Expression and Purification of a Novel Computationally Designed Antigen for Simultaneously Detection of HTLV-1 and HBV Antibodies.

Computational tools are reliable alternatives to laborious work in chimeric protein design. In this study, a chimeric antigen was designed using computational techniques for simultaneous detection of anti-HTLV-I and anti-HBV in infected sera. Databases were searched for amino acid sequences of HBV/HLV-I diagnostic antigens. The immunodominant fragments were selected based on propensity scales. The diagnostic antigen was designed using these fragments. Secondary and tertiary structures were predicted and the B-cell epitopes were mapped on the surface of built model. The synthetic DNA coding antigen was sub-cloned into pGS21a expression vector. SDS-PAGE analysis showed that glutathione fused antigen was highly expressed in E. coli BL21 (DE3) cells. The recombinant antigen was purified by nickel affinity chromatography. ELISA results showed that soluble antigen could specifically react with the HTLV-I and HBV infected sera. This specific antigen could be used as suitable agent for antibody-antigen based screening tests and can help clinicians in order to perform quick and precise screening of the HBV and HTLV-I infections.

The prevalence and significance of HTLV-I/II seroindeterminate Western blot patterns.

Human T-lymphotropic virus type I (HTLV-I) infects an estimated 15-20 million persons worldwide. A number of diseases have been associated with the virus including adult T-cell leukemia (ATL), HTLV-associated myelopathy/tropical spastic paraparesis (HAM/TSP), HTLV-I uveitis, and HTLV-I-associated infective dermatitis. Once it was shown that there is an increased risk for developing HAM/TSP associated with blood transfusion, screening for HTLV-1 among blood banks was implemented in Japan, United States, France, and the Netherlands. This process includes detection by an enzyme immunoassay (EIA) followed by a confirmatory Western blot (WB) in which recombinant proteins specific for HTLV-I Env glycoproteins are incorporated into WB strips. HTLV-I seropositive results are defined by the presence of antibodies against either gp46 or gp62/68 (both Env protein bands) and either p19, p24, or p53 (one of the gag bands). HTLV-II seropositivity is confirmed by the presence of rgp46-II. However, numerous cases have been documented in which serum samples are reactive by EIA, but an incomplete banding pattern is displayed by subsequent confirmatory WB. Although the significance of these HTLV-I/II seroindeterminates is unclear, it may suggest a much higher incidence of exposure to HTLV-I/II than previously estimated.

False positive antibody results against human T-cell lymphotropic virus in patients with severe acute respiratory syndrome.

Taiwan suffered from the outbreak of severe acute respiratory syndrome (SARS) in 2003. Our laboratory performed a series of virology and serology tests for SARS patients admitted to our hospital. Cross-reactivity was found when testing for antibody against human T-cell lymphotropic virus (HTLV) in one patient with SARS. Therefore, antibodies against HTLV were examined in paired-sera from 26 SARS patients. ELISA and a neutralization test were used to measure anti-SARS antibodies. Seroconversion for antibody against SARS-CoV was observed in all patients. Surprisingly, with the use of ELISA for HTLV, sera for 13 patients were positive for HTLV (50%), and seroconversion for HTLV was also observed in 10 patients (38.5%). Western blot for HTLV on those 26 paired-sera from 13 HTLV-positive patients displayed 5 positive results for HTLV-I, 7 positive results for HTLV-II, 1 positive result for both HTLV-I and II, 9 negative results for either HTLV-I or HTLV-II, and 4 "indeterminate" results. The findings that antibody to HTLV can be detected in blood samples collected from SARS patients provide important information for safe handling of blood products. Without such knowledge, blood products can be discarded mistakenly even though they contain anti-SARS-CoV antibodies that may be potentially valuable for SARS therapy.

Human T lymphotropic virus type 1 in a seronegative B chronic lymphocytic leukemia patient.

