Importance of the nef gene for maintenance of high virus loads and for development of AIDS

Determination of B-cell epitopes of nef HIV-I protein: immunogenicity related to their structure

Determination of the B-cell epitopes of the nef molecule encoded by the human immunodeficiency virus type 1 (HIV-1) was undertaken using a set of six synthetic peptides. Sequences that were both antigenic and immunogenic and stimulated the production of antibodies recognizing the full length molecule, were considered as B-cell epitopes. Two peptidic sequences were antigenic both in rodents (mice and rats) and in non-human primates (chimpanzee). They were located in the regions 45-69 and 176-206 of the nef molecule. Two additional antigenic sequences were determined, one in chimpanzees, region 79-94, and the second in rodents, region 148-161. Immunogenicity was investigated in the rodents. Only the 45-69 and 176-206 sequences were immunogenic, and specific antibodies present in the sera of the immunized animals reacted with the nef protein. Therefore, each of these two sequences could be considered as containing at least one B-cell epitope. The fine epitopic specificity was determined using subfragments of these two sequences and it was shown that the antigenic determinants were contained in the C-terminal region of each sequence overlapping with the T-cell epitopes. These results raised the importance of vicinity of B- and T-cell determinants and their immunogenicity.

Complete nucleotide sequence, genome organization, and biological properties of human immunodeficiency virus type 1 in vivo: evidence for limited defectiveness and complementation

Previous studies of the genetic and biologic characteristics of human immunodeficiency virus type 1 (HIV-1) have by necessity used tissue culture-derived virus. We recently reported the molecular cloning of four full-length HIV-1 genomes directly from uncultured human brain tissue (Y. Li, J. C. Kappes, J. A. Conway, R. W. Price, G. M. Shaw, and B. H. Hahn, J. Virol. 65:3973-3985, 1991). In this report, we describe the biologic properties of these four clones and the complete nucleotide sequences and genome organization of two of them. Clones HIV-1YU-2 and HIV-1YU-10 were 9,174 and 9,176 nucleotides in length, differed by 0.26% in nucleotide sequence, and except for a frameshift mutation in the pol gene in HIV-1YU-10, contained open reading frames corresponding to 5'-gag-pol-vif-vpr-tat-rev-vpu-env-nef-3' flanked by long terminal repeats. HIV-1YU-2 was fully replication competent, while HIV-1YU-10 and two other clones, HIV-1YU-21 and HIV-1YU-32, were defective. All three defective clones, however, when transfected into Cos-1 cells in any pairwise combination, yielded virions that were replication competent and transmissible by cell-free passage. The cellular host range of HIV-1YU-2 was strictly limited to primary T lymphocytes and monocyte-macrophages, a property conferred by its external envelope glycoprotein. Phylogenetic analyses of HIV-1YU-2 gene sequences revealed this virus to be a member of the North American/European HIV-1 subgroup, with specific similarity to other monocyte-tropic viruses in its V3 envelope amino acid sequence. These results indicate that HIV-1 infection of brain is characterized by the persistence of mixtures of fully competent, minimally defective, and more substantially altered viral forms and that complementation among them is readily attainable. In addition, the limited degree of genotypic heterogeneity observed among HIV-1YU and other brain-derived viruses and their preferential tropism for monocyte-macrophages suggest that viral replication within the central nervous system may differ from that within the peripheral lymphoid compartment in significant and clinically important ways. The availability of genetically and biologically well characterized HIV-1 clones from uncultured human tissue should facilitate future studies of virus-cell interactions relevant to viral pathogenesis and drug and vaccine development.

The Zvonimir Dinter Memorial Lecture. New insights into the pathogenesis of viral infection

Interesting recent highlights into the pathogenesis of viral infections have come from: (1) Studies of viruses that persist in cells and modify cell function without causing cell damage. (2) Transgenic mouse studies showing how tissue-specific transcriptional activators control virus expression and can determine viral tropism. (3) Studies of the influence of cell differentiation on viral expression. (4) The exploding world of cytokines, whose baffling complexity and multiple interactions are subjects of intense study. (5) Studies of the interaction of viruses with the immune system. In each case, no molecular studies are giving unprecedented insights into disease processes. However, even when viral genomes are sequenced and virulence genes identified there are additional daunting steps before we understand the role of a given gene product in pathogenesis.

