In this study, we utilized two anti-T11 monoclonal antibodies (mAbs) that inhibited the specific cytolytic activity of mixed lymphocyte culture (MLC) activated T cells to analyze, at the clonal level, the involvement of T11 molecules in 1) antigen specific versus non-specific mechanisms of target cell lysis 2) antigen-driven T cell proliferation and IL-2 production versus IL-2-induced cell proliferation. In contrast to anti-T3 or anti-T8 mAbs, antibodies to T11 molecules inhibited the cytolytic activity of MLC-derived allospecific clones in a uniform manner. In addition, anti-T11 antibodies inhibited the specific activity of CTL clones resistant to anti-T3 antibodies, even after antibody-induced modulation of T3 molecules (while anti-T3 mAbs had no effect). Similarly, anti-T11 antibodies inhibited the alloantigen induced proliferation and IL-2 release of alloreactive clones independent on their T4+ or T8+ phenotype. The inhibitory activity of anti-T11 antibodies appears to be confined to antigen-specific T cell functions since neither natural killer-like activity of CTL clones nor the IL-2 induced clonal proliferation was affected. Thus, our results indicate that T11 molecules are functionally involved in antigen recognition by T cell regardless of their function and T4/T8 phenotype.
Abstract Clones capable of lysing fresh, uncultured tumor cells (“lym‐phokine‐activated killer”: “LAK” activity) were selected from microcultures derived from either E‐rosette‐positive or E‐ rosette‐negative cell populations. All the selected clones displayed a strong cytolytic activity against the NK‐sensitive K562 cell line. Two major phenotypic groups of clones could be identified: a first group expressed the CD3 differentiation antigen, present exclusively on mature T lymphocytes; however, in contrast to typical cytolytic T lymphocytes, the majority of these clones expressed the unusual CD4‐ CD8‐ phenotype, whereas the remainder were CD4‐ CD8 +. A second group was represented by CD3 ‐ clones which, in most instances, expressed the T‐cell‐lineage‐specific CD2 antigen. Following stimulation with phytohemagglutinin (PHA), most of the CD3 + LAK clones produced lnterleukin‐2 (1L‐2) and interferon‐γ (1FN‐γ) whereas those expressing the CD3 ‐ phenotype did not. Since previous studies indicated that PHA may be inefficient in inducing lymphokine production by T‐ cell variants lacking the CD3/T cell receptor complex (TCR), CD3 ‐ clones were further stimulated with the calcium iono‐phore A23187 plus phorbol 12‐myristate 13‐acetate (PMA). Only 2/11 CD3 ‐ LAK clones produced small amounts of IL‐2, whereas the majority released 1FN‐γ. Given the peculiar phenotypic and functional properties of many CD3 + LAK clones, we suggest that they may belong to a T‐cell subset distinct from typical CTLs.
In the present study, we have characterized the reactivity of two mAbs that are directed at the human TCR-gamma/delta. These reagents, designated anti-A13 and anti-TiV delta 2, were found to recognize antigenic determinants encoded by the TCR V delta 1 and V delta 2 gene segments, respectively. Immunofluorescence analyses performed with the antibodies confirmed that, in the TCR-gamma/delta+ cell subpopulation, the expression of V delta 2+ delta chains is largely predominant, as compared with the V delta 1+ counterparts. However, these experiments led to an apparently discrepant finding. Indeed, the total number of cells recognized by the anti-A13 plus the anti-TiV delta 2 antibodies was often greater than that detected with anti-TCR-delta 1, a reagent specific for a constant epitope of the human delta chain. Further investigation showed that the presence of a sizeable peripheral lymphocyte subset coexpressing the BMA031 and the A13 epitopes. Because the former antibody is known to recognize an invariant antigenic determinant of the TCR-alpha/beta dimer, these results suggested that the V delta 1 gene segment may be expressed with either C delta or C alpha. This hypothesis was confirmed using T2, an IL-2-dependent BMA031+ A13+ polyclonal cell line developed from peripheral blood of a healthy adult donor. Indeed, T2 cells were found to have productively rearranged the V delta 1 gene. Together, results of Northern blot analysis and cDNA cloning indicated that V delta 1 was expressed in these cells as part of a 1.6-kb full-length message including J alpha-C alpha segments.