Human T lymphotropic virus type 1 (HTLV-1) is the etiological agent of adult T cell leukemia and HTLV-1-associated myelopathy/tropical spastic paraparesis. HTLV-1 infection in patients with B cell-type chronic lymphocytic leukemia (B-CLL) is rare and has been reported only in areas in which HTLV-1 is endemic. In the present study, we detected HTLV-1 proviral DNA by polymerase chain reaction, using tax primers, in peripheral blood lymphocytes from a B-CLL patient, an immigrant to Israel, where HTLV-1 infection is not endemic. F344 rats injected intravenously with peripheral blood lymphocytes obtained from the patient developed HTLV-1 antibodies. Titers of antibody to HTLV-1 in the rat blood were 1:512 by particle agglutination; enzyme-linked immunosorbent assay and Western blotting were also positive. No antibody against HTLV-1 was demonstrated in the animal model after inoculation of either purified B lymphocytes from the B-CLL patient or peripheral blood mononuclear cells from healthy donors. This is one of the few studies showing the presence of HTLV-1 provirus in T lymphocytes of a B-CLL patient who had multiple infections, and died of salmonella sepsis, and the first report of HTLV-1 antibody induction in an animal model by inoculation of lymphocytes obtained from an HTLV-1-infected B-CLL patient.

The pathogenesis of tropical spastic paraparesis/human T-cell leukemia type I-associated myelopathy.

Tropical spastic paraparesis/human T-cell leukemia type I-associated myelopathy (TSP/HAM) is caused by a human T-cell leukemia virus type I (HTLV-I) after a long incubation period. TSP/HAM is characterized by a chronic progressive paraparesis with sphincter disturbances, no/mild sensory loss, the absence of spinal cord compression and seropositivity for HTLV-I antibodies. The pathogenesis of this entity is not completely known and involves a multivariable phenomenon of immune system activation against the presence of HTLV-I antigens, leading to an inflammatory process and demyelination, mainly in the thoracic spinal cord. The current hypothesis about the pathogenesis of TSP/HAM is: 1) presence of HTLV-I antigens in the lumbar spinal cord, noted by an increased DNA HTLV-I load; 2) CTL either with their lytic functions or release/production of soluble factors, such as CC-chemokines, cytokines, and adhesion molecules; 3) the presence of Tax gene expression that activates T-cell proliferation or induces an inflammatory process in the spinal cord; 4) the presence of B cells with neutralizing antibody production, or complement activation by an immune complex phenomenon, and 5) lower IL-2 and IFN-gamma production and increased IL-10, indicating drive to a cytokine type 2 pattern in the TSP/HAM subjects and the existence of a genetic background such as some HLA haplotypes. All of these factors should be implicated in TSP/HAM and further studies are necessary to investigate their role in the development of TSP/HAM.

The pathogenesis of tropical spastic paraparesis/human T-cell leukemia type I-associated myelopathy

Tropical spastic paraparesis/human T-cell leukemia type I-associated myelopathy (TSP/HAM) is caused by a human T-cell leukemia virus type I (HTLV-I) after a long incubation period. TSP/HAM is characterized by a chronic progressive paraparesis with sphincter disturbances, no/mild sensory loss, the absence of spinal cord compression and seropositivity for HTLV-I antibodies. The pathogenesis of this entity is not completely known and involves a multivariable phenomenon of immune system activation against the presence of HTLV-I antigens, leading to an inflammatory process and demyelination, mainly in the thoracic spinal cord. The current hypothesis about the pathogenesis of TSP/HAM is: 1) presence of HTLV-I antigens in the lumbar spinal cord, noted by an increased DNA HTLV-I load; 2) CTL either with their lytic functions or release/production of soluble factors, such as CC-chemokines, cytokines, and adhesion molecules; 3) the presence of Tax gene expression that activates T-cell proliferation or induces an inflammatory process in the spinal cord; 4) the presence of B cells with neutralizing antibody production, or complement activation by an immune complex phenomenon, and 5) lower IL-2 and IFN-gamma production and increased IL-10, indicating drive to a cytokine type 2 pattern in the TSP/HAM subjects and the existence of a genetic background such as some HLA haplotypes. All of these factors should be implicated in TSP/HAM and further studies are necessary to investigate their role in the development of TSP/HAM

Human T-cell lymphotropic virus type 1 gag indeterminate western blot patterns in Central Africa: relationship to Plasmodium falciparum infection.