Infection of accessory dendritic cells by human immunodeficiency virus type 1

Many details of the pathogenesis of the human immunodeficiency virus type 1 remain to be elucidated. Details of how the virus gains entry via the mucosal surface upon sexual contact or during breast feeding remain obscure. The means by which the infection travels throughout the body as well as the nature of the major reservoirs of virus infection remains, for the most part, unknown. Recent studies raise the possibility that cells of the Langerhans/dendritic lineage play a central role in human immunodeficiency virus (HIV-1) infection and pathogenesis. It has been known for several years that veiled dendritic cells in the circulation as well as skin Langerhans are infected in people with prolonged HIV-1 infections. More recently it has been found that a large burden of viral DNA sequences is found, not only in the circulating T-cell population, but also in a population that is defined as a non-T, non-B, non-monocyte/macrophage population rich in T-helper dendritic cells. Detailed analysis of infection of primary blood-derived T-helper dendritic cells by HIV-1 shows that such cells are the most susceptible cells in the blood to infection by this virus. The cells also produce much more virus per cell than do purified populations of other blood mononuclear cells. Moreover, primary blood-derived T-helper dendritic cells are not killed by infection by HIV-1. These cells are susceptible to lymphotropic, monocyte tropic, and primary isolates of HIV-1. The sensitivity of primary blood-derived T-helper dendritic cells to infection by HIV-1 has been shown to be attributable to rapid uptake of virus particles as well as rapid synthesis of viral DNA. Subsequent steps of virus replication also occur more rapidly and more efficiently in populations of primary blood-derived T-helper dendritic cells than they do in purified preparations of blood-derived T cells and monocyte/macrophages. Studies with primates using the simian immunodeficiency virus (SIV) show that dendritic cells at the surface of sexual mucosa are rapidly infected upon exposure to high concentrations of the virus. SIV is also produced in abundance in Langerhans cells located at the surface of the sexual mucosa in animals infected for prolonged periods of time.

How human immunodeficiency virus ravages the immune system

The immune system of individuals infected with human immunodeficiency virus is affected in two distinct ways: by loss of CD4+ cells and by loss of T-helper-cell function. Neither of these processes is yet fully understood. Research during 1991 that investigated the interaction between human immunodeficiency virus and the immune system has raised as many questions as it answered. Nevertheless, many of the issues raised are relevant to mechanisms responsible for the ravaging of the immune system by human immunodeficiency virus.

Identification of a feline immunodeficiency virus gene which is essential for cell-free virus infectivity

Feline immunodeficiency virus (FIV) contains at least three small open reading frames (ORFs) in the genome, in addition to the three structural genes. Two of these ORFs (putative vif and ORF-A) have unknown functions. Northern (RNA) blot analysis of mRNAs from an FIV-infected cell line showed that the putative-vif-specific mRNA was expressed as a 5.2-kb species. To examine the function of the putative vif gene, we constructed mutants carrying a deletion in either the vif-like gene or the rev gene from an infectious molecular clone of FIV. Although the vif mutant produced virion-associated reverse transcriptase at a normal level upon transfection, cell-free virus prepared from the transfected cells could not infect feline CD4+ cells. The infectivity of the vif mutant, however, was demonstrated in a coculture of the transfected cells and feline CD4+ cells. We conclude that FIV contains the vif gene, which is structurally and functionally similar to that of the primate lentiviruses.

Human immunodeficiency virus type 1 Nef protein inhibits NF-kappa B induction in human T cells

Human immunodeficiency virus type 1 (HIV-1) can establish a persistent and latent infection in CD4+ T lymphocytes (W. C. Greene, N. Engl. J. Med. 324:308-317, 1991; S. M. Schnittman, M. C. Psallidopoulos, H. C. Lane, L. Thompson, M. Baseler, F. Massari, C. H. Fox, N. P. Salzman, and A. S. Fauci, Science 245:305-308, 1989). Production of HIV-1 from latently infected cells requires host cell activation by T-cell mitogens (T. Folks, D. M. Powell, M. M. Lightfoote, S. Benn, M. A. Martin, and A. S. Fauci, Science 231:600-602, 1986; D. Zagury, J. Bernard, R. Leonard, R. Cheynier, M. Feldman, P. S. Sarin, and R. C. Gallo, Science 231:850-853, 1986). This activation is mediated by the host transcription factor NF-kappa B [G. Nabel and D. Baltimore, Nature (London) 326:711-717, 1987]. We report here that the HIV-1-encoded Nef protein inhibits the induction of NF-kappa B DNA-binding activity by T-cell mitogens. However, Nef does not affect the DNA-binding activity of other transcription factors implicated in HIV-1 regulation, including SP-1, USF, URS, and NF-AT. Additionally, Nef inhibits the induction of HIV-1- and interleukin 2-directed gene expression, and the effect on HIV-1 transcription depends on an intact NF-kappa B-binding site. These results indicate that defective recruitment of NF-kappa B may underlie Nef's negative transcriptional effects on the HIV-1 and interleukin 2 promoters. Further evidence suggests that Nef inhibits NF-kappa B induction by interfering with a signal derived from the T-cell receptor complex.

Human immunodeficiency virus type 1 nef quasispecies in pathological tissue

The role of the nef gene in human immunodeficiency virus type 1 (HIV-1) infection is poorly understood. To provide a basis for studies on the role of nef in AIDS, we used targeted polymerase chain reaction amplification and DNA sequencing to determine the structure of nef genes in pathologic tissue from HIV-1-infected children and adults. We find that the nef reading frame is open in 92% of clones derived from both brain and lymphocytic tissue of children, suggesting that nef is expressed in these tissues. One HIV-1 clone, BRVA, obtained by coculture from the brain of an adult AIDS patient with progressive dementia, was previously shown to contain a duplicated region in nef. We show here that similar duplications are widespread in both adults and children with AIDS. However, coculture strongly selects against the broad spectrum of nef quasispecies found in tissue. These findings suggest functional selection for nef quasispecies in pathologic tissues during HIV-1 infection of the human host.

