Antigenic epitopes of NEF proteins from different HIV-1 strains as recognized by sera from patients with manifest and latent HIV infection

Low or no antibody responses to human immunodeficiency virus type 1 Nef in infected carriers with subtype E, in contrast to subtype B that showed antibodies preferentially recognizing subtype-specific Nef epitopes

The viral accessory gene product Nef has been shown to play an important role in human immunodeficiency virus type 1 (HIV-1)-induced pathogenesis. Only little information is available regarding the differences in the host immune responses against Nef protein and its function in vivo among different subtypes of HIV-1. In the present study, we showed marked differences in the immune responses to Nef protein between subtypes B and E. The amino acid sequence in subtype E Nef showed 72% homology with that in subtype B. Most murine monoclonal antibodies obtained by immunization with subtype B or E Nef protein showed cross-reactivity with both Nef proteins (80 and 67%, respectively). Next, we focused on the immune responses among infected Japanese and Thai individuals. Subtyping of the individuals into B and E was carried out by enzyme-linked immunosorbent assay (ELISA) using synthetic peptides corresponding to the V3 loop representing the principal neutralizing domain. Most of the sera from these individuals reacted strongly with Gag p24 proteins derived from subtypes B and E at similar levels. However, the immune responses among these individuals to Nef protein were markedly different. Some subtype B-infected Japanese and Thai individuals (40 and 35%, respectively) showed higher levels of anti-Nef antibodies, although these antibodies preferentially recognized epitopes specific to subtype B. On the other hand, most of the subtype E-infected Japanese and Thai individuals showed low or no antibody responses to Nef proteins. Thus, immune responses to Nef were markedly different between subtypes B- and E-infected carriers, suggesting different function(s) for Nef in AIDS pathogenesis. Further, vaccine design must take into account the different subtypes of HIV-1.

Expression of a novel Nef epitope on the surface of HIV type 1-infected cells

We compared antibody responses to various structural and accessory gene products of HIV-1 between long-term nonprogressors and patients who have progressed to AIDS. On the basis of our results, we performed epitope mapping of the Nef protein and identified a novel epitope. This novel epitope of the Nef protein was found to be exposed on the surface of HIV-1-infected cells. The antibody response against it correlated with CD4+ cell counts among HIV-1-infected patients (r = 0.457, p < 0.001). Although further research is necessary, we suspect that antibody response against the epitope may be protective against disease progression.

B-cell epitopes in HIV-1 Tat and Rev proteins colocalize with T-cell epitopes and with functional domains

We describe the characterization of the B-cell epitopes of HIV-1 regulatory proteins Tat and Rev. The prevalence of antibodies to these proteins among human immunodeficiency virus (HIV)-1-infected individuals was examined by enzyme-linked immunosorbent assay (ELISA) and by Western blotting. The Tat and Rev antibody-positive sera were selected for epitope mapping performed with partially overlapping synthetic peptides bound to polyethylene pins. Eighteen and twelve percent of HIV-infected individuals had antibodies against Tat or Rev, respectively. In Tat, four epitopic regions were identified, situated within amino acids 6-10 (PRLEP), 21-37 (ACTNCYCKKCCFHCQVC), 39-58 (ITKALGISYGRKKRRQRRRA) and 74-82 (TSQSRGDPT). The most frequently recognized epitopic regions were located in the middle of the protein. In Rev, the two most frequently recognized epitopic regions were near the amino terminus of the protein within amino acids 12-20 (LIRTVRLIK) and 38-49 (RRNRRRRWRERQ). A third epitope was mapped around amino acids 55-62 (ISERILGT) and a fourth around amino acids 78-83 (LERLTU). To analyze the specificity of Tat and Rev epitopes, soluble synthetic peptides representing the identified epitopes were used in an ELISA assay, and the recognition of most epitopes was shown to be specific for HIV-1-infected individuals. In addition, many of the Tat and Rev epitopes were shown to overlap with regions having functional activity or with regions previously identified as T-cell epitopes.

