Reversion of the lethal phenotype of an HIV-1 integrase mutant virus by overexpression of the same integrase mutant protein

The human immunodeficiency virus type 1 (HIV-1) integrase (IN) is essential for integration of viral DNA into host cell chromatin. We have reported previously (Priet, S., Navarro, J. M., Gros, N., Querat, G., and Sire, J. (2003) J. Biol. Chem. 278, 4566-4571) that IN also plays a role in the packaging of the host uracil DNA glycosylase UNG2 into viral particles and that the region of IN encompassing residues 170-180 was responsible for the interaction with UNG2 and for its packaging into virions. In this work, we aimed to investigate the replication of HIV-1 viruses rendered deficient in virion-associated UNG2 by single or double point mutations in the region 170-180 of IN. We show that the L172A/K173A IN mutant virus was deficient for UNG2 packaging and was defective for replication because of a blockage at the stage of proviral DNA integration in host cell DNA. In vitro assays using long term repeat mimics, however, demonstrate that the L172A/K173A IN mutant was catalytically active. Moreover, trans-complementation experiments show that the viral propagation of L172A/K173A viruses could be rescued by the overexpression of Vpr.L172A/K173A IN fusion protein in a dose-dependent manner and that this rescue is independent of UNG2 packaging. Altogether, our data indicate that L172A/K173A mutations of IN induce a subtle defect in the function of IN, which nevertheless dramatically impairs viral replication. Unexpectedly, this blockage of replication could be overcome by forcing the packaging of higher amounts of this same mutated integrase. This is the first study reporting that blockage of the integration process of HIV-1 provirus carrying a mutation of IN could be alleviated by increasing amounts of IN even carrying the same mutations.     

Targeting of Chrolamphenicol Acetyltransferase to Human Immunodeficiency Virus Particles via Vpr and Vpx

Vpr and Vpx are the auxiliary proteins of human immunodeficiency viruses (HIVs) selectively incorporated into mature viral particles. We showed that the bacterial chloramphenicol acetyltransferase (CAT) fused to the N-terminus of HIV-1 Vpr, HIV-2 Vpr, or HIV-2 Vpx was incorporated into mature virions in a type-selective manner. By using chimeric proteins between HIV-1 Vpr and HIV-2 Vpx, we found that the N-terminal side of these proteins was mainly important for type-selective virion incorporation. The C-terminal arginine-rich region of HIV-1 Vpr was also found to transport CAT fusion proteins into virions but without any type selectivity. Furthermore, the corresponding regions of HIV-2 Vpr and HIV-2 Vpx had no such activity. This region of HIV-1 Vpr may interact nonspecifically with viral genomic RNA. Collectively, Vpr and Vpx may provide a means to introduce foreign proteins and other molecules into HIV virions for therapeutic purposes.     

Cellular distribution and karyophilic properties of matrix, integrase, and Vpr proteins from the human and simian immunodeficiency viruses

Infections by human and simian immunodeficiency viruses (HIV and SIV) are independent of host cell division since the preintegration complex (PIC), containing the viral DNA, is able to undergo active nuclear import after viral entry. In order to clarify the mechanisms responsible for nuclear import of the PIC, we have analyzed the subcellular distribution and the karyophilic properties of its viral components, matrix protein (MA), integrase (IN), Vpr, and Vpx. Although MA has been reported to contain a nuclear localization signal, the MA/GFP fusions are excluded from the nucleus and associated with cellular membranes. In contrast, both HIV-1 and SIV IN and Vpr localize in the nucleus of transfected cells. Interestingly, only Vpx from SIVsm virus accumulate in the nucleus while SIVsm Vpr is uniformly distributed throughout nucleus and cytoplasm. Coexpression of MA, Vpr, and IN does not induce any change in their respective intracellular localizations. Finally, we confirm the karyophilic properties of HIV-1 IN and Vpr using an in vitro nuclear import assay. These results indicate that the viral proteins IN and Vpr, which are strongly associated with the viral DNA within PIC, may participate in the nuclear import of the HIV PIC.     

Incorporation of functional human immunodeficiency virus type 1 integrase into virions independent of the Gag-Pol precursor protein.