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.

Mechanism of action of regulatory proteins encoded by complex retroviruses

Complex retroviruses are distinguished by their ability to control the expression of their gene products through the action of virally encoded regulatory proteins. These viral gene products modulate both the quantity and the quality of viral gene expression through regulation at both the transcriptional and posttranscriptional levels. The most intensely studied retroviral regulatory proteins, termed Tat and Rev, are encoded by the prototypic complex retrovirus human immunodeficiency virus type 1. However, considerable information also exists on regulatory proteins encoded by human T-cell leukemia virus type I, as well as several other human and animal complex retroviruses. In general, these data demonstrate that retrovirally encoded transcriptional trans-activators can exert a similar effect by several very different mechanisms. In contrast, posttranscriptional regulation of retroviral gene expression appears to occur via a single pathway that is probably dependent on the recruitment of a highly conserved cellular cofactor. These two shared regulatory pathways are proposed to be critical to the ability of complex retroviruses to establish chronic infections in the face of an ongoing host immune response.

Derivation of a biologically contained replication system for human immunodeficiency virus type 1

Human immunodeficiency virus type 1 (HIV-1) proviral mutants that lack viral regulatory genes are unable to replicate unless rescued by complementation in trans. Structurally intact virus can be produced by infecting recombinant cell lines expressing the deficient genes. A HIV-1 mutant functionally defective in tat and rev (vIIIB delta Tat/Rev), which replicates only in a recombinant T-cell line expressing tat and rev (CEMTART), is described in this report. Infection of the CEMTART cell line with vIIIB delta Tat/Rev permits the complete HIV-1 life cycle, including cytopathology, decreased expression of CD4, and production of viral structural proteins, to be biologically contained. Culture supernatants from infected CEMTART contain virus that is able to replicate only in uninfected CEMTART. No reversion of vIIIB delta Tat/Rev to wild-type HIV-1 was observed as measured either by sequencing proviral vIIIB delta Tat/Rev or by detecting the ability of vIIIB delta Tat/Rev to replicate in CEM or activated CD4-bearing T lymphocytes. Defective HIV-1 mutants produced by trans complementation of essential genes permit infection and analysis of defined genotypes on cellular function and phenotype. Authentic HIV-1 structural proteins and infected cells can be prepared in mass, and agents that interfere with the HIV-1 life cycle can be studied on a large scale with minimum risk of exposing workers to virulent HIV-1.

Mutational analysis of the human immunodeficiency virus type 1 Eli Nef function

The studies presented here define an internally consistent experimental system that permits systematic analysis of the effect of nef on the rate of the human immunodeficiency virus type 1 (HIV-1) replication in a CD4+ tumor T-cell line and in primary peripheral blood mononuclear cells. The parental full-length Nef protein, derived from the Eli strain of HIV-1, accelerates virus replication in both cell types. Mutations that destabilize or alter the intracellular location of the protein affect the ability of the Nef protein to accelerate virus replication. A set of mutants was made in amino acids proposed to be required for Nef function, including threonine and serine residues proposed to be targets for phosphorylation, and in sequences thought to resemble the G-1, G-3, and G-4 sites of the family of G proteins. In most cases alterations of the critical amino acids yield stable Nef proteins of parental phenotype. These results challenge the existing theories for the mechanism of Nef function. The results also identify two residues in the carboxyl half of the protein that are important for Nef function.

Loss of V protein expression in human parainfluenza virus type 1 is not a recent event

The P gene of paramyxoviruses usually contains an alternate overlapping ORF coding for a short cysteine-rich domain called V. This domain was thought to be a common feature of these genes as it is present in ten paramyxoviruses. However, the V ORF region of the P gene of one strain of human parainfluenza-virus type 1 (isolated in 1957) was recently found to be closed by no less than 9 stop codons. To determine whether the absence of the V ORF here might be due to the long adaptation of this strain in culture, 3 other more recent isolates were examined. Small differences in the V region were found, but all had conserved the vast majority of the stop codons. Moreover, examination of most of the intercistronic regions of the PIV1 genome failed to uncover a cryptic V gene. The V ORF is then unlikely to be a common feature of paramyxovirus P genes.

Persistent infection of rabbits with bovine immunodeficiency-like virus

Chronic infection of rabbits was induced by a single intraperitoneal injection of bovine immunodeficiency-like virus (BIV)-infected cells. Ten BIV-infected animals were monitored serologically for up to 2 years. Results of serologic and virus rescue assays indicated that all animals became infected and demonstrated a rapid and sustained BIV-specific humoral response. BIV was rescued by cocultivation from spleen, lymph nodes, and peripheral blood leukocytes of infected animals. Viral DNA in immune tissues was confirmed by polymerase chain reaction amplification of BIV sequences. These data and specific immunohistochemical staining of mononuclear cells of the spleen for BIV antigen suggest that the infection is targeted to immune system cells.

