Human immunodeficiency virus protease expressed in Escherichia coli exhibits autoprocessing and specific maturation of the gag precursor.

The mature gag and pol proteins of human immunodeficiency virus (HIV) and all retroviruses derive from large gag and gag-pol polyprotein precursors by posttranslational cleavage. A highly specific, virally encoded protease is required for this essential proteolytic processing. In this study, the HIV protease gene product was expressed in Escherichia coli and shown to autocatalyze its maturation from a larger precursor. In addition, this bacterially produced HIV protease specifically processed an HIV p55 gag polyprotein precursor when coexpressed in E. coli. This system will allow detailed structure-function analysis of the HIV protease and provides a simple assay for the development of potential therapeutic agents directed against this critical viral enzyme.     

An inhibitor of the protease blocks maturation of human and simian immunodeficiency viruses and spread of infection.

The activity of the human immunodeficiency virus (HIV) protease is essential for processing of the gag-pol precursor proteins and maturation of infectious virions. We have prepared a peptidomimetic inhibitor, U-75875, that inhibited HIV-1 gag-pol protein processing in an essentially irreversible manner. Noninfectious virus particles produced in the presence of the drug contained gag precursors and were morphologically immature. In human peripheral blood mononuclear cells and in a continuous cell line, U-75875 completely blocked HIV replication; in the latter case, no spread occurred over a period of 4 weeks. U-75875, on a molar basis, was as potent as 3'-azido-3'-deoxythymidine in blocking HIV-1 replication in human lymphocytes and also inhibited HIV-2 and simian immunodeficiency virus proteases, demonstrating that it has broad activity. These results provide further evidence for the therapeutic potential of protease inhibitors in HIV infection.     

Deletion of sequences upstream of the proteinase improves the proteolytic processing of human immunodeficiency virus type 1.

Human immunodeficiency virus type 1 expresses structural proteins and replicative enzymes within gag and gag-pol precursor polyproteins. Specific proteolytic processing of the precursors by the viral proteinase is essential for maturation of infectious viral particles. We have studied the activity of proteinase in its immature form, as part of a gag-pol fusion protein, in an in vitro expression system. We found that deletion of p6*, the region in pol upstream of proteinase, resulted in improved processing of the precursor. A modified proteinase is released, but it functions less efficiently than wild type. Improved autoprocessing correlates with increased accessibility of the active site region in the polyprotein carrying the p6* deletion. Our results suggest that p6* is involved in the regulation of proteinase activation, perhaps as a region limiting the interaction of the active site and substrate binding domain with the remainder of the polyprotein. Release of p6* inhibition may be an activation step necessary for infectious particle maturation.     

Proteasome inhibition interferes with gag polyprotein processing, release, and maturation of HIV-1 and HIV-2

Retrovirus assembly and maturation involve folding and transport of viral proteins to the virus assembly site followed by subsequent proteolytic cleavage of the Gag polyprotein within the nascent virion. We report that inhibiting proteasomes severely decreases the budding, maturation, and infectivity of HIV. Although processing of the Env glycoproteins is not changed, proteasome inhibitors inhibit processing of Gag polyprotein by the viral protease without affecting the activity of the HIV-1 viral protease itself, as demonstrated by in vitro processing of HIV-1 Gag polyprotein Pr55. Furthermore, this effect occurs independently of the virus release function of the HIV-1 accessory protein Vpu and is not limited to HIV-1, as proteasome inhibitors also reduce virus release and Gag processing of HIV-2. Electron microscopy analysis revealed ultrastructural changes in budding virions similar to mutants in the late assembly domain of p6(gag), a C-terminal domain of Pr55 required for efficient virus maturation and release. Proteasome inhibition reduced the level of free ubiquitin in HIV-1-infected cells and prevented monoubiquitination of p6(gag). Consistent with this, viruses with mutations in PR or p6(gag) were resistant to detrimental effects mediated by proteasome inhibitors. These results indicate the requirement for an active proteasome/ubiquitin system in release and maturation of infectious HIV particles and provide a potential pharmaceutical strategy for interfering with retrovirus replication.     

Myristoylation-dependent replication and assembly of human immunodeficiency virus 1.