Retroviral integrase (IN) is expressed and incorporated into virions as part of the Gag-Pol polyprotein precursor. IN catalyzes integration of the proviral DNA into host cell chromosomes during the early stages of the virus life cycle, and as a component of Gag-Pol, it is involved in virion morphogenesis during late stages. It is unknown whether the scheme, conserved among retroviruses, for expressing and incorporating IN as a component of the Gag-Pol precursor protein is necessary for its function in the infected cell after viral entry. We have developed human immunodeficiency virus (HIV) virion-associated accessory proteins (Vpr and Vpx) as vehicles to deliver both foreign and viral proteins into the virus particle by their expression in trans as heterologous fusion proteins (X. Wu, et al., J. Virol. 69:3389-3398, 1995; X. Wu, et al., J. Virol. 70:3378-3384, 1996; X. Wu, et al., EMBO J. 16:5113-5122, 1977). To analyze IN function independent of its expression as a part of Gag-Pol, we expressed and incorporated IN into HIV type 1 (HIV-1) virions in trans as a fusion partner of Vpr (Vpr-IN). Our results demonstrate that the Vpr-IN fusion protein is efficiently incorporated into virions and then processed by the viral protease to liberate the IN protein. Virus derived from IN-minus provirus is noninfectious. However, this defect is overcome by trans complementation with the Vpr-IN fusion protein. Moreover, complemented virions are able to replicate through a complete cycle of infection, including formation of the provirus (integration). These results show, for the first time, that full IN function can be provided in trans, independent of its expression and incorporation into virions as a component of Gag-Pol. This finding also indicates that the IN domain of Gag-Pol is not required for the formation of infectious virions when IN is provided in trans. The ability to incorporate functional IN into retroviral particles in trans will provide unique opportunities to explore the function of this critical enzyme in a biologically relevant context, i.e., in infected cells as part of the nucleoprotein/preintegration complex.     

Isolation of human immunodeficiency virus type 1 cores: retention of Vpr in the absence of p6(gag)

Mature human immunodeficiency virus type 1 (HIV-1) virions contain a typically cone-shaped core that encases the viral genome. In this study, we established conditions which allowed the efficient isolation of morphologically intact HIV-1 cores from virions. The isolated cores consisted mostly of cones which appeared uniformly capped at both ends but were heterogeneous with respect to the shape of the broad cap as well as the dimensions and angle of the cone. Vpr, a nonstructural virion component implicated in the nuclear import of the viral genome, was recovered in core preparations of HIV-1 and simian immunodeficiency viruses from African green monkeys. Unexpectedly, p6(gag), a structural protein required for the incorporation of Vpr, was absent from HIV-1 core preparations. Taken together, our results indicate that the incorporation of Vpr into the virion core is a conserved feature of primate lentiviruses and that the interactions required for the uptake of Vpr into assembling particles differ from those which confine Vpr within the core.     

Complementation of integrase function in HIV-1 virions.

Proviral integration is essential for HIV-1 replication and represents an important potential target for antiviral drug design. Although much is known about the integration process from studies of purified integrase (IN) protein and synthetic target DNA, provirus formation in virally infected cells remains incompletely understood since reconstituted in vitro assays do not fully reproduce in vivo integration events. We have developed a novel experimental system in which IN-mutant HIV-1 molecular clones are complemented in trans by Vpr-IN fusion proteins, thereby enabling the study of IN function in replicating viruses. Using this approach we found that (i) Vpr-linked IN is efficiently packaged into virions independent of the Gag-Pol polyprotein, (ii) fusion proteins containing a natural RT/IN processing site are cleaved by the viral protease and (iii) only the cleaved IN protein complements IN-defective HIV-1 efficiently. Vpr-mediated packaging restored IN function to a wide variety of IN-deficient HIV-1 strains including zinc finger, catalytic core and C-terminal domain mutants as well as viruses from which IN was completely deleted. Furthermore, trans complemented IN protein mediated a bona fide integration reaction, as demonstrated by the precise processing of proviral ends (5'-TG...CA-3') and the generation of an HIV-1-specific (5 bp) duplication of adjoining host sequences. Intragenic complementation between IN mutants defective in different protein domains was also observed, thereby providing the first evidence for IN multimerization in vivo.     