Molecular clones from a non-acutely pathogenic derivative of SIVsmmPBj14: characterization and comparison to acutely pathogenic clones

Molecularly cloned simian immunodeficiency viruses capable of inducing acute, fatal disease in pig-tailed macaques had been derived previously from a biological clone (bcl-3) of the PBj14 isolate of SIV from sooty mangabey monkeys (SIVsmmPBj14). The present study was undertaken in order to characterize virus from a second biological clone of SIVsmmPBj14, bcl-1, which fails to induce acute or fatal disease. Polymerase chain reaction was used to amplify 5' and 3' viral genome halves. The DNA sequence of two 3' halves was determined, and an infectious recombinant generated using a bcl-3-derived 5' half and a bcl-1-derived 3' half. Overall, bcl-1- and bcl-3-derived viruses displayed close homology, differing by a total of 2% at the DNA level and 1-6% at the amino acid level within the 8 open reading frames examined. In contrast to the bcl-3-derived viruses, the bcl-1-derived viruses encode a truncated transmembrane envelope glycoprotein. Another consistent difference was the presence of a 22 bp duplication in the U3 portion of the long terminal repeat (LTR) of bcl-3-derived viruses that includes the NF-kappa B transcriptional enhancer binding site. To assess the importance of this duplication, virus chimeras were generated which removed the duplication from the 3'-LTR or from both LTRs of a bcl-3 clone. The former virus was unstable, reacquiring the duplication through recombination with the 5' LTR. No consistent difference were observed, however, between viruses with or without the duplication in the in vitro studies conducted to date.(ABSTRACT TRUNCATED AT 250 WORDS)

Activation pathways and human immunodeficiency virus type 1 replication are not altered in CD4+ T cells expressing the nef protein

While recent studies in Rhesus monkeys have pointed out the importance of an intact nef gene for the development of acquired immunodeficiency syndrome (AIDS), no biological function has been so far unambiguously attributed to its product. Since Nef has been described to possess GTP-binding properties and to down-regulate CD4 cell surface expression, we looked for evidences of Nef interfering with the transduction of activating signals in human CD4+ T cells. We used a murine leukemia retroviral vector to express the HIV-1BRU nef gene in two permanent tumoral T-cell lines (CEM and Jurkat) and in two nonimmortalized, interleukin-2 (IL2)-dependent, T-cell clones. The single copy recombinant provirus integrated in the genome of these cells directed the synthesis of a 27-kD protein with a half-life greater than 5 h. The levels of expression of cell surface molecules involved in T-cell functions (CD4, CD3, CD28, CD29, IL-2 receptor) were not modified in cell populations expressing Nef. In immunocompetent T-cell clones, cell proliferation and lymphokine production in response to activating stimuli (IL-2, alloantigens, phorbol esters, or antibodies directed against CD2, CD3, CD4, CD28) remained unmodified. Moreover, the presence of Nef did not change the kinetics of human immunodeficiency virus (HIV) infection.

In vivo derived HIV-1 nef gene products are heterogeneous and lack detectable nucleotide binding activity

Multiple HIV-1 nef genes were cloned from lymphocyte DNA of asymptomatic seropositive individuals by polymerase chain reaction (PCR). Sequence analysis of these clones revealed a unique set of nef variants with premature terminations (PCRnef 1 and 6), mutations at sites of potential posttranslational modification (PCRnef 2 and 3) and deletions. In common with laboratory isolates of nef, strong sequence conservation was observed in the central domain of nef and in the myristylation target sequence, with variable domains toward the N- and C-termini of the molecule. The biochemical function of nef remains elusive however, as the products of these genes cloned into a bacterial expression system failed to reveal any nucleotide binding activity.

Expression, purification and biochemical characterisation of the human immunodeficiency virus 1 nef gene product

The human immunodeficiency virus 1 (HIV-1) nef gene encoded by the HIV-1 isolate lymphadenopathy-associated virus type 1 was expressed in Escherichia coli under the control of the tac promoter. The protein is found mainly in the soluble part of the bacterial lysate; a simple two-column purification scheme has been developed allowing isolation of the recombinant protein without using denaturing agents. Analysis of the circular dichroism spectra reveals that the purified protein is folded and has a helix content of 16% and a beta-pleated sheet content of 31%. GTPase activity and binding of guanine nucleotides were measured for Nef and compared with the results obtained under identical experimental conditions for p21rasC, which represents a typical, well-characterized guanine-nucleotide-binding (GNB) protein. Within the limits of error, native Nef does not show GTPase activity and does not bind guanine nucleotides strongly (association constant, Kass less than 5 x 10(3) M-1). An upper limit for the association constant of Nef for ATP was determined by equilibrium dialysis as 5 x 10(3) M-1. Nef can be autophosphorylated by ATP; under the experimental conditions used, 1-2% of the protein become phosphorylated. Correspondingly, our Nef preparation shows a low, but significant, ATPase activity. In conclusion, Nef is not a member of the GNB protein family, but a possible role as a protein kinase cannot be excluded.