Serological detection of attenuated HIV-1 variants with nef gene deletions

OBJECTIVE

To investigate whether members of a transfusion-linked cohort (the Sydney Bloodbank Cohort) infected with a nef-deleted strain of HIV-1 could be differentiated from individuals infected with wild-type strains of HIV-1 by characterizing the Nef antibody response of cohort members.

DESIGN

Retrospective and prospective analysis of the nef gene sequence and the antibody response to Nef peptides in HIV-infected subjects.

METHODS

Plasma was obtained from all individuals of the Sydney cohort, and from a variety of HIV-1-infected and uninfected controls. Antibodies recognizing full-length recombinant HIV-1NL43 Nef protein and synthetic peptide analogues were assessed by enzyme-linked immunosorbent assay.

RESULTS

All 34 individuals infected with wild-type HIV-1 had antibodies reacting with full-length Nef protein as well as with a series of synthetic peptides (6-23-mers) spanning most of the Nef protein of HIV-1NL43. Although the HIV-1 quasispecies infecting the Sydney cohort had a consensus deletion of the nef gene corresponding to amino-acids 165-206, HIV-1 strains from individual members of the cohort had additional deletions comprising up to 80% of the nef gene. Members of the cohort had antibodies to peptides homologous to all regions of the Nef protein tested, except for a single peptide (amino-acids 162-177) that lies within the consensus nef deletion for the cohort quasispecies.

CONCLUSION

These data show that nef-deleted strains of HIV-1 can be detected serologically. In the Sydney cohort, detection of antibodies to all regions of Nef tested, except that corresponding to amino-acids 162-177, suggests that observed deletions outside this domain occurred after this virus had infected these subjects and stimulated an immune response. A Nef peptide serological assay may be useful for identifying further examples of individuals infected with nef-deleted, attenuated HIV-1 quasispecies and for assessing the evolution of those variants in vivo.

Epitope mapping of murine monoclonal antibodies against human immunodeficiency virus type 1 Nef

It has shown that the human immunodeficiency virus type 1 (HIV-1) Nef protein has the high antigenicity in HIV-1 seropostive individuals. We newly obtained seven monoclonal antibodies (mAbs). To identify the antigenic determinants of HIV-1 Nef protein against murine, epitope mapping of the mAbs was performed by enzyme-linked immunosorbent assay (ELISA) by using several recombinant truncated Nef fusion proteins, that were expressed in Esherichia coli, and synthetic peptides. The results showed that mAbs A6, A7, F2, F3, F4, F8 and E5 recognized epitopes on Nef protein located at amino acid residues 18-26, 28-45, 115-137, 128-137, 115-126, 128-137, and 170-181, respectively.

Heparin-binding capacity of the HIV-1 NEF-protein allows one-step purification and biochemical characterization

Recombinant Nef-protein of HIV-1 Bru derived from Escherichia coli revealed heparin-binding activity. This property was used to purify the Nef-protein by a one-step procedure, yielding about 90% homogenous Nef-protein as evaluated by silver staining. The Nef-protein was soluble without denaturing agents. Native folding of Nef was demonstrated with antibodies against conformational epitopes of Nef by a slot blot assay under native conditions. Despite its affinity to heparin and its nuclear localization in persistently HIV-1 infected glioblastoma cells (Kohleisen et al., 1992), Nef did not show DNA-binding properties by slot blot/hybridization assay and South/Western blot. In nucleotide-binding assays a strong autophosphorylation activity with [gamma-32P]ATP was observed. Nef-protein was not a substrate for ADP-ribosylation by bacterial toxins arguing against G-protein-like activities of Nef. Recombinant Nef did not interact with membranes as shown by the lack of increased fluorescence emission of Nef in the presence of liposomes. The recombinant Nef-protein obtained by one-step heparin-based purification shares immunological properties with native Nef and should prove useful for further studies of Nef function and immunogenicity.

