The nef gene products of both simian and human immunodeficiency viruses enhance virus infectivity and are functionally interchangeable.

Adult rhesus macaques infected with nef-defective simian immunodeficiency virus (SIV) exhibit extremely low levels of steady-state virus replication, do not succumb to immunodeficiency disease, and are protected from experimental challenge with pathogenic isolates of SIV. Similarly, rare humans found to be infected with nef-defective human immunodeficiency virus type 1 (HIV-1) variants display exceptionally low viral burdens and do not show evidence of disease progression after many years of infection. HIV-1 Nef induces the rapid endocytosis and lysosomal degradation of cell surface CD4 and enhances virus infectivity in primary human T cells and macrophages. Although expression of SIV Nef also leads to down-modulation of cell surface CD4 levels, no evidence for SIV Nef-induced enhancement of virus infectivity was observed in earlier studies. Thus, it remains unclear whether fundamental differences exist between the activities of HIV-1 and SIV Nef. To establish more clearly whether the SIV and HIV-1 nef gene products are functionally analogous, we compared the replication kinetics and infectivity of variants of SIVmac239 that either do (SIVnef+) or do not (SIV delta nef) encode intact nef gene products. SIVnef+ replicates more rapidly than nef-defective viruses in both human and rhesus peripheral blood mononuclear cells (PBMCs). As previously described for HIV-1 Nef, SIV Nef also enhances virus infectivity within each cycle of virus replication. As a strategy for evaluating the in vivo contribution of HIV-1 nef alleles and long terminal repeat regulatory sequences to the pathogenesis of immunodeficiency disease, we constructed SIV-HIV chimeras in which the nef coding and U3 regulatory regions of SIVmac239 were replaced by the corresponding regions from HIV-1/R73 (SIVR7nef+). SIVR7nef+ displays enhanced infectivity and accelerated replication kinetics in primary human and rhesus PBMC infections compared to its nef-defective counterpart. Converse chimeras, containing SIV Nef in an HIV-1 background (R7SIVnef+) also exhibit greater infectivity than matched nef-defective viruses (R7SIV delta nef). These data indicate that SIV Nef, like that of HIV-1, does enhance virus replication in primary cells in tissue culture and that HIV-1 and SIV Nef are functionally interchangeable in the context of both HIV-1 and SIV.     

The human immunodeficiency virus type 1 nef gene can to a large extent replace simian immunodeficiency virus nef in vivo.

The nef gene of the pathogenic simian immunodeficiency virus (SIV) 239 clone was replaced with primary human immunodeficiency virus type 1 (HIV-1) nef alleles to investigate whether HIV-1 Nef can substitute for SIV Nef in vivo. Initially, two rhesus macaques were infected with the chimeric viruses (Nef-SHIVs). Most of the nef alleles obtained from both animals predicted intact open reading frames. Furthermore, forms containing upstream nucleotide substitutions that enhanced expression of the inserted gene became predominant. One animal maintained high viral loads and slowly progressed to immunodeficiency. nef long terminal repeat sequences amplified from this animal were used to generate a second generation of Nef-SHIVs. Two macaques, which were subsequently infected with a mixture of cloned chimeric viruses, showed high viral loads and progressed to fatal immunodeficiency. Five macaques received a single molecular clone, named SHIV-40K6. The SHIV-40K6 nef allele was active in CD4 and class I major histocompatibility complex downregulation and enhanced viral infectivity and replication. Notably, all of the macaques inoculated with SHIV-40K6 showed high levels of viral replication early in infection. During later stages, however, the course of infection was variable. Three animals maintained high viral loads and developed immunodeficiency. Of the remaining two macaques, which showed decreasing viral loads after the acute phase of infection, only one efficiently controlled viral replication and remained asymptomatic during 1.5 years of follow-up. The other animal showed an increasing viral load and developed signs of progressive infection during later stages. Our data demonstrate that HIV-1 nef can, to a large extent, functionally replace SIVmac nef in vivo.     