Natural HIV-1 NEF accelerates virus replication in primary human lymphocytes

HIV-1 NEF genes were isolated directly from peripheral blood lymphocyte DNA of two HIV-1-infected individuals and cloned into an HXB-2-infectious molecular clone. The effect of NEF on virus production in T-cell lines and primary human lymphocytes was studied. Naturally occurring NEF accelerates virus production in primary human lymphocytes, but not in T-cell lines.

Complex determinants of macrophage tropism in env of simian immunodeficiency virus

Macrophage-tropic virus variants evolved during the course of infection of individual rhesus monkeys with cloned, non-macrophagetropic simian immunodeficiency virus. Specific changes in the envelope gene (env) were found to be primarily responsible for the dramatic increase in the ability of the virus to replicate in macrophages. Cloned viruses differing at nine amino acid positions in env exhibited a more than 100-fold difference in replicative capacity for primary cultures of rhesus monkey alveolar macrophages. At least five of the nine amino acid changes contributed to macrophage tropism. These determinants were distributed across the full length of env, including both the gp120 and gp41 products of the env gene. Furthermore, the emergence of macrophagetropic variants in vivo was associated with specific pathologic manifestations in which the macrophage is the major infected cell type. Thus, major determinants of macrophage tropism reside in env, they can be complex in nature, and the presence of macrophage-tropic virus variants in vivo can influence the disease course and disease manifestations.

Genetic characterization of simian immunodeficiency virus isolated from an African mandrill

We constructed an infectious molecular clone of simian immunodeficiency virus from an African mandrill (SIVMND). Upon transfection, this clone directed the production of progeny virus particles infectious to and cytopathic for CD4+ human leukemia cells. Thirteen frameshift proviral mutants with an alteration in the eight open reading frames of SIVMND were generated by recombinant DNA techniques, and were analyzed biologically and biochemically. While mutations in the structural genes gag, pol, and env abolished viral growth and induction of cytopathology, mutants of the vif, vpr, and nef genes were fully biologically active. Of the tat and rev mutants, only one rev mutant grew in CD4+ cells with delayed kinetics. In reporter-based transient expression systems, transactivation potentials of the tat and rev mutants were evaluated. A mutant lacking 2nd coding exon of tat gene exhibited tat activity similar to that of the wild type clone. The infectious rev mutant was partially defective for rev gene activity.

Genetic and biological comparisons of pathogenic and nonpathogenic molecular clones of simian immunodeficiency virus (SIVmac)

Simian immunodeficiency virus (SIV) is a designation for a group of related but unique lentiviruses identified in several primate species. A viral isolate from a rhesus macaque (i.e., SIVmac) causes a fatal AIDS-like disease in experimentally infected macaques, and several infectious molecular clones of this virus have been characterized. This report presents the complete nucleotide sequence of molecularly cloned SIVmac1A11, and comparisons are made with the sequence of molecularly cloned SIVmac239. SIVmac1A11 has delayed replication kinetics in lymphoid cells but replicates as well as uncloned SIVmac in macrophage cultures. Macaques infected with virus from the SIVmac1A11 clone develop antiviral antibodies, but virus does not persist in peripheral blood mononuclear cells and no disease signs are observed. SIVmac239 infects lymphoid cells, shows restricted replication in cultured macrophages, and establishes a persistent infection in animals that leads to a fatal AIDS-like disease. Both viruses are about 98% homologous at the nucleotide sequence level. In SIVmac1A11, the vpr gene as well as the transmembrane domain of env are prematurely truncated, whereas the nef gene of SIVmac239 is prematurely truncated. Sequence differences are also noted in variable region 1 (V1) in the surface domain of the env gene. The potential implications of these and other sequence differences are discussed with respect to the phenotypes of both viruses. This animal model is critically important for investigating the roles of specific viral genes in viral/host interactions that cannot be studied in individuals infected with the human immunodeficiency virus (HIV).

HIV with multiple gene deletions as a live attenuated vaccine for AIDS

Most viral vaccines currently in use in humans are live attenuated strains of virus that lack pathogenic potential. In general, such live attenuated vaccines induce the strongest longest-lasting immunity. Live attenuated strains of human immunodeficiency virus type 1 (HIV-1) have not been previously considered as vaccines for acquired immunodeficiency syndrome (AIDS) because of an inability to envision how their safety could be adequately assured. This report describes a means for making live, nonpathogenic strains of SIVmac and HIV-1 that cannot revert to a virulent form and a stepwise scheme for demonstrating their safety. Replication-competent, multiply deleted derivatives that are currently being tested are missing combinations of auxiliary genes (nef, vpr, vif, vpx, vpu) and certain control elements in the negative regulatory element (NRE) of the long terminal repeat (LTR). Since these genomic regions are in large part conserved among the SIVs and HIVs, they are likely to be important for the virus life cycle in vivo. Consistent with this line of reasoning, a replication-competent nef deletion mutant of SIVmac apparently has lost most or all of its pathogenic potential, yet it still induces strong immune responses. Multiply deleted derivatives of SIVmac and HIV-1 will have to be extensively tested in animal models prior to moving a promising HIV-1 candidate to initial trials in high-risk human volunteers. Definitive evidence for safety and general acceptance for this approach can only evolve gradually over a prolonged period of time.