To gain insight on the significance of human T-cell lymphotropic virus type 1 (HTLV-1) indeterminate serological reactivities, we studied villagers of South Cameroon, focusing on a frequent and specific HTLV-1 Gag indeterminate profile (HGIP) pattern (gag p19, p26, p28, and p30 without p24 or Env gp21 and gp46). Among the 102 sera studied, 29 from all age groups had a stable HGIP pattern over a period of 4 years. There was no epidemiological evidence for sexual or vertical transmission of HGIP. Seventy-five percent of HGIP sera reacted positively on MT2 HTLV-1-infected cells by immunofluorescence assay. However, we could not isolate any HTLV-1 virus or detect the presence of p19 Gag protein in cultures of peripheral blood mononuclear cells obtained from individuals with strong HGIP reactivity. PCR experiments conducted with primers for HTLV-1 and HTLV-2 (HTLV-1/2 primers) encompassing different regions of the virus did not yield HTLV-1/2 proviral sequences from individuals with HGIP. Using 11 peptides corresponding to HTLV-1 or HTLV-2 immunodominant B epitopes in an enzyme-linked immunosorbent assay, one epitope corresponding to the Gag p19 carboxyl terminus was identified in 75% of HGIP sera, while it was recognized by only 41% of confirmed HTLV-1-positive sera. A positive correlation between HTLV-1 optical density values and titers of antibody to Plasmodium falciparum was also demonstrated. Finally, passage of sera through a P. falciparum-infected erythrocyte-coupled column was shown to specifically abrogate HGIP reactivity but not the HTLV-1 pattern, suggesting the existence of cross-reactivity between HTLV-1 Gag proteins and malaria-derived antigens. These data suggest that in Central Africa, this frequent and specific Western blot is not caused by HTLV-1 infection but could instead be associated with P. falciparum infection.

[Expression of a fragment of the env gene, coding for the GP46 surface glycoprotein of the human T-cell leukemia virus, in Escherichia coli cells]. / Ekspressiia fragmenta gena env, kodiruiushchego poverkhnostnyi glikoprotein GP46 virusa T-kletochnogo leikoza cheloveka tipa II, v kletkakh bakterii Escherichia coli.

Designing of recombinant plasmids pSB2 and pSB3 with the 932 bp HTLV-II env gene inserts encoding the full-length surface membrane glycoprotein gp46 is described. Vectors pGOmpF and pET32a expressing genes cloned under control of the late bacteriophage T7 promoter were used. Western blot analysis of cellular proteins derived from E. coli B834/pSB2 and E. coli B834/pSB3 revealed that 34 kD and 31 kD polypeptides corresponding to the full-length gp46 and its processed form without signal peptide were synthesized under control of these recombinant plasmids. Cytotoxic activity of the recombinant proteins towards bacterial cells was demonstrated. Both polypeptides specifically reacted to sera from humans infected with HTLV-II. High antigenic specificity of P34-HTLV-II proteins makes a promising candidate for diagnostic confirmation tests.

The HTLV-I orfI protein is recognized by serum antibodies from naturally infected humans and experimentally infected rabbits.

The mechanism of T-cell transformation by human T-cell lymphotropic virus type I (HTLV-I), though not completely understood, appears to involve the interactions of several viral and cellular proteins. One of these viral proteins, p12(I), encoded by HTLV-I orfI, is a weak oncogene that binds the 16-kDa subunit of the vacuolar ATPase and interacts with the immature beta and gamma(c) chains of the IL-2 receptor. We have expressed the singly spliced orfI cDNA in the baculovirus system and used the recombinant protein as a tool to assess the presence of antibodies in naturally or experimentally infected hosts. In addition, rabbit antisera were raised against various p12(I) synthetic peptides and used to identify three antigenic regions within p12(I), one between the two putative transmembrane regions of p12(I) and two at the carboxy-terminus of the protein. More importantly, sera from a naturally infected human (1 of 32) and experimentally infected rabbits (9 of 20) recognized the rp12(I), demonstrating orfI expression and immunogenicity in vivo. Taken together these data provide the first evidence of orfI expression during HTLV-I infections.

Influence of amino acid substitutions on antigenicity of immunodominant regions of the HTLV type I envelope surface gylcoprotein: a study using monoclonal antibodies raised against relevant peptides.