Simian immunodeficiency virus in which nef and U3 sequences do not overlap replicates efficiently in vitro and in vivo in rhesus macaques

The nef genes of human immunodeficiency virus and simian immunodeficiency virus (SIV) overlap about 80% of the U3 region of the 3' long terminal repeat (LTR) and contain several essential cis-acting elements (here referred to as the TPI region): a T-rich region, the polypurine tract, and attachment (att) sequences required for integration. We inactivated the TPI region in the nef reading frame of the pathogenic SIVmac239 clone (239wt) by 13 silent point mutations. To restore viral infectivity, intact cis-regulatory elements were inserted just downstream of the mutated nef gene. The resulting SIV genome contains U3 regions that are 384 bp shorter than the 517-bp 239wt U3 region. Overall, elimination of the duplicated Nef coding sequences truncates the proviral genome by 350 bp. Nonetheless, it contains all known coding sequences and cis-acting elements. The TPI mutant virus expressed functional Nef and replicated like 239wt in all cell culture assays and in vivo in rhesus macaques. Notably, these SIVmac constructs allow us to study Nef function in the context of replication-competent viruses without the restrictions of overlapping LTR sequences and important cis-acting elements. The genomes of all known primate lentiviruses contain a large overlap between nef and the U3 region. We demonstrate that this conserved genomic organization is not obligatory for efficient viral replication and pathogenicity.     

The nef gene of simian immunodeficiency virus SIVmac1A11.

The role of the simian immunodeficiency virus (SIV) nef gene in viral replication was investigated in several tissue culture systems. SIVmac1A11 is a molecularly cloned virus which replicates in both peripheral blood mononuclear cells (PBMC) and macrophages, although no disease is observed in infected rhesus macaques. In this report, we demonstrate that SIVmac1A11 contains a full open reading frame for nef which specifies a 37-kDa protein. To investigate the effects of nef on viral replication, a 70-bp deletion was introduced into the nef gene of SIVmac1A11. Analysis of infected cell extracts by immunoblotting revealed that both SIVmac1A11 and nef deletion virus SIVmac1A11 delta nef produced the same viral proteins, except that Nef was absent in the mutant virus. The deletion mutation did not affect viral replication in PBMC, in monocyte-derived and alveolar macrophages obtained from rhesus macaques, and in human cell lines HUT-78 and CEMx-174. In addition, SIVmac1A11 and SIVmac1A11 delta nef exhibited similar patterns of cytopathologic changes and ultrastructural appearances in infected cells. SIVmac1A11 and SIVmac1A11 delta nef did not infect human tumor macrophage cell line U937, GCT, THP-1, or HL-60 cells, although virus was produced after these cells were transfected with either wild-type or nef mutant viral DNA. Similar levels of virus were recovered from U937 and THP-1 cells transfected with mutant and parental proviral DNAs. In transient expression assays in a T-cell line and a macrophage line, the nef protein of SIVmac1A11 did not significantly suppress or enhance expression of the chloramphenicol acetyltransferase reporter gene linked to the SIVmac long terminal repeat. Thus, abrogation of nef did not affect several in vitro properties of SIVmac1A11, including patterns of viral infection in rhesus PBMC, rhesus macrophages, or human T-cell lines.     

Producer-cell modification of human immunodeficiency virus type 1: Nef is a virion protein.