In these studies we investigated the phenotypic and functional characteristics of human rIL 2-activated killer cells (LAK). By FACS sorting we separated PBL into Leu-11- and Leu-11+ cell fractions and cultured them for 4 days in 100 U/ml rIL 2. Under these culture conditions, cells of the Leu-11+ fraction acquired a stronger LAK activity against fresh autologous or allogeneic melanoma cells as compared with Leu-11- cells or unfractionated PBL. To better characterize the cells responsible for this cytolytic activity, we directly cloned Leu-11+ and Leu-11- FACS-sorted cells in the presence of 1% PHA, irradiated spleen feeder cells, and rIL 2. From 6 to 10% of the Leu-11+ cells and from 42 to 66% of the Leu-11- cells plated gave rise to clonal progenies that were tested simultaneously for cytolytic activity against fresh melanoma cells and NK-sensitive K562 target cells in a 4-hr 51Cr-release assay. Most of the Leu-11+ microcultures lysed fresh melanoma target cells (35 out of 38 and 26 out of 34 in two separate experiments), whereas only a few clones derived from the Leu-11- cell fraction had this capability (four out of 45 and one out of 41). All the clones lysing fresh melanoma cells also efficiently killed K562 target cells, whereas other clones lysing only K562 could be found among Leu-11+ and Leu-11- clones. Nine clones expressing LAK activity were tested for their reactivity against a panel of different tumor target cells. All clones were able to lyse a broad panel of target cells including NK-sensitive and NK-resistant cultured or noncultured human tumor target cells, as well as mouse tumor cell lines. Surface marker analysis of 14 clones displaying LAK activity, all derived from Leu-11+ cells, showed that they were all T3 (CD3)-, whereas 10 out of 14 expressed the T11 (CD2) antigen and only four were weakly stained by an anti-T8 (CD8) mAb. All 14 clones expressed the T40 (CD7) T cell marker and DR and LFA-1 antigens. Cytolysis inhibition experiments performed on a rIL 2-activated Leu-11+ population and on two LAK cell clones, both expressing T11 antigen, showed that anti-LFA-1 but not anti-T11 mAb could inhibit cytolysis of freshly derived tumor target cells.
Most mature T lymphocytes express CD3-associated antigen receptor molecules (TCR) formed by alpha and beta chains. Recently, a minor subset has been identified that express a different CD3-associated TCR composed of gamma and delta chains. The cell subset expressing TCR gamma/delta differs from conventional T cells in a number of phenotypic and functional characteristics. The simultaneous lack of both CD4 and CD8 antigens at the cell surface allows one to greatly enrich for TCR gamma/delta + cells (by monoclonal antibodies, mAbs and complement). Cloning of CD4-8- peripheral blood lymphocytes revealed that they are homogeneously composed of cytolytic cells which, in most instances, lyse tumor target cells. TCR gamma/delta + cells proliferated in response to allogeneic cells in mixed lymphocyte culture (MLC) and MLC-derived TCR gamma/delta + cells specifically lysed PHA-induced blast cells bearing the stimulating alloantigens, thus providing the formal proof that they recognize (allo)antigens. The use of different mAbs specific for TCR gamma/delta molecules allowed us to identify two distinct subsets which bound BB3 and delta-TCS-1 mAbs, respectively. The BB3-reactive molecules in peripheral blood-derived TCR gamma/delta + cells were represented by C gamma 1-encoded disulphide-linked heterodimers, whereas delta-TCS-1 reacted with C gamma 2-encoded non disulphide-linked molecules. Both BB3 and delta-TCS-1 mAb induced activation of cloned cells expressing the corresponding antigenic determinants (as assessed by measurements of intracellular Ca++ and/or lymphokine production or cytolytic activity).(ABSTRACT TRUNCATED AT 250 WORDS)
In this report we describe the precursor frequency and the subset distribution of peripheral blood human T cells producing lymphokine(s) acting on the proliferation and differentiation of bone marrow precursors of the granulocyte/macrophage series, as assessed in a liquid microculture assay. Because the sensitivity of this system was similar to that of the classic colony formation assay in semi-solid (methylcellulose) medium, it is likely that the lymphokine activity measured in this assay corresponds to the colony-stimulating factor (CSF) activity. Single human T lymphocytes, isolated from peripheral blood by E rosetting and Ficoll-Hypaque gradients, were seeded into microculture wells by limiting dilution or micromanipulation techniques and were incubated under culture conditions that allow clonal expansion of essentially all T cells. After 15 to 20 days, microcultures were stimulated with PHA and CSF activity was assayed in culture supernatants 24 hr thereafter. About 45% (1/2.3) of peripheral blood T cells were found to give rise to CSF-producing progenies. Moreover, when fluorescence-activated cell sorter-purified T4+ and T4- (or T8- and T8+) were analyzed, the frequency of the precursors of CSF-producing cells was 1/1.5 in the T4+ subset, whereas approximately one-third of the T8+ cells had this functional potential. To additionally characterize T cells responsible for CSF production, unfractionated T cells as well as T4+ and T4- cells were cloned by single cell micromanipulation. The resulting clones were analyzed simultaneously for the production of IL 2, production of CSF and for cytolytic activity in a lectin-dependent assay. It was found that 25/48 clones obtained from unfractionated T cells produced CSF, whereas 23/48 and 19/48 produced IL 2 or had cytolytic activity respectively. Six of the 25 CSF-producing clones had only this functional capability, whereas the remaining clones in addition displayed cytolytic activity (4/25), IL 2 production (10/25), or both (5/25). A similar functional heterogeneity was observed among T4+ and T4- clones, thus indicating that T cells producing CSF are functionally heterogeneous within both the T4+ and T8+ subsets.