Characterization of human CD4+, HIV-SF2 Nef-specific T-cell clones for antigen-processing and presentation requirements and for cytotoxic activity

We have described previously the generation of seven HIV-SF2 Nef-specific, CD4+ T-cell clones, identification of epitopes within which are recognized by these clones, and the MHC alleles that restrict their responses. In this study, we have extended this characterization to include evaluation of antigen-processing and presentation requirements and cytotoxic activity. Clones were generated from five HIV-1 uninfected donors by in vitro stimulation of peripheral blood mononuclear cells with purified recombinant Nef1. In experiments with fixed cells, with the exception of two clones, recognition of Nef, but not Nef peptides, required processing. Also, at higher concentrations of antigen, the clones themselves were capable of presenting Nef peptides, but not soluble Nef. All clones had the ability to specifically lyse autologous, Epstein-Barr virus-transformed lines sensitized with Nef synthetic peptides, or, in some cases, soluble Nef. The cytotoxic activity mapped to the same epitopes identified for the proliferative response (a.a. 14-22, 47-53, 68-77, 70-77, 195-203 and 185-192) and was restricted by the same HLA class II molecules (DRw6, DQw7, DRw15(2), DR1 and DP5). Sensitization of the cytolytic clones with specific Nef peptides, but not soluble Nef, resulted in autolysis.

Stability and proteolytic domains of Nef protein from human immunodeficiency virus (HIV) type 1

Proteolytic experiments in conjunction with 1H-NMR spectroscopy show that the Nef (negative factor) protein from human immunodeficiency virus type 1 probably consists of two main domains, the N-terminal anchor domain at amino acid positions 2-65 and the C-terminal core domain at positions 66-206. The N-terminal domain is likely to be located at the surface of the protein, while the C-terminal domain has a compactly folded core and is stable in the absence of the anchor domain. It is conceivable that the core domain represents a functional domain of the Nef protein, activated after the removal of the membrane anchor by the human-immunodeficiency-virus protease or cellular proteases. Nef is stable at pH 5-12 and denatures at 317-322 K. The Nef protein remains in its native conformation in dimethyl-sulfoxide/water mixtures up to 35% (by vol.), and in acetonitrile/water up to 14% (by vol.). Nef refolds spontaneously after denaturation with urea or guanidinium hydrochloride. The 1H-NMR parameters and pKa values of five of the nine histidine residues and one of the seven tyrosine residues were determined and were found in four cases to be typical for residues which are not located in the interior of the protein.

Epitopes recognized by HIV-SF2 nef-specific CD4+ T-cell clones generated from HIV-1-uninfected donors

Human T-cell clones with specificity to the HIV-1 nef protein were generated by the in vitro stimulation of peripheral blood mononuclear cells (PBMCs) from HIV-1-seronegative donors with purified nef from the HIV-SF2 isolate produced in genetically engineered yeast. Here the characterization is described of a total of seven discrete clones derived from five different donors. Each clone was CD3+ CD4+ CD8- as determined by FACS analysis. The epitopes recognized by these clones were identified using synthetic overlapping peptides spanning the entire length of nef. Six discrete helper T-cell epitopes located in five distinct regions of nef were identified by this approach. Three of these epitopes are more than 80% conserved among all HIV-1 nef proteins for which sequence data are available. The remaining epitopes are in regions of nef that vary among isolates. Many of the epitopes recognized by our clones overlap T-cell epitopes identified by others examining T-cell responses to nef in HIV-1-infected patients and immunized animals. Using partially class II-matched EBV-transformed B-cell lines, we were able to identify five different HLA class II alleles which encode restricting elements for the in vitro nef-specific proliferative response of these clones (DR1, DRw15(2), DRw6, DQw7, DP5).