Type 1 human immunodeficiency viruses encoding mutated nef reading frames are 10- to 30-fold less infectious than are isogenic viruses in which the nef gene is intact. This defect in infectivity causes nef-negative viruses to grow at an attenuated rate in vitro. To investigate the mechanism of Nef-mediated enhancement of viral growth rate and infectivity, a complementation analysis of nef mutant viruses was performed. To provide Nef in trans upon viral infection, a CEM derivative cell line (designated CLN) that expresses Nef under the control of the viral long terminal repeat was constructed. When nef-negative virus was grown in CLN cells, its growth rate was restored to wild-type levels. However, the output of nef-negative virus during the first 72 h after infection of CLN cells was not restored, suggesting that provision of Nef within the newly infected cell does not enhance the productivity of a nef-negative provirus. The genetically nef-negative virions produced by the CLN cells, however, were restored to wild-type levels of infectivity as measured in a syncytium formation assay in which CD4-expressing HeLa cells were targets. These trans-complemented, genetically nef-negative virions yielded wild-type levels of viral output following a single cycle of replication in primary CD4 T cells as well as in parental CEM cells. To define the determinants for producer cell modification of virions by Nef, the role of myristoylation was investigated. Virus that encodes a myristoylation-negative nef was as impaired in infectivity as was virus encoding a deleted nef gene. Because myristoylation is required for both membrane association of Nef and optimal viral infectivity, the possibility that Nef protein is included in the virion was investigated. Wild-type virions were purified by filtration and exclusion chromatography. A Western blot (immunoblot) of the eluate fractions revealed a correlation between peak Nef signal and peak levels of p24 antigen. Although virion-associated Nef was detected in part as the 27-kDa full-length protein, the majority of immunoreactive protein was detected as a 20-kDa isoform. nef-negative virus lacked both 27- and 20-kDa immunoreactive species. Production of wild-type virions in the presence of a specific inhibitor of the human immunodeficiency virus type 1 protease resulted in virions which contained only 27-kDa full-length Nef protein. These data indicate that Nef is a virion protein which is processed by the viral protease into a 20-kDa isoform within the virion particle.     

Mutational analysis of the simian immunodeficiency virus SIVmac nef gene.

We are using site-directed mutagenesis of single viral genes to identify and analyze the genetic determinants of human and simian immunodeficiency virus pathogenicity. In a first approach, we have constructed a series of simian immunodeficiency virus SIVmac nef mutants by partial deletion and insertions in the nef gene, as this gene is a candidate gene for the establishment and maintenance of latency. nef insertion mutants replicated faster than wild-type SIVmac, suggesting that the nef gene product acts as a negative factor for replication. Surface phenotyping revealed that cultures permanently infected with nef mutants exhibit an enhanced expression of viral proteins on the outer cell surface. We have analyzed the properties of the mutant viruses in cell culture and intend to use rapidly replicating mutants (putatively unable to undergo latency) as model vaccine viruses in the rhesus monkey.     

Construction and characterization of an infectious DNA clone and of mutants of simian immunodeficiency virus isolated from the African green monkey.

We constructed a full-length molecular clone of simian immunodeficiency virus from an African green monkey. Upon transfection, this clone directed the production of virus particles cytopathic and infectious to human CD4+ leukemia cell lines. Mutations were introduced by recombinant DNA techniques into eight open reading frames of simian immunodeficiency virus from the African green monkey thus far identified. The phenotypes of mutant viruses, i.e., infectivity, cytopathogenicity, transactivation of gene expression controlled by a long terminal repeat, and viral RNA and protein syntheses, were examined by transfection and infection experiments. Three structural (gag, pol, and env) and two regulatory (tat and rev) gene mutants were not infectious, whereas vif, vpx, and nef were dispensable for infectivity and mutant viruses were highly cytopathic. In transient transfection assays, a rev mutant produced mainly small mRNA species and no detectable virus protein and particles. The transactivation potential of a tat mutant was about 10-fold less than that of wild-type DNA, generating small amounts of virus.     

TAR-independent replication of human immunodeficiency virus type 1 in glial cells.

The molecular mechanisms involved in the replication of human immunodeficiency virus type 1 (HIV-1) may differ in various cell types and with various exogenous stimuli. Astrocytic glial cells, which can support HIV-1 replication in cell cultures and may be infected in vivo, are demonstrated to provide a cellular milieu in which TAR mutant HIV-1 viruses may replicate. Using transfections of various TAR mutant HIV-1 proviral constructs, we demonstrate TAR-independent replication in unstimulated astrocytic cells. We further demonstrate, using viral constructs with mutations in the tat gene and in the nuclear factor kappa B (NF-kappa B)-binding sites (enhancer) of the HIV-1 long terminal repeat, that TAR-independent HIV-1 replication in astrocytic cells requires both intact NF-kappa B moiety-binding motifs in the HIV-1 long terminal repeat and Tat expression. We measured HIV-1 p24 antigen production, syncytium formation, and levels and patterns of viral RNA expression by Northern (RNA) blotting to characterize TAR-independent HIV-1 expression in astrocytic glial cells. This alternative regulatory pathway of TAR-independent, Tat-responsive viral production may be important in certain cell types for therapies which seek to perturb Tat-TAR binding as a strategy to interrupt the viral lytic cycle.     