Expression of nef, vpu, CA and CD4 during the infection of lymphoid and monocytic cell lines with HIV-1

The expression of the capsid antigen (CA) and the two regulatory proteins nef and vpu as well as the CD4 cell surface receptor was followed in HIV-infected lymphoid and promonocytic cells. In the lytic phase of infection all three viral proteins were expressed; production of these proteins coincided with the increase of CA antigen and infectious virus in culture supernatants and with prominent cytopathic effects. After selection of persistently infected cells, the number of lymphoid cells expressing detectable levels of nef decreased to zero; the number of cells positive for CA ranged between 40 to 70%. In chronically infected promonocytic cells nef and vpu expression was reduced to undetectable levels, whereas most of the cells accumulated CA intracellularly. Infectious cell free virus and CA in the supernatant of promonocytic cells had low titers. CD4 surface expression declined in all cell lines investigated before cell free virus was detectable.

SIV/HIV recombinants and their use in studying biological properties

A series of chimeric clones between human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency viruses (SIV) were constructed. Viability of the recombinant viruses was dependent on the position of recombination. Infectious chimeric viruses between HIV-1 and SIVAGM (isolated from an African green monkey) and those between HIV-1 and SIVMAC (isolated from a rhesus monkey) were examined for host cell tropism. Viral determinants that restrict the replication of SIVAGM in human MT-4 cells and that of HIV-1 in macaque monkey peripheral blood mononuclear cells (PBMC) mapped to the 5' half of the virus genome. One HIV-1/SIVMAC chimera which contained the HIV-1 env gene was shown to replicate in macaque PBMC in vitro and to infect macaque monkeys in vivo. This HIV-1/SIVMAC chimera will be useful for a variety of AIDS pathogenesis and vaccine studies.

Distinct subsets of retroviruses encode dUTPase

The nonprimate lentiviruses feline immunodeficiency virus, equine infectious anemia virus, visna virus, and caprine encephalitis virus contain a gene segment in the polymerase gene that is lacking in the primate lentiviruses. A related sequence has been noted in other retroviruses, most notably the type D retroviruses. Computer searches have indicated a relatedness between this unique gene segment, termed proteaselike element and elements of both the aspartate proteinase and the dUTPase enzyme families. In this report, we show that members of both nonprimate lentiviruses and type D retroviruses possess dUTPase activity and present a formal demonstration that in feline immunodeficiency virus, the activity is encoded by the proteaselike element.

Macaque CD4+ T-cell subsets: influence of activation on infection by simian immunodeficiency viruses (SIV)

Simian immunodeficiency virus (SIV) infects a small number of CD4+ T cells including "memory" T cells. The following describes the cell surface markers which may delineate subsets of CD4+ memory T cells and reviews how memory CD4+ T cells are activated and regulated through the T-cell receptor and such accessory receptors as CD28. The factors which may influence initial expression and infection of T cells by CD4 are discussed. Unlike activated and infected T cells, unstimulated CD4+ T cells have little or no SIV DNA detectable in the genomic fraction, but key activation signals may promote integration of viral DNA in memory T cells. Bacterial superantigens (SuperAg) can promote increased levels of SIV viral DNA in mature and immature T cells. Immunodeficiency virus products such as gp120, Nef, and Tat can affect CD4+ T-cell function. Whereas Nef can reduce expression of CD4, Tat reduces the expression of CD28. We hypothesize that the lack of expression of key accessory molecules on CD4 lineage T cells infected with immunodeficiency viruses may make infected T cells more susceptible to recall-antigen-induced programmed cell death.

Expression of the HIV-1 Nef protein in the baculovirus system: investigation of anti-Nef antibodies response in human sera and subcellular localization of Nef

The nef gene of HIV-1 was expressed in insect cells using the eucaryotic baculovirus system. The recombinant Nef protein frequently reacted with seropositive sera of HIV-1 and HIV-2 infected patients. Anti-Nef antibodies in HIV-1 seronegative high risk groups individuals were only occasionally seen. Confocal laser scanning microscopy demonstrated that Nef is present both in the cytoplasm and in the nucleus, indicating that Nef might directly function on gene expression.

Functional characterization of a U5 ribozyme: intracellular suppression of human immunodeficiency virus type 1 expression

We have designed a ribozyme that cleaves human immunodeficiency virus type 1 (HIV-1) RNA in U5 (at nucleotide +115). This ribozyme was tested in vitro and was found to give efficient and specific digestion of RNA containing the HIV-1 U5 sequence. When the U5 ribozyme was placed into the HIV-1 genome, virus replication was suppressed in tissue culture. Introduction of this ribozyme into cells by using an amphotropic retrovirus vector significantly reduced expression of U5-containing RNA in cells chronically infected with HIV-1. Naive T cells were cocultivated with packaging cells that produce defective amphotropic retroviruses containing the U5 ribozyme. These lymphocytes were found to be partially protected from HIV-1 infection.

