Polyclonal use of T-cell receptor alpha for human T-cell lymphotropic virus type 1-infected T cells.
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To understand better the immunopathology of HTLV-I uveitis by investigating the clonality of HTLV-I-infected T-cell clones.Eleven T-cell clones were established from the aqueous humor (six clones) and the peripheral blood (five clones) of a patient with HTLV-I uveitis, and the clonality of the HTLV-I-infected T cells was investigated by sequencing the T-cell receptor (TCR) alpha gene after the amplification of TCR alpha cDNA using an adaptor-ligation method and reverse transcriptase-polymerase chain reaction (RT-PCR).TCR alpha use was different for each of 11 T-cell clones, encompassing eight different HTLV-I-infected T-cell clones (four from the aqueous humor and four from peripheral blood) and three HTLV-I-negative T-cell clones.This study demonstrated polyclonal use of TCR alpha for HTLV-I-infected T cells in the ocular lesion and the peripheral blood. Results suggested that these T cells are not precursors of the leukemic cells associated with malignant transformation. Instead, they might be randomly infected with HTLV-I in the process of HTLV-I uveitis.Keywords:
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Polyclonal use of T-cell receptor alpha for human T-cell lymphotropic virus type 1-infected T cells.
To understand better the immunopathology of HTLV-I uveitis by investigating the clonality of HTLV-I-infected T-cell clones.Eleven T-cell clones were established from the aqueous humor (six clones) and the peripheral blood (five clones) of a patient with HTLV-I uveitis, and the clonality of the HTLV-I-infected T cells was investigated by sequencing the T-cell receptor (TCR) alpha gene after the amplification of TCR alpha cDNA using an adaptor-ligation method and reverse transcriptase-polymerase chain reaction (RT-PCR).TCR alpha use was different for each of 11 T-cell clones, encompassing eight different HTLV-I-infected T-cell clones (four from the aqueous humor and four from peripheral blood) and three HTLV-I-negative T-cell clones.This study demonstrated polyclonal use of TCR alpha for HTLV-I-infected T cells in the ocular lesion and the peripheral blood. Results suggested that these T cells are not precursors of the leukemic cells associated with malignant transformation. Instead, they might be randomly infected with HTLV-I in the process of HTLV-I uveitis.
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We report the detection of human T‐lymphotropic virus type I (HTLV‐I) genomic sequences by polymerase chain reaction in lymphocyte cultures of three unrelated native Solomon Islanders, including a patient with HTLV‐I myeloneuropathy, residing in widely separated regions. In addition, we have isolated HTLV‐I from T‐cell lines derived from two of these individuals. Virus‐specific proteins of 15, 19, 24, 46 and 53 kilodaltons were detected by immunofluorescence and Western immunoblot, using serum from a Colombian patient with HTLV‐I myeloneuropathy, sera from HTLV‐I‐infected rabbits, and monoclonal and polyclonal antibodies against HTLV‐I gag and env gene products. Amplification of HTLV‐I gag, pol and env sequences by polymerase chain reaction confirmed that the viral isolates were HTLV‐I, not HTLV‐II. Our data clearly demonstrate that HTLV‐I does exist in Melanesia. Although the Solomon Islands viral isolates resemble prototype strains of HTLV‐I, we believe they represent variants of HTLV‐I, particularly in the light of our recent isolation of an HTLV‐I variant from Papua New Guinea. Nucleotide sequence analysis of these viral strains, now in progress, should clarify the molecular epidemiology and phylogeny of HTLV‐I.
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A full-length molecular clone of equine infectious anemia virus (EIAV) was isolated from a persistently infected canine fetal thymus cell line (Cf2Th). Upon transfection of equine dermis cells, the clone, designated CL22, yielded infectious EIAV particles (CL22-V) that replicated in vitro in both Cf2Th cells and an equine dermis cell strain. Horses infected with CL22-V developed an antibody response to viral proteins and possessed viral DNA in peripheral blood mononuclear cells, as determined by polymerase chain reaction assays. In addition, horses infected with CL22-V became persistently infected and were capable of transmitting the infection by transfer of whole blood to uninfected horses. However, CL22-V, like the parental canine cell-adapted virus, did not cause clinical signs in infected horses. Reverse transcriptase assays of CL22-V- and virulent EIAV-infected equine mononuclear cell cultures indicated that the lack of virulence of CL22-V was not due to an inability to infect and replicate in equine mononuclear cells in vitro.
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Three rat mAb, RR3-15, RR3-16, and RR3-18, were established by fusing spleen cells from a rat immunized with the male Ag-specific cytolytic T cell clone, OH6, to mouse myeloma cells. The mAb was identified by their capacity to focus the cytolytic activity of the OH6 CTL clone on nonspecific target cells via FcR-FcR interaction. That all three mAb recognized the OH6 TCR was confirmed by immunoprecipitation studies in which each antibody precipitated a 90 kDa disulfide-linked heterodimer characteristic of the TCR. Surface immunofluorescence staining of a panel of T cell lines and splenic T cell populations showed that RR3-16 reacted not only to the OH6 T cell clone but also to a minor fraction of normal T cells. This reactivity was found to be due to the expression of a gene in the V alpha 3 family. However, RR3-16 did not react with all T cell lines and clones known to express genes from the V alpha 3 family. cDNA sequences of three independent RR3-16+ T cell hybridomas analyzed by polymerase chain reaction were identical to the previously published V alpha 3 sequence of the CTL clone C9. Thus, the mAb RR3-16 is specific for a single member of the TCR V alpha 3 gene family. Analysis of the expression of RR3-16+ TCR in CD4+ and CD8+ subsets of peripheral T cells demonstrated preferential expression on CD8+ T cells, suggesting regulated expression of this particular TCR V alpha gene.
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It has been assumed, without direct evidence, that T cell hybridomas and non-transformed T cell clones are both good models of normal Ag-specific T cells. To compare directly the difference in activation of cloned normal T cells and T hybridoma cells with the same TCR, cloned T hybridoma cells were obtained by fusing pre-established, myoglobin-specific, Iad-restricted T cell clones (14.5 and 9.27) with BW5147 cells. T cell clones were pre-activated with IL-2 as well as specific Ag before fusion. Cloned T hybridoma A3.4C6 was derived from Lys 140-specific and I-Ed-restricted clone 14.5. The other cloned T hybridoma, C7R14, was a fusion product of Glu 109-specific and I-Ad-restricted clone 9.27. Both T hybridomas showed the same Ag specificity and Ia restriction as the parental cloned T cells. However, C7R14 showed higher apparent affinity and broader cross-reactivity than 9.27. Clone 14.5, but not hybridoma A3.4C6, appeared to stimulate splenic cells to secrete cytokines inhibiting HT-2A cell proliferation. The most striking difference between the clones and hybridomas was that both clones, but neither of the matched hybridomas, were induced to synthesize IL-1 on stimulation with Ag. Finally, both cloned T cells and T hybridomas killed Ag-pulsed Iad-bearing B lymphoma target cells. This evidence suggests that killing function can be inherited from clones to hybridomas. However, the clones were much more efficient at killing than the hybridomas, and the hybridomas were more efficient at IL-2 production than the clones. Thus, matched pairs of clones and hybridomas differ in their capacity to mediate the two functions or may tend to be selected differently during cloning. Thus, although our results generally support the validity of T cell hybridomas as faithful models of the corresponding T cell clones, a number of subtle and not-so-subtle differences indicate that caution must be used in such an extrapolation.
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