Characterization of three nef-defective human immunodeficiency virus type 1 strains associated with long-term nonprogression. Australian Long-Term Nonprogressor Study Group

Long-term survivors (LTS) of human immunodeficiency virus type 1 (HIV-1) infection provide an opportunity to investigate both viral and host factors that influence the rate of disease progression. We have identified three HIV-1-infected individuals in Australia who have been infected for over 11 years with viruses that contain deletions in the nef and nef-long terminal repeat (nef/LTR) overlap regions. These viruses differ from each other and from other nef-defective strains of HIV-1 previously identified in Australia. One individual, LTS 3, is infected with a virus containing a nef gene with a deletion of 29 bp from the nef/LTR overlap region, resulting in a truncated Nef open reading frame. In addition to the Nef defect, only viruses containing truncated Vif open reading frames of 37 or 69 amino acids could be detected in peripheral blood mononuclear cells isolated from this patient. LTS 3 had a viral load of less than 20 copies of RNA/ml of plasma. The other two long-term survivors, LTS 9 and LTS 11, had loads of less than 200 copies of RNA/ml of plasma and are infected with viruses with larger deletions in both the nef alone and nef/LTR overlap regions. These viruses contain wild-type vif, vpu, and vpr accessory genes. All three strains of virus had envelope sequences characteristic of macrophagetropic viruses. These findings further indicate the reduced pathogenic potential of nef-defective viruses.     

Analysis of human immunodeficiency virus type 1 nef gene sequences present in vivo.

The nef genes of the human immunodeficiency viruses type 1 and 2 (HIV-1 and HIV-2) and the related simian immunodeficiency viruses (SIVs) encode a protein (Nef) whose role in virus replication and cytopathicity remains uncertain. As an attempt to elucidate the function of nef, we characterized the nucleotide and corresponding protein sequences of naturally occurring nef genes obtained from several HIV-1-infected individuals. A consensus Nef sequence was derived and used to identify several features that were highly conserved among the Nef sequences. These features included a nearly invariant myristylation signal, regions of sequence polymorphism and variable duplication, a region with an acidic charge, a (Pxx)4 repeat sequence, and a potential protein kinase C phosphorylation site. Clustering of premature stop codons at position 124 was noted in 6 of the 54 Nef sequences. Further analysis revealed four stretches of residues that were highly conserved not only among the patient-derived HIV-1 Nef sequences, but also among the Nef sequences of HIV-2 and the SIVs, suggesting that Nef proteins expressed by these retroviruses are functionally equivalent. The "Nef-defining" sequences were used to evaluate the sequence alignments of known proteins reported to share sequence similarity with Nef sequences and to conduct additional computer-based searches for similar protein sequences. A gene encoding the consensus Nef sequence was also generated. This gene encodes a full-length Nef protein that should be a valuable tool in further studies of Nef function.     

Generation of a chimeric human and simian immunodeficiency virus infectious to monkey peripheral blood mononuclear cells.