By the use of sera of human T cell leukemia virus type I (HTVL-I)-infected individuals it was shown that amino acid substitutions at positions 192 (proline to serine) and 250 (serine to proline) in major immunodominant regions (175-199 and 239-261) of the surface envelope glycoprotein (gp46) of the virus may influence the humoral response. Since human sera are polyclonal in nature, one cannot readily discriminate between an immunoglobulin-specific recognition and multiple bindings of diverse antibodies. To overcome this difficulty we generated murine monoclonal antibodies to synthetic peptides mimicking all or portions of these gp46 regions. The reactivity of some of these antibodies to synthetic peptides harboring (or not harboring) the preceding amino acid substitutions at position 192 or 250, to denatured gp46 by Western blotting, and to live (variously substituted) HTLV-I-infected cells, combined with blocking experiments with various peptides, allow us to conclude that the major epitopes (positions 183-191, 190-197, 190-199, and 246-252) in the two immunodominant regions may elicit different antibody responses according to their sequences. It is worth noting that in a reporter gene inhibition assay, it was found that a neutralizing monoclonal antibody (MF1), the epitope for which is located between residues 190 and 197, had a high level of activity when cells (2060) harboring a gp46 with proline at position 192 were used and had no activity toward cells (1010) with a serine at this position. Therefore our results establish that certain amino acid substitutions of gp46 may drastically affect the antigenicity of the molecule and the biological activity of the antibodies elicited.

Characterization of a simian T-lymphotropic virus from a wild-caught orang-utan (Pongo pygmaeus) from Kalimantan, Indonesia.

In a recent serological survey among 143 ex-captive orang-utans two individuals were found that reacted positive in an ELISA detecting antibodies which cross-react with human T-lymphotropic virus type I (HTLV-I) antigens. Infection of both animals with an HTLV-I or simian T-lymphotropic virus (STLV)-like virus was confirmed by Western blot analysis. A third wild-caught animal, which was not part of the original serological survey, was also found to be infected with an HTLV-related virus in a diagnostic PCR assay and Western blot assay. Nucleotide sequence analysis of the 709 bp PCR fragment from the tax/rex region of the HTLV/STLV genome confirmed infection of orang-utans with an STLV similar to but clearly distinct from other Asian STLVs.

Random suppression of T cells that bear specific T cell receptor V beta sequences in adult T cell leukemia/lymphoma (ATLL) patients at each clinical stage: carrier, smoldering, chronic, and acute.

Human T cell leukemia virus type I (HTLV-I) is associated with adult T cell leukemia/lymphoma (ATLL), which is well known as a T cell malignancy. In order to clarify whether HTLV-I plays a role as a virus-encoded superantigen in the neoplastic process, we examined the TCR V beta families in the peripheral blood at four different clinical stages: carrier, smoldering leukemia, chronic leukemia, and acute leukemia. An increased number of CD4 T cells was found in each of the four clinical stages. However, we found neither uniform specific losses nor uniform clonal expansion of particular TCR V beta gene families in any case from the four clinical stages. However, a suppression of the random TCR V beta families was found. Our data did not therefore directly suggest the existence of a common superantigen model of HTLV-I which induces an increase in CD4 T cells. The random suppression in the TCR V beta repertoire is most likely caused by the influence of HTLV-I neoplastic pathogenesis rather than by virus-encoded superantigens. In the patients with acute leukemia, one or two families of the V beta repertoires were very strongly expressed, while in chronic leukemia, no such repertoire of strong expression was observed. The immunological reaction of the hosts might thus be different between the above described groups.

Rapid generation of antibodies against the HTLV-II external envelope protein by growth of mouse plasmacytomas in SCID mice.

Recombinant human T-cell leukemia virus type II (HTLV-II) envelope external glycoprotein, gp46-II, was expressed using a vaccinia virus vector. A recombinant gp46-II fused to an epitope of the influenza virus hemagglutinin, YPYDVPDYA, was purified by immunoaffinity chromatography. The purified glycoprotein was used to immunize Balb/c mice, and antibodies against gp46-II were detected by Western blot analysis and syncytium inhibition assays. We transformed spleen cells from the immunized mice by retroviral infection with ABL-MYC (psi 2) and intraperitoneally transplanted the infected cells into syngeneic Balb/c and severe combined immunodeficient (SCID) mice. The plasmacytomas established ascitic tumors that produced antibodies directed against HTLV-II gp46-II. Ascites developed more rapidly in SCID mice than in normal syngeneic mice. This procedure provides a general means to generate antibodies rapidly.

Association between maternal antibodies to the external envelope glycoprotein and vertical transmission of human T-lymphotropic virus type I. Maternal anti-env antibodies correlate with protection in non-breast-fed children.