Carboxyl-terminal and central regions of human immunodeficiency virus-1 NEF recognized by cytotoxic T lymphocytes from lymphoid organs. An in vitro limiting dilution analysis

Cytotoxic T lymphocytes (CTL) specific for human immunodeficiency virus (HIV) proteins have been analyzed in lymphoid organs from seropositive patients. Indeed, an active HIV replication coexists with a major CD8+ lymphocytic infiltration in these organs. We have shown in a previous report that HIV-seropositive patients lungs were infiltrated by HIV specific CD8+ lymphocytes. In the present report, we show that HIV-specific CTL responses can also be detected in lymph nodes and spleens, and were mainly directed against the ENV, GAG, and NEF HIV-1 proteins. The primary NEF-specific CTL responses were further characterized by epitope mapping. Determination of epitope-specific CTL frequencies were performed by limiting dilution analysis. Our results indicated that, in addition to the central region of NEF (AA66-148), a new immunodominant region is recognized by CTL. This region corresponds to the carboxyl-terminal domain of NEF (amino acids 182-206). AA182-206 is recognized in association with at least two common human histocompatibility leukocyte antigen (HLA) molecules (HLA-A1 and B8), with clonal frequencies of one CTL per 10(-5) to 10(-6) splenic lymphocytes. Our data indicate that lymphoid organs may represent a major reservoir for in vivo activated HIV-specific CTL. Furthermore, the carboxyl-terminal domain of NEF was found to be conserved among several HIV strains. Therefore, our finding is of interest for further HIV vaccines development.

Genetic analysis and gene expression of human immunodeficiency virus

Ten years after the initial description of acquired immune deficiency syndrome, its causative agent, the human immunodeficiency virus, remains the subject of intense scientific interest. Recent research has focused on the detailed analysis of the molecular principles governing gene expression and virion formation and on the cause of immune system dysfunction. Within the past year, considerable progress has been made regarding both the role of the regulatory proteins and the mechanism by which they function, and the determinants of cell tropism and of virion formation.

Three epitopic peptides of the simian immunodeficiency virus Nef protein recognized by macaque cytolytic T lymphocytes

In 8 of 12 experimentally infected macaques, the Nef SIVmac 251 protein was recognized by cytolytic T lymphocytes (CTL) and appeared strongly immunogenic. Here, we report experiments which have been performed by using synthetic peptides to precisely determine the epitopes recognized by macaque CTL. Three epitopes of the Nef protein have been defined as CTL targets in three macaques. The epitopic peptides are located in the central region of the protein, and all of them show high homology with peptides of the human immunodeficiency virus type 1 Nef protein recognized by human CTL in association with several human leukocyte antigen molecules. These results suggest that (i) the Nef protein is a good candidate for vaccination not only because of its early expression but also because of its high immunogenicity for CTL, (ii) long peptides covering the central region of this protein could be used as vaccines and could cross the major histocompatibility complex barrier in a large variety of individuals, and (iii) the rhesus macaque is a good animal model in which to test for protection by CTL.

Hepatitis B virus X protein is not central to the viral life cycle in vitro

The hepatitis B x (HBx) gene is the smallest open reading frame of the hepatitis B virus (HBV) genome. It is conserved among all mammalian hepadnaviruses and is expressed during viral infection. While the HBx protein (pX) has been shown to trans-activate the transcription of a wide range of viral and cellular genes and to induce liver cancer in transgenic mice, the significance of pX for the life cycle of HBV itself has not been elucidated. To assess the function of pX in viral replication and virion export, we designed an X-minus mutant by introduction of a stop codon at the beginning of the HBx gene without affecting the viral polymerase gene product. Transient transfection analyses using different cell lines revealed that this X-minus mutant directs the synthesis of wild-type levels of viral proteins, replicative intermediates, and virion export. These data suggest that the expression of the highly conserved HBx gene is not central for the life cycle of HBV in vitro but may be involved in the pathogenicity of hepadnavirus infection, including liver cancer development.

Human immunodeficiency virus type 1 envelope gene structure and diversity in vivo and after cocultivation in vitro

Nested-primer polymerase chain reaction (PCR) has been applied to the molecular cloning of 4.6-kb half-genome fragments of human immunodeficiency virus type 1 (HIV-1) taken directly from the peripheral blood mononuclear cells (PBMC) of an individual with neurological symptoms of HIV-1 infection. In a similar manner, gp120-coding portions of the envelope gene were cloned after PBMC from the same blood sample were cocultivated with uninfected PBMC for 28 days. The complete 1.6-kb nucleotide sequence of the gp120 gene was determined from each of 35 clones examined. Two of 13 (15%) PBMC-derived gp120 genes and 3 of 22 (14%) coculture-derived gp120 genes were defective as a result of frameshifts and an in-frame stop codon(s). Mean diversity between individual gp120-coding sequences in PBMC was fivefold greater (3.24%) than after coculture (0.65%). A predominant sequence of "strain" was found after coculture that was distinct from the diverse viral genotypes detected in vivo and therefore was selectively amplified during in vitro propagation. Multiple distinct third variable (V3) regions encoding the principal neutralizing domain of the envelope protein were detected in PBMC-derived genes, suggesting the presence of immunologic diversity of HIV env genes in vivo not reflected in the cocultured virus sample. The large size of the HIV fragments generated in this study will permit analysis of the diversity of immunologic reactivity, gene function, and pathogenicity of HIV genomes present within infected individuals, including the functional significance of the loss of diversity that occurs upon coculture.