A leucine triplet repeat sequence (LXX)4 in p6gag is important for Vpr incorporation into human immunodeficiency virus type 1 particles.

Incorporation of Vpr into human immunodeficiency virus type 1 (HIV-1) virions is mediated by the Gag protein, independently of other viral components. We have coexpressed Vpr and Gag constructs in a vaccinia virus expression system in order to map the region of Gag involved in Vpr packaging. Deletion of the carboxyl-terminal p6 region of Gag impaired the ability of Gag to package Vpr. To confirm the role of p6 in Vpr packaging, Rous sarcoma virus (RSV)-HIV chimeras containing HIV-1 p6 were constructed. Although RSV Gag does not package Vpr into virus particles, a chimera containing HIV-1 p6 is sufficient for Vpr incorporation. To map the region of p6 involved in Vpr packaging, a series of p6 point mutations and deletion mutations was analyzed. Mutations in the N-terminal p6 proline-rich domain, for which preliminary evidence shows a marked decrease in virion incorporated RNA, did not affect Vpr incorporation. Deletion of residues 1 to 31 of HIV-1 p6 did not affect Vpr packaging, but residues 35 to 47, including an (LXX)4 domain, were required for Vpr incorporation into virus particles.     

Interaction with the p6 Domain of the Gag Precursor Mediates Incorporation into Virions of Vpr and Vpx Proteins from Primate Lentiviruses

Vpr and Vpx proteins from human and simian immunodeficiency viruses (HIV and SIV) are incorporated into virions in quantities equivalent to those of the viral Gag proteins. We demonstrate here that Vpr and Vpx proteins from distinct lineages of primate lentiviruses were able to bind to their respective Gag precursors. The capacity of HIV type 1 (HIV-1) Vpr mutants to bind to Pr55^Gag was correlated with their incorporation into virions. Molecular analysis of these interactions revealed that they required the C-terminal p6 domain of the Gag precursors. While the signal for HIV-1 Vpr binding lies in the leucine triplet repeat region of the p6 domain reported to be essential for incorporation, SIV_sm Gag lacking the equivalent region still bound to SIV_sm Vpr and Vpx, indicating that the determinants for Gag binding are located upstream of this region of the p6 domain. Binding to Gag cleavage products showed that HIV-1 Vpr interacted directly with the nucleocapsid protein (NC), whereas SIV_sm Vpr and Vpx did not interact with NC but with the p6 protein. These results (i) reveal differences between HIV-1 and SIV_sm for the p6 determinants required for Vpr and Vpx binding to Gag and (ii) suggest that HIV-1 Vpr and SIV_sm Vpr and Vpx interact with distinct cleavage products of the precursor following proteolytic processing in the virions.     

Cyclophilin A is required for the replication of group M human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus SIV(CPZ)GAB but not group O HIV-1 or other primate immunodeficiency viruses.

The human immunodeficiency virus type 1 (HIV-1) Gag polyprotein binds to cyclophilin A and incorporates this cellular peptidyl prolyl-isomerase into virions. Disruption of cyclophilin A incorporation, either by gag mutations or by cyclosporine A, inhibits virion infectivity, indicating that cyclophilin A plays an essential role in the HIV-1 life cycle. Using assays for packaging of cyclophilin A into virions and for viral replication sensitivity to cyclosporine A, as well as information gleaned from the alignment of Gag residues encoded by representative viral isolates, we demonstrate that of the five lineages of primate immunodeficiency viruses, only HIV-1 requires cyclophilin A for replication. Cloned viral isolates from clades A, B, and D of HIV-1 group M, as well as a phylogenetically related isolate from chimpanzee, all require cyclophilin A for replication. In contrast, the replication of two outlier (group O) HIV-1 isolates is unaffected by concentrations of cyclosporine A which disrupt cyclophilin A incorporation into virions, indicating that these viruses are capable of replicating independently of cyclophilin A. These studies identify the first phenotypic difference between HIV-1 group M and group O and are consistent with phylogenetic studies suggesting that the two HIV-1 groups were introduced into human populations via separate zoonotic transmission events.     