Highly localized tracks of human immunodeficiency virus type 1 Nef in the nucleus of cells of a human CD4+ T-cell line

A human T-cell line constitutively expressing the nef gene from the human immunodeficiency virus type 1 SF2 isolate was used to examine the distribution of the Nef protein in the nucleus. High-resolution immunogold labeling/electron microscopic studies with polyclonal anti-Nef antibodies on nef+ and nef- cells revealed that a small fraction of Nef is in the nucleus and it is localized in specific curvilinear tracks that extend between the nuclear envelope and the nucleoplasm. An examination of the sequence of the SF2 nef gene revealed a putative nuclear targeting sequence that was previously found in several other eukaryotic nucleoplasmic proteins. The nuclear localization of Nef suggests a potential nuclear function for this protein. The presence of Nef in distinct nuclear tracks suggests that Nef is transported along a specific pathway that extends from the nuclear envelope into the nucleoplasm. A previous study [Meier, U. T. & Blobel, G. (1992) Cell 70, 127-138] has shown that the nucleolar protein of rat liver cells (Nopp140) shuttles from the nucleolus to the nuclear envelope on distinct tracks. The present study has suggested that the transport of a nucleoplasmic protein may also occur on distinct nuclear pathways.

Analysis of antibody response to the measles virus using synthetic peptides of the fusion protein. Evidence of non-random pairing of T and B cell epitopes

The measles virus induces a life-long immune response associated with antibodies specific for the fusion protein. To map the linear immunodominant recognition sites of the fusion (F) protein of the measles virus, we have reacted a complete set of 108 overlapping pentadecapeptides with purified IgG obtained from donor sera with elevated anti-measles titers. The antibodies recognized about 20% of the peptides and generated a characteristic binding pattern, defining about 6 or 7 distinctive regions (31-75; 111-145; 151-165; 191-215; 271-320; 421-440; 481-530) which include the major hydrophobic segment (111-145) of the intersubunit region and the C-terminal Cys-cluster region. The binding sites were located in close proximity of the few experimentally defined T cell epitopes. This pairing of T and B cell epitopes was corroborated by computer-assisted T cell prediction. The significance of a non-random association of T and B cell epitopes for processing and presentation is discussed. It is speculated that in long-term immunity against measles (F protein), B cells of the same sIg specificity play an important role both as antigen presenting cells and as antibody producing cells. In contrast to human sera from late convalescent donors, mouse and rabbit MV antisera with high neutralizing titers as well as neutralizing MV-F specific monoclonal antibodies did not react with the peptides.

Analysis of the neutralizing antibody response to the measles virus using synthetic peptides of the haemagglutinin protein

Infection or immunization with measles virus induces a protective immune reaction including neutralizing antibodies against the haemagglutinin and fusion protein. The reactivity of the polyclonal IgG response of sera obtained from late convalescent donors was studied, using overlapping 15mer peptides covering the complete sequence of the measles virus haemagglutinin. Most sera reacted with a similar set of peptides generating a characteristic binding pattern. The reactive peptides correspond to a region mediating cell hemolysis (aa310-325), to regions which serve as targets to neutralizing antibodies and to a putative transmembrane region (aa35-58). The latter region contains also a human T-cell epitope providing evidence of a non-random association of T- and B-cell epitopes. We also immunized different strains of mice and rabbits with measles virus. In contrast to the human sera, animal sera with strong neutralizing activities did not react with any of the H-protein peptides. The mostly weak reactivities with the linear sequences contrast with the strong neutralizing activities of the human or animal antibodies, suggesting that these primarily recognize the fusion protein or conformational epitopes of the haemagglutinin protein.

Epitope mapping: synthetic approaches to the understanding of molecular recognition in the immune system

Progress in the field of immunochemistry is rapidly increasing due to very efficient methods of epitope mapping. Experimental results on the allele-specific sequence motifs of MHC-binding peptides allow the exact forecast of T-cell epitopes and, in combination with B-cell prediction methods and synthetic adjuvant systems, fully synthetic vaccines may be constructed. Methods of multiple peptide synthesis are of particular use for such constructs and for the fine mapping of monoclonal antibodies or sera of patients. Peptide libraries, containing hundred thousands of different oligopeptides are made available for novel screening procedures. These techniques and their applications in various fields are summarized and discussed with respect to efficiency and productivity.