HIV-1 replication and potential targets for intervention

Intense research into fundamental processes of human immunodeficiency syndrome type 1 (HIV-1) replication has yielded knowledge that in many aspects equals or exceeds that of the oncogenic retroviruses. The availability of sensitive virus detection methods has allowed a more thorough characterization of the biology of virus persistence and latency in vivo and removed the dependence on in vitro models. As a clearer picture of the pattern of HIV-1 replication in vivo evolves, it becomes apparent that HIV-1 biology is distinct from that of the prototypic oncogenic retroviruses in several key aspects, particularly with regard to host cell range and determinants of viral permissiveness. In this respect it may be appropriate to examine the lentivirus, rather than the oncovirus model system to better understand the biology and pathogenesis of HIV-1 infection. This synopsis of recent and ongoing research developments in HIV-1 replication and pathogenesis emphasizes the determinants of host cell permissiveness, early events in virus replication, and underlying features in HIV-1 cytopathogenesis. In addition, basic viral replication processes which can be exploited for therapeutic intervention are discussed.

SIV infection of macaques as a model for AIDS pathogenesis

Simian immunodeficiency virus (SIV) infection of macaques is the best available animal model for studying the pathogenesis of AIDS. Experimental inoculation of macaques with SIV results in a persistent infection that leads to immunodeficiency, opportunistic infections, and death. Most aspects of the illness, including immunologic and virologic parameters, are easily quantified. Furthermore, pathologic processes can be evaluated throughout the course of experimental infection. Recently, molecular clones of SIV proviral DNA have been used to study genetic variation and specific viral determinants of pathogenesis. Considered together, these observations support the continued detailed study of SIV infection of macaques as a model for human AIDS.

AIDS acquired by drug consumption and other noncontagious risk factors

The hypothesis that human immunodeficiency virus (HIV) is a new, sexually transmitted virus that causes AIDS has been entirely unproductive in terms of public health benefits. Moreover, it fails to predict the epidemiology of AIDS, the annual AIDS risk and the very heterogeneous AIDS diseases of infected persons. The correct hypothesis must explain why: (1) AIDS includes 25 previously known diseases and two clinically and epidemiologically very different epidemics, one in America and Europe, the other in Africa; (2) almost all American (90%) and European (86%) AIDS patients are males over the age of 20, while African AIDS affects both sexes equally; (3) the annual AIDS risks of infected babies, intravenous drug users, homosexuals who use aphrodisiacs, hemophiliacs and Africans vary over 100-fold; (4) many AIDS patients have diseases that do not depend on immunodeficiency, such as Kaposi's sarcoma, lymphoma, dementia and wasting; (5) the AIDS diseases of Americans (97%) and Europeans (87%) are predetermined by prior health risks, including long-term consumption of illicit recreational drugs, the antiviral drug AZT and congenital deficiencies like hemophilia, and those of Africans are Africa-specific. Both negative and positive evidence shows that AIDS is not infectious: (1) the virus hypothesis fails all conventional criteria of causation; (2) over 100-fold different AIDS risks in different risk groups show that HIV is not sufficient for AIDS; (3) AIDS is only 'acquired,' if at all, years after HIV is neutralized by antibodies; (4) AIDS is new but HIV is a long-established, perinatally transmitted retrovirus; (5) alternative explanations disprove all assumptions and anecdotal cases cited in support of the virus hypothesis; (6) all AIDS-defining diseases occur in matched risk groups, at the same rate, in the absence of HIV; (7) there is no common, active microbe in all AIDS patients; (8) AIDS manifests in unpredictable and unrelated diseases; and (9) it does not spread randomly between the sexes in America and Europe. Based on numerous data documenting that drugs are necessary for HIV-positives and sufficient for HIV-negatives to develop AIDS diseases, it is proposed that all American/European AIDS diseases, that exceed their normal background, result from recreational and anti-HIV drugs. African AIDS is proposed to result from protein malnutrition, poor sanitation and subsequent parasitic infections. This hypothesis resolves all paradoxes of the virus-AIDS hypothesis. It is epidemiologically and experimentally testable and provides a rational basis for AIDS control.

Molecular insights into human immunodeficiency virus type 1 pathogenesis

Infection with human immunodeficiency virus type 1 leads to a persistent but progressive cytopathic process that culminates in the near complete destruction of the CD4+ subset of T cells. The levels of human immunodeficiency virus type 1 replication and virus burden increase throughout the clinical course of disease reflecting a balance between the viral and cellular regulatory influences as well as the ability of the host immune system to eliminate infected T cells. Human immunodeficiency virus type 1 replication is dependent on the state of cellular activation and involves both inducible host cell derived transcription factors and at least three virus-derived gene products. Further study of the mechanism of action of these factors, particularly those encoded by the virus, may facilitate the future development of highly specific and effective therapies for human immunodeficiency virus type 1.