Covalent linkage of myristic acid to the N-terminal glycine residue of Pr55gag, the precursor of the major structural proteins of human immunodeficiency virus 1 (HIV-1), facilitates an essential step in virus assembly and propagation. Substitution of the myristoyl-acceptor glycine with alanine, in a functional clone of HIV-1, eliminates virus replication. Complementation of this defect, in trans, restores infectious particle production. The nonmyristoylated (myr-) gag precursor accumulates in infected cells and is not processed into the mature capsid components of the intact virion. However, myr- Pr55gag can be processed by purified HIV protease in vitro, demonstrating that the myristoyl moiety is not required for cleavage by the protease. Myristoylation of Pr55gag is not necessary for localization but is required for stable membrane association and assembly of HIV-1.     

Human immunodeficiency virus envelope protein determines the site of virus release in polarized epithelial cells.

In polarized epithelial cells, the release of enveloped viruses by budding at the cell surface is restricted to a specific cell membrane domain, either the apical or basolateral domain. To investigate the role of the envelope glycoprotein and the capsid proteins of human immunodeficiency virus type 1 (HIV-1) in determining the site of virus assembly, we analyzed virus maturation in a polarized monkey kidney cell line. A line of cells harboring the HIV-1 provirus (VERO-pFN) was found to differentiate into polarized epithelial cell monolayers upon reaching confluency. By electron microscopy, virus maturation was observed predominantly at the basolateral membranes of VERO-pFN cells. Analysis of HIV-1 proteins revealed that virtually all of glycoprotein gp120 and capsid protein p24 were found in the basolateral medium, while no HIV-1 proteins were detected apically. A recombinant vaccinia virus (VV) expressing the HIV-1 gag polyprotein (VVgag) was used to determine the site of release of HIV-1 core particles in polarized epithelial cells in the presence or absence of envelope glycoproteins. When cells were infected with VVgag in the absence of envelope proteins, similar amounts of the p24 capsid protein were released into virus particles at the apical or basolateral surface. In contrast, when cells were doubly infected with VVgag and a recombinant VV expressing the HIV-1 envelope glycoprotein (VVenv), 94% of p24 and all of gp120 were found to be associated with particles released into the basolateral medium. These results indicate that the HIV-1 envelope glycoprotein directly influences the site of release of virus particles containing the gag protein, probably via a specific interaction between the envelope protein and the gag protein.     

Cleavage of HIV-1 gag polyprotein synthesized in vitro: sequential cleavage by the viral protease

The virally encoded protease of human immunodeficiency virus is responsible for the processing of the gag and gag-pol polyprotein precursors to their mature polypeptides. Since correct processing of the viral polypeptides is essential for the production of infectious virus, HIV protease represents a potential target for therapeutic agents that may prove beneficial in the treatment of AIDS. In this study, full-length gag polyprotein has been synthesized in vitro to serve as a substrate for bacterially expressed HIV-1 protease. Expression of the protease in E. coli from the lac promoter was enhanced approximately five-fold by deletion of a potential hairpin loop upstream from the codon determining the amino terminus of mature protease. Extracts of induced cultures of E. coli harboring a protease-containing plasmid served as the source of protease activity. The gag polyprotein synthesized in vitro was cleaved by such lysates, producing fragments corresponding in size to p17 plus p24 and mature p24. Immunoprecipitations with monoclonal antibodies to p17 and p24 polypeptides suggest that initial cleavage of gag polyprotein occurs near the p24-p15 junction. The proteolysis was inhibited by pepstatin with an IC50 of 0.15 mM for cleavage at the p24-p15 junction and 0.02 mM for cleavage at the p17-p24 junction.     

Human immunodeficiency virus has an aspartic-type protease that can be inhibited by pepstatin A.

The protease encoded by the human immunodeficiency virus (HIV) processes the viral gag and gag-pol protein precursor by posttranslational cleavage. In this study we have demonstrated by site-specific mutagenesis (Asp----Thr) and by pepstatin A inhibition that the recombinant HIV protease is an aspartic-type protease. Furthermore, incubation of HIV-infected H9 cells with pepstatin A inhibited part of the intracellular processing of the HIV gag protein yet had no apparent toxicity on HIV-infected cells during 48 hr of incubation.     

Inhibition of bacterially expressed HIV protease activity determined by an in vitro cleavage assay with MuLV Pr65gag

HIV protease is a virally coded enzyme that cleaves gag as well as gag-pol precursor polyproteins into functional products needed for virus assembly. A pUC plasmid containing an HIV insert starting at the 5' end of the pol gene and ending just inside the intergrase coding sequence was expressed in E. coli. It provided an 11 kD gene product (protease) that specifically cleaved the Gazdar MuLV Pr65gag precursor into Pr40gag (p30 + p10) and Pr27gag (p15 + p12) intermediates, as well as lower molecular weight gag-encoded products. These were detected by immunoblotting with either MuLV anti-p30 or p12 sera. Using cleavage of MuLV Pr65gag as an assay system, pepstatin A, fusidic acid, and cerulenin were observed to inhibit HIV protease cleavage by greater than 50% at concentrations of 0.1, 0.2-0.5, and 0.5 mM, respectively.     