Fine mapping of HIV-1 Nef-epitopes by monoclonal antibodies

A panel of newly isolated murine monoclonal antibodies is described which are specific for the Nef protein of the human immunodeficiency virus type 1 (HIV-1). Epitope mapping using recombinant Nef-related proteins, synthetic peptides and lipopeptides showed 3 independent antigenic determinants located within the regions of amino acids 83-93, 175-190 and 86-166 of the Nef protein. None of the monoclonal antibodies reacted with recombinant Nef proteins of HIV-2.

Comprehensive delineation of antigenic and immunogenic properties of peptides derived from the nef HIV-1 regulatory protein

The Human Immunodeficiency Virus (HIV-1) nef regulatory protein, a protein involved in AIDS pathology, was used as a model to investigate and analyze B- and T-cell epitopes. In this paper, we describe the potential structural basis of antigenic and immunogenic reactivity of synthetic peptides derived from the macromolecular antigen. The relationship between B- and T-cell determinants in the context of regulatory mechanisms involved in immune recognition, while integrating recent data concerning MHC presentation. As a result of the recent progress in the field of peptide recognition and presentation, the potential of the peptide approach for constructing successful synthetic vaccines needs to be continuously re-evaluated.

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.

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.

Cell-free transmission of Vif mutants of HIV-1

To determine the phenotype of human immunodeficiency virus type 1 (HIV-1) defective in the production of Vif, mutations were introduced into the vif gene of infectious molecular clones of the LAI, MAL, and ELI strains. Previous results had demonstrated that viruses derived from these wild type clones display different replicative capacities on peripheral blood mononuclear cells (PBMC) and different tropisms for CD4-positive cell lines. Using cell-free infection, Vif mutants of LAI, MAL, and ELI were found to have delayed kinetics and to produce less virus than their corresponding wild type viruses when propagated on most permissive cell lines. An additional mutation in the vpr gene in the LAI strain had no effect on this phenotype. However, on one T cell line, the H9 cell line, two Vif mutants of LAI and a Vif.Vpr double mutant were unable to replicate. Furthermore, Vif mutants from all three strains were only able to establish a productive infection on PBMC by coculture and not by cell-free infection. No defects in the processing of the virion proteins or the release of particles in the Vif mutants were detected.

Fine specificity of the B-cell epitopes recognized in HIV-1 NEF by human sera

We have previously used partially overlapping synthetic nonapeptides to characterize the human natural antibody response against HIV-1 negative regulatory factor (NEF), and identified nine 5 to 13 amino acid long regions that were recognized by sera of HIV-1-infected individuals. In this report we define the minimal size of these epitopes with the use of shorter, from 3 to 8 amino acid long partially overlapping peptides covering the complete sequence of the previously identified reacting regions and the N- and C-terminal flanking sequences. We also introduce a new method for the analysis of the reactivities obtained with peptides of different lengths. In six of the antigenic regions the epitopes were found to be noncontiguous and to consist of multiple, down to three amino acid long separate reactive stretches (epitope 1: WSK, VGW, TVRERMRR; epitope 3A: PLRPM, SHFLK; epitope 3B: SQRRQD, DLW; epitope 3C: IYHT, QGYFPDWQN; epitope 4: SLL, VSL; epitope 5: EVLEWRFDSR, VAR). Three epitopes were clearly linear (epitope 2: CAWLE; epitope 3D: LTFGWC; epitope 6: PEYF). Interestingly, five of the minimized B-cell epitopes (1, 3A, 3C, 3D, 5) recognized by human sera overlap totally or partly with the previously identified T-cell epitopes in HIV-1 NEF. Also, only three of the epitopes (3C, 3D, 5) were in a computer-based homology search shown to contain strictly NEF-specific sequences.

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.

