Pol mutants with deletions in the C-terminal gag sequence was constructed and viral incorporation of the Gag-Pol deletion mutants was analyzed using co-transfecting 293T cells with a Pr55(gag) expression plasmid. The biological function of the incorporated HIV-1 pol gene product was tested using an infectivity assay of the released virus particles which were pseudotyped with the murine leukemia virus Env. Analysis indicated that Gag-Pol deletion mutants, with a removal of the matrix (MA) and/or nucleocapsid (NC) or of the N-terminal two thirds of the gag coding sequence, could be incorporated efficiently into virus particles and produce significant amounts of infectious virions when assayed in a single-cycle infection assay. In contrast, mutations involving a deletion of the major homology region and the adjacent C-terminal capsid sequence significantly affected Gag-Pol incorporation. However, incorporation into virus particles of a Gag-Pol deletion mutant retaining both the major homology region and the adjacent C-terminal capsid intact was still severely impaired. This suggests that the capsid major homology region and the adjacent C-terminal capsid sequence in Gag-Pol are necessary but not sufficient for the incorporation of HIV-1 Pr160(gag-pol) into virus particles.

Characterization of human immunodeficiency virus type 1 Pr160 gag-pol mutants with truncations downstream of the protease domain

We have constructed a series of HIV-1 Gag-pol mutants by progressive deletion of the pol sequence downstream of the viral protease (PR) domain. Effects of the truncation mutations on virus particle production and Gag particle processing were analyzed. Analysis indicated that removal of the integrase (IN) domain had no major effect on the efficiency of particle processing, but resulted in a marked reduction in virus particle budding. Deletion of both the IN and RNase H domains, however, restored the production of virus particles to wild-type level. The proteolytic processing of virus particle was significantly impaired when the p51RT domain was truncated. All of the truncated Gag-pol proteins could be incorporated into virus particles and demonstrated an immunofluorescence staining pattern similar to that of the wild type (wt). Our data are consistent with the proposal that signals for directing the Gag-pol transport and particle incorporation are determined by its N-terminal Gag domain. Truncated Gag-pol retaining an intact p51RT was able to complement a PR-defective mutant to produce infectious pseudotyped virions, with a virus titer 20-70% of that of wt. Pseudotyped virions produced by the Gag-pol lacking an intact p51RT were noninfectious or poorly infectious. This suggests that an intact p51RT domain is required for the Gag-pol to mediate production of mature infectious virus particles in trans.

Selected amino acid substitutions in the C-terminal region of human immunodeficiency virus type 1 capsid protein affect virus assembly and release

The capsid protein (CA or p24) of human immunodeficiency virus type 1 (HIV-1) plays a major role both early and late in the virus replication cycle. Many studies have suggested that the C-terminal domain of this protein is involved in dimerization and proper assembly of the viral core. Point mutations were introduced in two conserved sites of this region and their effects on viral protein expression, particle assembly and infectivity were studied. Eight different mutants (L205A+P207A, L205A, P207A, 223GPG225AAA, G223A, P224A, G225A and V221G) of the infectious clone pNL4-3 were constructed. Most substitutions had no substantial effect on HIV-1 protein synthesis, yet they impaired viral infectivity and particle production. The two mutants P207A and V221G also had a profound effect on Gag–Pol protein processing in HeLa–tat cells. However, these results were cell line-specific and Gag–Pol processing of P207A was not affected in 293T cells. In HeLa–tat cells, no virus particles were detected with the P207A mutation, whereas the other mutant virus particles were heterogeneous in size and morphology. None of the mutants showed normal, mature, conical core structures in HeLa–tat cells. These results indicate that the two conserved sequences in the C-terminal CA domain are essential for proper morphogenesis and infectivity of HIV-1 particles.