We constructed five chimeric clones between human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus (SIVMAC) and four SIVMAC mutants by recombinant DNA techniques. Three chimeric clones and all mutants with an alteration in either the vif, vpx, vpr, or nef gene were infectious to human CD4-positive cell lines. The susceptibility of macaque monkey peripheral blood mononuclear cells (PBMC) to infection by these mutants and chimeras was examined in vitro. Macaque PBMC supported the replication of wild-type and vpx, vpr, and nef mutant SIVMAC strains. A chimera carrying the long terminal repeats (LTRs), gag, pol, vif, and vpx of SIVMAC and tat, rev, vpu, and env of HIV-1 was also replication competent in PBMC. In contrast, HIV-1, the vif mutant of SIVMAC, a chimera containing rev and env of SIVMAC, and a chimera containing vpx, vpr, tat, rev, and env of SIVMAC did not grow in PBMC. Western immunoblotting analysis of the replicating chimera in PBMC confirmed the hybrid nature of the virus. These data strongly suggested that the sequence important for macaque cell tropism lies within the LTR, gag, pol, and/or vif sequences of the SIVMAC genome.     

Construction and characterization of replication-competent simian immunodeficiency virus vectors that express gamma interferon.

We report the construction and characterization of several replication-competent simian immunodeficiency virus (SIV) vectors with a deletion in the viral nef gene (SIV(delta nef)) that express gamma interferon (IFN-gamma). The expression of the cytokine gene was controlled either by the simian virus 40 early promoter or by the SIV 5' long terminal repeat regulatory sequences, utilizing the nef gene splice signals. To enhance the expression of IFN-gamma, the two in-frame nef start codons were mutated without altering the Env amino acid sequence (SIV(HyIFN)). Plasmids containing full-length proviral genomes were used to obtain high-titer stocks of each recombinant virus in cell cultures. Expression of IFN-gamma by SIV(HyIFN) reached levels as high as 10(6) U/ml after 11 days in culture. The IFN-gamma gene was unstable and sustained deletions after serial passage of SIV(delta nef) vectors in CEM-X-174 cells. The degree of instability appears to depend on size and orientation of the insert and the expression of IFN-gamma. Only one virus, SIV(HyIFN), expressed detectable levels of IFN-gamma up to the sixth passage. Prospects for the use of IFN-gamma and other lymphokines to enhance the safety and efficacy of live attenuated vaccines are discussed.     

The NF-kappa B binding sites in the human immunodeficiency virus type 1 long terminal repeat are not required for virus infectivity.

Mutations were introduced into the regulatory sequences in the long terminal repeat of an infectious molecular clone of the human immunodeficiency virus. Viruses in which the NF-kappa B binding sites were deleted or ones in which one or two Sp1 binding sites were mutated still replicated efficiently in human T lymphocytes. A deletion of the two NF-kappa B sites plus the three Sp1 sites or a mutation of the tat-responsive region rendered the virus replication incompetent. Thus, the NF-kappa B sequences are not required for human immunodeficiency virus infectivity; however, a tat-responsive region is essential.     

Evolution of human immunodeficiency virus type 1 nef and long terminal repeat sequences over 4 years in vivo and in vitro.

The evolution of an 851-bp segment of the human immunodeficiency virus type 1 (HIV-1) genome encoding the nef open reading frame and U3/R elements of the long terminal repeat has been followed over a 4-year period in vivo and in vitro. The population of viral sequences at any given time was established by sequencing cloned polymerase chain reaction products. The samples studied were derived from the same man for whom a detailed analysis of the tat gene was previously described (A. Meyerhans, R. Cheynier, J. Albert, M. Seth, S. Kwok, J. Sninsky, L. Morfeldt-Manson, B. Asj?, and S. Wain-Hobson, Cell 58:901-910, 1989). Once again in vitro culture resulted in the selection of minor forms. Over a 4-year period in vivo, there was no obvious selection for, or outgrowth of, any particular nef or U3/R sequence. Few defective nef protein sequences were observed, which argues against nef acting as a negative regulatory factor. Although no functionally defective promoter/trans-activation-responsive elements were identified, the transactivation efficiencies varied between 0.2 and 2 times that of the control. The sequence encoding the most efficient trans-activation-responsive region did not outgrow others. The extreme genetic heterogeneity of the different samples of the locus, either in vivo or in vitro, indicates that there is no such thing as a single, distinct HIV sequence. It is suggested that different HIV-1 loci evolve independently, recombination being responsible for their uncoupling.