Vertical transmission of human T-lymphotropic virus type I (HTLV-I) depends primarily on breast-feeding; substitution of bottle-feeding has reduced the transmission rate from 20% in breast-fed children to 3% among bottle-fed. To determine the correlates of transmission for long breast-feeding (> or = 6 mo), short breast-feeding (< 6 mo), and bottle-feeding mothers, the antibody titers of transmitter (T) mothers and non-transmitter (nT) mothers were analyzed by using synthetic and recombinant epitopes representing the immunodominant epitopes of gag (Gag1a, r24), env (Env1/5, MTA1, RE3), and tax (Tax8/22-24) proteins. Seroreactivity to gag and tax epitopes was not significantly different except for anti-r24 antibody titer, which was significantly higher among T-mothers (geometric mean 134) when compared with nT-mothers (62) in the long-feeding group (P < 0.001). Profiles of antibody titers against env epitopes were different. Within the long-feeding group, Env1/5, MTA1, and RE3 titers were significantly higher among T-mothers (258, 1,476, and 738, respectively) when compared with nT-mothers (106, 279, and 320, respectively) (P < 0.01 for all three epitopes). In contrast, within the bottle-feeding group, antibody titers to Env1/5 (269) and RE3 (418) among nT-mothers were significantly higher than those among T-mothers (80 and 113, respectively) (P < 0.01). These data confirm that high-titered anti-HTLV-I antibodies in the long-feeding group correlate with milk-borne transmission of HTLV-I and, more importantly, imply that maternal anti-env antibodies may reduce the risk of non-milkborne infection.

A peptide-based human T cell leukemia virus type I vaccine containing T and B cell epitopes that induces high titers of neutralizing antibodies.

We have recently identified the principal linear neutralizing B cell epitopes of human T cell leukemia virus type I (HTLV-I) on the envelope protein gp46, amino acids (aa) 187-199, by using a number of human mAbs. We therefore propose that this region would be a good candidate for a peptide-based HTLV-I vaccine. To develop a peptide-based vaccine that can induce a high titer of neutralizing Abs against HTLV-I, we first synthesized peptides of various lengths containing aa187-199. Because the addition of gp46 aa181-186 or aa200-210 to either the N-terminus or C-terminus of SP187-199 did not alter the antigenicity of the principal neutralizing determinant, we prepared two peptide-based vaccines, MAP181-203 and MAP181-210, by conjugating SP181-203 and SP181-210 with a branched polylysine oligomer. In rabbits, X4 to X8 and X8 to X64 titers of the neutralizing Abs were induced by immunization with MAP181-203 and MAP181-210, respectively. Furthermore, high titers of neutralizing Abs (X40 to X320) were elicited in five different strains of rats by immunization with MAP181-210. We also identified the major T cell epitope on gp46 aa194-210 in various strains of rats immunized with MAP181-210. Furthermore, the peripheral T lymphocytes obtained from the majority of HTLV-I-infected patients including HTLV-I-associated myelopathy/tropical spastic paraparesis, adult T cell leukemia/lymphoma, and healthy carriers, proliferated in response to the peptides containing aa194-210. These results indicated that MAP181-210 contains a T cell helper epitope on aa194-210 not only in rats and rabbits, but also in humans with various HLA haplotypes. It is therefore possible that MAP181-210 could become one of the candidates for a peptide-based HTLV-I vaccine for human use.

RS3PE syndrome: no evidence for retroviruses.

OBJECTIVE: To determine whether human T cell lymphotrophic virus (HTLV) infection is associated with remitting seronegative symmetrical synovitis with pitting edema (RS3PE) syndrome. METHODS: Three patients presenting with RS3PE syndrome and 7 controls were examined for the presence of HTLV crossreactive antigens. RESULTS: Our patients were elderly men who presented with typical symptoms of abrupt onset of synovitis of the wrist, carpal joints, metacarpophalangeal, proximal interphalangeal, distal interphalangeal joints, and flexor tendons, associated with remarkable pitting edema of the hands. Transmission electron microscopy and immunohistochemical analysis for HTLV-1 P19 and P20 related antigens failed to detect retroviral presence in the sample specimens or controls. CONCLUSION: Our investigation suggests there is no evidence for HTLV synovial infection associated with RS3PE.

Establishment and characterization of an HTLV-I cell line from a Taiwanese patient with HTLV-I-associated myelopathy.