Incorporation of pol into human immunodeficiency virus type 1 Gag virus-like particles occurs independently of the upstream Gag domain in Gag-pol

By using particle-associated reverse transcriptase (RT) activity as an assay for Pol incorporation into human immunodeficiency virus type 1 (HIV-1) Gag virus-like particles (VLPs), it has been found that truncated, protease-negative, Gag-Pol missing cis Gag sequences is still incorporated into Gag VLPs, albeit at significantly reduced levels (10 to 20% of the level of wild-type Gag-Pol). In this work, we have directly measured the incorporation of truncated Gag-Pol species into Gag VLPs and have found that truncated Gag-Pol that is missing all sequences upstream of RT is still incorporated into Gag VLPs at levels approximating 70% of that achieved by wild-type Gag-Pol. Neither protease nor integrase regions in Pol are required for its incorporation, implying an interaction between Gag and RT sequences in the Pol protein. While the incorporation of Gag-Pol into Gag VLPs is reduced 12-fold by the replacement of the nucleocapsid within Gag with a leucine zipper motif, this mutation does not affect Pol incorporation. However, the deletion of p6 in Gag reduces Pol incorporation into Gag VLPs four- to fivefold. Pol shows the same ability as Gag-Pol to selectively package tRNA(Lys) into Gag VLPs, and primer tRNA(3)(Lys) is found annealed to the viral genomic RNA. These data suggest that after the initial separation of Gag from Pol during cleavage of Gag-Pol by viral protease, the Pol species still retains the capacity to bind to both Gag and tRNA(3)(Lys), which may be required for Pol and tRNA(3)(Lys) to be retained in the assembling virion until budding is completed.

The virus-associated human immunodeficiency virus type 1 Gag-Pol carrying an active protease domain in the matrix region is severely defective both in autoprocessing and in trans processing of gag particles

We have previously demonstrated that a human immunodeficiency virus (HIV) chimeric Gag protein containing a partial replacement of the matrix domain by the viral protease domain (PR) could undergo autoprocessing with no virus particle production [J. Virol. 74 (2000) 3418]. To further analyze the effects of repositioned PR on virus particle production and Gag-Pol incorporation, we introduced the chimeric PR construct into a PR-negative Gag-Pol expression plasmid and coexpressed the resultant construct with a Pr55(gag) expression plasmid (pGAG) in 293T cells. Analysis indicated that the chimeric PR was similar to native PR in that both could prevent virus particle production in cotransfections with an equivalent amount of pGAG plasmid DNA, suggesting an efficient trans processing of Pr55(gag) by the chimeric PR. In cotransfections with the pGAG at a DNA ratio of 1:10 to 1:20, which resembles the normal intracellular expression ratio of Gag-Pol to Gag, Gag-Pol carrying the PR in the Gag coding region could undergo autoprocessing in cells and was incorporated into virus particles at a level about 20-40% of that of wild-type Gag-Pol. However, the incorporated chimeric Gag-Pol was unable to autocleave and unable to process the Gag particles properly, as mature particle-associated reverse transcriptase (RT) and p24(gag) proteins were barely detected. Our data strongly suggest that positioning an active HIV PR in the matrix region significantly affects the PR-mediated virus particle maturation.

Rapid localization of Gag/GagPol complexes to detergent-resistant membrane during the assembly of human immunodeficiency virus type 1

During human immunodeficiency virus type 1 (HIV-1) assembly in HIV-1-transfected COS7 cells, almost all steady-state Gag/Gag and Gag/GagPol complexes are membrane bound. However, exposure to 1% Triton X-100 gives results indicating that while all Gag/GagPol complexes remain associated with the detergent-resistant membrane (DRM), only 30% of Gag/Gag complexes are associated with the DRM. Analysis of the localization of newly synthesized Gag/Gag and Gag/GagPol to the membrane indicates that after a 10-min pulse with radioactive [(35)S]Cys-[(35)S]Met, all newly synthesized Gag/GagPol is found at the DRM. Only 30% of newly synthesized Gag/Gag moves to the membrane, and at 0 min of chase, only 38% of this membrane-bound Gag/Gag is associated with the DRM. During the first 30 min of chase, most membrane-bound Gag/Gag moves to the DRM, while between 30 and 60 min of chase, there is a significant decrease in membrane-bound Gag/Gag and Gag/GagPol. Since the localization of newly synthesized Gag/Gag to the DRM and the interaction of GagPol with Gag both depend upon Gag multimerization, the rapid localization of GagPol to the DRM probably reflects the interaction of all newly synthesized GagPol with the first newly synthesized polymeric Gag to associate with the DRM.