Antigenic domains of the HIV-1 vif protein as recognized by human sera and murine monoclonal antibodies

To analyze the vif antibody response in individuals infected with the human immunodeficiency virus type 1 (HIV-1) and to determine antigenic epitopes on the vif protein, 104 HIV-1+ sera were screened for reactivity with a recombinant vif protein; 30 (28.8%) of these sera recognized the recombinant vif protein in immunoblot and were employed, together with 17 HIV-1/vif-negative control sera, in an enzyme immunoassay (EIA)-based epitope scanning assay with 183 overlapping decapeptides that covered the complete amino acid sequence of the HIV-1 vif protein (strain BH10). Of the 30 HIV-1/vif+ sera, 87% reacted with decapeptides comprising the two following epitopes: IEWRKKRY (vif amino acids 87-94) or DRWNKPQ (vif amino acids 172-178). The two epitopes were 89% and 100% conserved among different HIV-1 strains and their antigenicity could be confirmed by computer-assisted predictions of vif antigenic determinants. All the sera reactive with recombinant vif protein and with vif peptides originated from patients in CDC stages III or IV. Two murine anti-vif monoclonal antibodies reacted only with the seven C-terminal amino acids of the vif protein (SHTMNGH), which were not recognized by any of the human sera. Our results may be useful for further studies of vif seroreactivity and for the production of anti-vif mono- or polyclonal antibodies using vif peptides.

Immunological study of the nef protein from HIV-1 by polyclonal and monoclonal antibodies

We constructed and expressed different overlapping fusion proteins with the nef gene of HIV-1 and generated specific polyclonal rabbit and monoclonal mouse antibodies against these recombinant proteins. The rabbit antisera, one of the monoclonal antibodies as well as a serum from a HIV-1 infected patient recognized the nef protein with Mr 27 kDa in latently HIV-1 infected glioma cells in the immunoblot. In contrast, these antibodies could not detect nef in productively HIV-1 infected Molt-3 cells neither in immunoblot nor in indirect immunofluorescence assays. These results indicate the possible participation of nef in viral latency. The recombinant nef proteins were used as probes for anti-nef antibodies in human sera. We observed in 17 of 57 sera tested specific anti-nef antibodies. All of these anti-nef positive sera also contained antibodies directed against viral structural proteins. The NH2-terminal region of the recombinant nef was shown to be the major immunodominant antigenic site in the immunoblot assay.

Epitopes of the HIV-1-negative factor (nef) reactive with murine monoclonal antibodies and human HIV-1-positive sera

Murine monoclonal antibodies (MAbs) raised against a recombinant nef protein fragment of human immunodeficiency virus type 1 (HIV-1) strain BH10 were characterized by an epitope mapping system using overlapping decapeptides. Four different immunogenic regions were identified. Ten human HIV-1-positive sera were tested in the same epitope mapping system, seven of these were reactive with four immunogenic regions. Two of the nef-specific epitopes recognized by human sera overlapped with the epitopes defined by the murine monoclonal antibodies. The reactivity of the monoclonal antibodies with the recombinant nef protein and with infected and uninfected cells were investigated in a variety of test systems. The results are discussed with respect to homologous regions of nef and cellular proteins.

Antibodies to recombinant HIV-1 vif, tat, and nef proteins in human sera

The prevalence of antibodies against HIV-1 regulatory proteins in sera of HIV-infected patients from different stages of disease was investigated. HIV-1 vif, tat, and nef genes were cloned in procaryotic vectors and were expressed as MS-2 fusion proteins (vif and nef) or as a non-fusion protein (tat). These recombinant proteins were employed in immunoblot experiments. The specificity of the recognition was confirmed by competition experiments and with control sera from HIV-negative patients. Analysis of 136 serum samples revealed a high percentage of antibodies against nef, irrespective of the stage of disease. Antibodies against tat were found less frequently and increased from 16% to 40% with disease progression. Vif antibodies were detected only in a low percentage in early stages of disease, but their prevalence increased to 36% and 72% with progression of disease to AIDS-related complex and AIDS. Our data suggest that the detection of antibodies against nef may represent an additional and useful marker for the diagnosis of HIV infection, whereas the detection of vif antibodies may indicate disease progression.