Chemical synthesis and enzymatic activity of a 99-residue peptide with a sequence proposed for the human immunodeficiency virus protease.

Retroviral proteins, including those from the human immunodeficiency virus (HIV), are synthesized as polyprotein precursors that require proteolytic cleavage to yield the mature viral proteins. A 99-residue polypeptide, encoded by the 5' end of the pol gene, has been proposed as the processing protease of HIV. The chemical synthesis of the 99-residue peptide was carried out by the solid-phase method, and the isolated product was found to exhibit specific proteolytic activity upon folding under reducing conditions. Upon size-exclusion chromatography, enzymatic activity was eluted at a point consistent with a dimeric molecular size. Specificity was demonstrated by the cleavage of the natural substrate HIV gag p55 into gag p24 and gag p17, as well as cleavage of small peptide substrates representing processing sites of HIV fusion proteins. The proteolytic action of the synthetic product could be inhibited by pepstatin, an aspartic protease inhibitor.     

Inhibition of human immunodeficiency virus 1 protease in vitro: rational design of substrate analogue inhibitors.

Inhibitors of the protease from human immunodeficiency virus 1 (HIV-1) were designed, synthesized, and kinetically characterized. Analogues of a heptapeptide substrate of HIV-1 protease with sequence similar to the p17-p24 cleavage site in the natural substrate, Pr55gag, were synthesized in which the scissile dipeptide bond was replaced with bonds from six categories of stable mimics of an aspartic proteolysis transition state or intermediate. These mimics included an analogue of statine, hydroxyethylene isosteres, two categories of phosphinic acids, a reduced amide isostere, and an alpha,alpha-difluoroketone. The resulting peptide analogues were linear competitive inhibitors of purified recombinant HIV-1 protease with inhibition constants ranging from 18 nM to 40 microM depending on the type of inhibitor. A truncated inhibitor, an analogue of a hexapeptide, retained full inhibitory potency. The most potent inhibitors, containing the hydroxyethylene isostere, effectively blocked the proteolytic processing of a recombinant form of Pr55gag by HIV-1 protease in a cell-free assay.     

Highly immunogenic human immunodeficiency viruslike particles are produced by recombinant vaccinia virus-infected cells

CV-1 cells were infected with two recombinant vaccinia viruses carrying the gag gene with deletion of 231 bp from 3' terminus (strain vC5) and env gene (strain vE234L) of human immunodeficiency virus type 1 (HIV-1). Both recombinant proteins synthesized in the cells (p50gag and gp160/120env) were localized predominantly in cell membranes; however, some amount of p50 was found in cell nuclei. Thin-section immunoelectron microscopy showed accumulation of viruslike particles undistinguished from immature HIV-1 virions in the culture medium of the cells infected with vC5. The similar particles containing gag and env proteins were produced into the culture medium when the cells were coinfected with vC5 and vE234L strains. The particles contained heterogeneous cellular RNA, but no virus-specific RNA as shown by Northern blot hybridization. Immunization of the rabbits with purified viruslike particles produced virus-specific antibodies against gag and env proteins. The titer of antibodies was significantly higher than after immunization with cell lysate or recombinant proteins purified from the infected cells. Highly immunogenic HIV-1-like particles containing gag and env proteins but no virus-specific RNA are good candidates for potential vaccine.     

Chimeric gag-V3 virus-like particles of human immunodeficiency virus induce virus-neutralizing antibodies.