We describe a Taiwanese woman with chronic progressive myelopathy, in whom Western blot analysis of the serum and cerebrospinal fluid (CSF) displayed positive reactions to human T-lymphotropic virus type I (HTLV-I) proteins, p19, p24, p28, p36, gp46 and p53. HTLV-I proviral genomes were detected in the peripheral blood mononuclear cells (PBMC) and CSF cells by nested polymerase chain reaction and Southern blot hybridization. HTLV-I was successfully isolated from PBMC stimulated with interleukin-2 (IL-2). The established cell line, named THAM-1, was an IL-2-independent T-cell line with CD2+, CD3+, CD4+, CD25+ and HLA-DR+. Retrovirus particles with type C morphology were observed in the THAM-1 cells by electron microscopy, and HTLV-I-related antigens were also demonstrated by immunocytochemical staining and Western blot assay. Southern blot analysis revealed that HTLV-I proviral genomes were integrated into the THAM-1 cellular DNA. In Northern blot analysis, two extra-species of RNA were detected in addition to three typical viral transcripts. For the first time, an HTLV-I-producing T cell line was established from a patient with HTLV-I-associated myelopathy in Taiwan, an HTLV-I non-endemic area.

Detection of human T-lymphotropic virus type-I/II env antibodies by immunoassays using recombinant fusion proteins.

Two recombinant fusion proteins representing the C-terminus of the envelope glycoprotein of HTLV-I (rEnv-93(201-440)) and the C-terminus of the external glycoprotein (RE-3(165-306)) were tested in a Western blot (WB) assay for their ability to detect the presence of env antibodies in serum specimens from HTLV-I (n = 27) and HTLV-II (n = 22) infected individuals. The rEnv-93 reacted with 27 (100%) of 27 HTLV-I-infected specimens and 19 (86%) of 22 of HTLV-II-infected specimens. In contrast, RE-3 reacted with 25 (93%) of 27 HTLV-I-infected specimens, and only six (27%) of 22 HTLV-II-infected specimens, thus demonstrating predominant reactivity with HTLV-I compared with HTLV-II. Because of the high sensitivity of rEnv-93 reactivity in both HTLV-I and HTLV-II, the specificity of this env protein was evaluated in specimens with isolated gag reactivity (HTLVind). Of the 44 HTLVind specimens, four (9%) demonstrated reactivity to rEnv-93 in WB assay. We, therefore, conclude that although rEnv-93 is highly sensitive for detection of env protein, it has the potential to yield some false-positive reactions presumably due to the conserved nature of retroviral transmembrane epitopes.

Serological speciation of human T-cell leukaemia virus infections using synthetic peptide antigens.

In order to assess the specificity and sensitivity of two peptide-based assays (Synth HTLV-I and HTLV-II enzyme-linked immunoassay [EIA] [UBI] and Select-HTLV EIA [IAF]) in discriminating between antibody to HTLV-I and HTLV-II infection, a panel of 186 well-characterised serum/plasma samples was tested by the two assays. The panel comprised 160 samples that by Western blot were confirmed to contain antibodies to HTLV-I/II and 26 samples that showed reactivity with gag but not env gene products. Both assays were found to be specific in that they did not misclassify any of the 80 specimens from cases of tropical spastic paraparesis or adult T-cell leukaemia/lymphoma, diseases believed to be HTLV-I associated, as anti-HTLV-II positive. Of the 160 specimens confirmed as anti-HTLV-I/II positive by Western blot, 6.2% were negative or untypable in the Synth EIA compared with 13.7% in the Select EIA. Of the 26 Western blot indeterminate samples, 16 were negative by both assays. Five were typed as anti-HTLV-I by both assays and 5 as anti HTLV-II by Select EIA only. The peptide based EIAs offer an economical and, in most cases, reliable means of discriminating between anti-HTLV-I and anti-HTLV-II. However, they should only be applied to sera that have been confirmed by Western blot or other methods as anti-HTLV-I/II positive. Even then they may fail to speciate sera from non-Japanese, non-Afrocaribbean populations.

Detection of HTLV-I and HTLV-II infection in Africans using type-specific envelope peptides.

Antibodies to HTLV were determined in 4,630 black African individuals from Zaire, Ghana and South Africa; 185 (4%) were confirmed as seropositive. Seroprevalance was 0.2% in a group of South African women, 0.9% among Ghanaian refugees in Belgium and from less than 1% to over 15% in various sites and populations in Zaire. With the use of HTLV-I and HTLV-II type-specific envelope peptides, 93% of confirmed HTLV seropositives were classified as HTLV-I. Five persons from the Haut Zaire region had HTLV-II serological reactivities, suggesting the presence of HTLV-II or a related retrovirus in central Africa. A cluster of HTLV-I-like indeterminate western blot patterns lacking anti-p24 antibody was found in Bas Zaire.