DNA binding properties of the integrase proteins of human immunodeficiency viruses types 1 and 2.

Integration of retroviral DNA into the host chromosome requires the integrase protein (IN). We overexpressed the IN proteins of human immunodeficiency viruses types 1 and 2 (HIV-1 and HIV-2) in E. coli and purified them. Both proteins were found to specifically cut two nucleotides off the ends of linear viral DNA, and to integrate viral DNA into target DNA. This demonstrates that HIV IN is the only protein required for integration of HIV DNA. Although the two types of IN proteins have only 53% amino acid sequence similarity, they act with equal efficiency on both type 1 and type 2 viral DNA. Binding of IN to DNA was tested: purified IN does not bind very specifically to viral DNA ends. Nevertheless, only viral DNA ends are cleaved and integrated. We interpret this as follows: in vitro quick aspecific binding to DNA is followed by slow specific cutting and integration. IN can not find viral DNA ends in the presence of an excess of aspecific DNA; in vivo this is not required since the IN protein is in constant proximity of viral DNA in the viral core particle.     

Nuclear export of Vpr is required for efficient replication of human immunodeficiency virus type 1 in tissue macrophages

Retroviruses must gain access to the host cell nucleus for subsequent replication and viral propagation. Human immunodeficiency virus type 1 (HIV-1) and other primate lentiviruses are distinguished from the gammaretroviruses by their ability to infect nondividing cells such as macrophages, an important viral reservoir in vivo. Rather than requiring nuclear membrane breakdown during cell division, the HIV-1 preintegration complex (PIC) enters the nucleus by traversing the central aqueous channel of the limiting nuclear pore complex. The HIV-1 PIC contains three nucleophilic proteins, matrix, integrase, and Vpr, all of which have been implicated in nuclear targeting. The mechanism by which Vpr can display such nucleophilic properties and yet also be available for incorporation into virions assembling at the plasma membrane is unresolved. We recently characterized Vpr as a nucleocytoplasmic shuttling protein that contains two novel nuclear import signals and an exportin-1-dependent nuclear export signal (NES). We now demonstrate that mutation of this NES impairs the incorporation of Vpr into newly formed virions. Furthermore, we find that the Vpr NES is required for efficient HIV replication in tissue macrophages present in human spleens and tonsils. These findings underscore how the nucleocytoplasmic shuttling of Vpr not only contributes to nuclear import of the HIV-1 PIC but also enables Vpr to be present in the cytoplasm for incorporation into virions, leading to enhancement of viral spread within nondividing tissue macrophages.     

Incorporation of Vpr into human immunodeficiency virus type 1 virions: requirement for the p6 region of gag and mutational analysis.

The product of the vpr open reading frame of human immunodeficiency virus type 1 (HIV-1) is a 15-kDa, arginine-rich protein that is present in virions in molar quantities equivalent to that of Gag. We report here the results of our investigations into the mechanism by which Vpr is incorporated into virions during assembly in infected cells. For these studies we used an expression vector encoding a Vpr molecule fused at its amino terminus to a nine-amino-acid peptide from influenza virus hemagglutinin. The tagged Vpr expression vector and a vpr mutant HIV-1 provirus were used to cotransfect COS cells, and the resulting virions were tested for the presence of the tagged protein on immunoblots probed with monoclonal antibody against the hemagglutinin peptide. The COS-produced virions were found to contain readily detectable amounts of tagged Vpr and smaller amounts of a putative tagged Vpr dimer. Infectivity of the particles was not altered by incorporation of tagged Vpr. Our results using this system in combination with mutant HIV-1 proviruses suggested that incorporation of Vpr into virions requires the carboxy-terminal Gag protein of HIV-1 (p6) but not gp160, Pol, or genomic viral RNA. In addition, analysis of mutated, tagged Vpr molecules suggested that amino acids near the carboxy terminus (amino acids 84 to 94) are required for incorporation of Vpr into HIV-1 virions. The single cysteine residue near the carboxy terminus was required for production of a stable protein. Arginine residues tested were not important for incorporation or stability of tagged Vpr. These results suggested a novel strategy for blocking HIV-1 replication.