A 41-kDa unprocessed human immunodeficiency virus 2 (HIV-2) gag precursor protein that has a deletion of a portion of the viral protease assembles as virus-like particles by budding through the cytoplasmic membrane of recombinant baculovirus-infected insect cells. We have constructed six different combinations of chimeric genes by coupling the truncated HIV-2 gag gene to the neutralizing domain (V3) or the neutralizing and the CD4 binding domains (V3+CD4BD) of gp120 env gene sequences from HIV-1 or HIV-2. The env gene sequences were inserted either into the middle of the gag gene or at the 3' terminus of the gag gene. Virus-like particles were formed by chimeric gene products only when the env gene sequences were linked to the 3' terminus of the gag gene. Insertion of env gene sequence in the middle of the gag gene resulted in high-level chimeric gene expression but without the formation of virus-like particles. Three different chimeric genes [gag gene with HIV-1 V3 (1V3), gag gene with HIV-2 V3 (2V3), and gag gene with HIV-2 V3+CD4BD (2V3+CD4BD)] formed virus-like particles that were secreted into the cell culture medium. In contrast, the HIV-1 V3+CD4BD/HIV-2 gag construct did not form virus-like particles. The chimeric gag-env particles had spherical morphology and the size was slightly larger than that of the gag particles, but the chimeric particles were similar to the mature HIV particles. Western blot analysis showed that the gag-env chimeric proteins were recognized by antibodies in HIV-positive human serum and rabbit anti-gp120 serum. Rabbit anti-gag 1V3 and anti-gag 2V3 sera reacted with authentic gp120 of HIV-1 and HIV-2, respectively, and neutralized homologous HIV infectivity. Our results show that precursor gag protein has potential as a carrier for the presentation of foreign epitopes in good immunological context. The gag protein is highly immunogenic and has the ability to carry large foreign inserts; as such, it offers an attractive approach for HIV vaccine development.     

Trans-dominant inhibitory human immunodeficiency virus type 1 protease monomers prevent protease activation and virion maturation.

Production of infectious human immunodeficiency virus (HIV) requires proper polyprotein processing by the dimeric viral protease. The trans-dominant inhibitory activity of a defective protease monomer with the active site Asp-25 changed to Asn was measured by transient transfection. A proviral plasmid that included the drug-selectable Escherichia coli gpt gene was used to deliver the wild-type (wt) or mutant proteases to cultured cells. Coexpression of the wt proviral DNA (HIV-gpt) with increasing amounts of the mutant proviral DNA (HIV-gpt D25N) results in a concomitant decrease in proteolytic activity monitored by in vivo viral polyprotein processing. The viral particles resulting from inactivation of the protease were mostly immature, consisting predominantly of unprocessed p55gag and p160gag-pol polyproteins. In the presence of HIV-1 gp160 env, the number of secreted noninfectious particles correlated with the presence of increasing amounts of the defective protease. Greater than 97% reduction in infectivity was observed at a 1:6 ratio of wt to defective protease DNA. This provides an estimate of the level of inhibition required for effectively preventing virion processing. Stable expression of the defective protease in monkey cells reduced the yield of infectious particles from these cells by 90% upon transfection with the wt proviral DNA. These results show that defective subunits of the viral protease exert a trans-dominant inhibitory effect resulting from the formation of catalytically compromised heterodimers in vivo, ultimately yielding noninfectious viral particles.     

HIV-1 env, nef, and gag-specific T-cell immunity in mice: conserved epitopes in nef p27 and gag p25 proteins.

Cellular immunogenicity of env gp160, nef p27, and gag p55 proteins of human immunodeficiency virus type 1 (HIV-1) was studied in mice immunized with vaccinia virus recombinants. Proliferative responses of spleen cells were comparable against env gp160, nef p27, and gag p25 recombinant proteins. No specific activity was observed against gag p18 protein. Env, nef, and gag-specific T-cell lines were generated by repeated stimulation of immune spleen cells with recombinant HIV-1 proteins. They were CD4 positive, proliferative, and also cytotoxic against HIV-transfected target cells. Specificity of the T-cell response against nef and gag protein was analyzed with synthetic peptides. Peptides nef 15, nef 16, and gag AM-30 were, respectively, reactive in nef- and gag-specific proliferative and cytolytic assays. The three peptides described have a relatively conserved amino acid sequence among HIV isolates and appear broadly immunoreactive among species.     

Complete nucleotide sequence of an infectious clone of human T-cell leukemia virus type II: an open reading frame for the protease gene.

The entire nucleotide sequence of an infectious clone of human T-cell leukemia virus type II provirus was determined. This provirus consists of 8952 nucleotides. In addition to long terminal repeats and gag, pol, env, and X, a protease gene that is responsible for processing the gag precursor protein was found. The protease gene is encoded in a different frame from gag and pol and was located between the gag and pol open reading frames. The 5' region of the protease gene overlaps the 3' gag region. Coding regions of the provirus show about 60% homology with those of human T-cell leukemia virus type I at the nucleotide level. The evolutionary relationship between human T-cell leukemia virus types I and II is discussed.