Regulation of cytolytic activity in CD3- and CD3+ killer cell clones by monoclonal antibodies (anti-CD16, anti-CD2, anti-CD3) depends on subclass specificity of target cell IgG-FcR

Anti-CD3 MAb can inhibit MHC-restricted cytolytic activity of CD3+ mature cytotoxic T cells. In particular effector-target cell combinations, however, anti-CD3 MAb enhance or induce cytolysis by cross-linking CD3+ effector and IgG-FcR+ target cells. Virtually all natural killer (NK) cells or NK cell-derived clones are CD3-4-8- but do express CD2 and CD16 (IgG-FcR) antigens. We have studied how these cell surface molecules are involved in the regulation of cytolytic activities. The addition of anti-CD2 MAb to effector and target cells was found to induce conjugate formation of the IgG-FcR+ target cells with the effector cell and nonspecific cytolysis of, for instance, the P815 mouse mastocytoma cells. Enhancement or induction of conjugate formation and cytolysis of IgG-FcR+, P815, U937, and Daudi cells was also accomplished by using anti-CD16 MAb (e.g., Leu-11c (B73.1) or CLB Fc-gran 1 (VD2) MAb). Some human and mouse tumor cell lines (K562, P815, and U937) appear to express distinct types of IgG-FcR, showing different affinities for distinct subclasses of MAb (e.g., IgG1, IgG2a), but another line (Daudi) expresses only one type of IgG-FcR preferentially binding IgG1 MAb. Here we demonstrate that IgG-FcR on the effector cells can act as activation sites because anti-CD3 as well as anti-CD16 MAb of IgG1 and IgG2a subclasses can induce lytic activity of target cells bearing the relevant IgG-FcR. These data demonstrate that induction of conjugate formation and cytolysis by MAb occur when the target cells bear IgG-FcR with "specificity" for those MAb. Thus, besides via CD3, cytolytic activity by mature T and NK cells also can be induced via the CD2 and CD16 antigens on these cells.     

Anti-CD3 and phorbol myristate acetate regulation of MHC unrestricted T cell cytotoxicity. Lack of a requirement for CD3/T cell receptor complex expression during tumor cell lysis

The effects of anti-CD3 mAb on MHC-unrestricted cytotoxic activity of NK depleted PHA-activated human T cells were examined. Anti-CD3 mAb had variable effects on killing of K562 or Daudi targets. Whereas lower concentrations of OKT3 often inhibited lysis of either target, higher concentrations (greater than 1 micrograms/ml) frequently increased K562 killing and always augmented Daudi lysis. However, lysis of the renal cell carcinoma, Cur, was consistently inhibited by OKT3 over a broad concentration range. Such variable effects were not related to differential regulation of heterogeneous subsets of effector cells, as similar patterns of OKT3-mediated modulation of tumor cell lysis by T cell clones was also observed. Another IgG2a anti-CD3 mAb, 64.1, and either F(ab')2 fragments of OKT3 or intact OKT3 in the presence of aggregated human Ig were found to inhibit lysis of Cur, K562, and Daudi targets consistently. Additional experiments were carried out to determine whether modulation of CD3 accounted for the inhibitory effects of the anti-CD3 mAb. PMA was noted to cause modulation of CD3 from the surface of PHA or alloantigen-activated T cells, and the combination of anti-CD3 and PMA caused even more marked modulation of CD3. Whereas preincubation with PMA and/or anti-CD3 decreased alloantigen-specific cytotoxic T cell function in relative proportion to the loss of CD3 expression, no consistent relationship between CD3 expression and the capacity of PHA-activated T cells to kill Cur targets was noted. PMA alone caused no consistent alteration of Cur lysis. Moreover, in the presence of PMA, anti-CD3 mAb caused no significant inhibitory effect on Cur lysis, in spite of increased modulation and in some cases virtual total loss of surface CD3 expression. These findings indicate that when FcR interactions are prevented, anti-CD3 mAb consistently inhibit MHC-unrestricted cytotoxicity by PHA-activated T cells. Despite this, the data support the conclusion that CD3/TCR complex interactions with target cells are not required for either target cell recognition or triggering of lysis by MHC-unrestricted cytotoxic T cells.     

Induction of lysis by T cell receptor gamma delta+/CD3+ T lymphocytes via CD2 requires triggering via the T11.1 epitope only

The requirements for activation of the lytic machinery through CD2 of TCR gamma delta+/CD3+ cells were examined, by utilizing bispecific heteroconjugates containing anti-CD2 mAb cross-linked to anti-DNP. Contrary to the CD2 activation requirements in TCR alpha beta+/CD3+ cells, cytotoxic activity in TCR gamma delta+/CD3+ clones and TCR-/CD3- NK cell clones can be induced by heteroconjugates containing a single anti-CD2 (OKT11.1) mAb. Activation of TCR gamma delta+/CD3+ cells via CD2 is independent of heteroconjugates binding to CD16 (Fc gamma RIII), because heteroconjugates prepared from Fab fragments induced equal levels of lysis. Moreover, anti-CD16 mAb did not inhibit triggering via CD2 in TCR gamma delta+/CD3+ cells. In TCR-/CD3- NK cells, however, induction of cytotoxicity via CD2 is co-dependent on interplay with CD16. Anti-CD3 mAb blocked the anti-CD2 x anti-DNP heteroconjugate-induced cytotoxicity of TCR gamma delta+/CD3+ cells, indicating a functional linkage between CD2 and CD3 on these cells. We conclude that induction of lysis via CD2 shows qualitatively different activation requirements in TCR gamma delta+/CD3+, TCR alpha beta+/CD3+ CTL and TCR-/CD3- NK cells.     

Lysis of tumor cells by CD3+4-8-16+ T cell receptor alpha beta- clones, regulated via CD3 and CD16 activation sites, recombinant interleukin 2, and interferon beta 1

A small subpopulation (about 2%) of normal CD3+ human T lymphocytes lacks both CD4 and CD8 antigens. We have cloned these cells from peripheral blood lymphocytes (PBL) obtained from healthy individuals and from a patient with severe combined immunodeficiency. Six out of seven CD3+4-8-clones exert strong cytolytic activity against a variety of so-called NK-susceptible and -nonsusceptible tumor target cells. Their target cell specificity spectrum can virtually be as wide as that of CD3-NK cell-derived clones, with strong lytic capacity. Some of these clones also exert antibody-dependent cellular cytotoxicity (ADCC), a characteristic of NK cell-derived clones but not of CD3+4+ or CD8+ mature T cell-derived clones. Such CD3+ T cell clones do not express the CD16 (IgG Fc receptor) antigen, but as we demonstrate here, the CD16 antigen can be identified on CD3+4-8-clones. Both ADCC activity and CD16 antigen expression are lower in CD3+4-8- than in CD3- NK cell clones. Lytic activity of mature CD3+4+ or CD8+ and CD3- NK cell clones can be augmented, respectively, by anti-CD3 or anti-CD16 monoclonal antibodies (MAb), but that of CD3+4-8- clones are augmented by both MAb. Lytic activity of CD3+4+ or CD8+ clones is considerably enhanced after 3 hr of incubation with recombinant IL 2, as found for CD3- NK cells. Enhancement of lytic activity of allospecific CD3+4+ or CD8+ clones requires 18 hr of incubation. Thus, CD3+4-8-16+ cells share several features with CD3- NK cells. However, they express the CD3 antigen, which is characteristic for CD4+ or CD8+ mature T cells. Our results also indicate that although CD3+4-8- clones react with five preparations of anti-CD3 MAb tested, these clones do not express a classical CD3+/Ti alpha, beta antigen receptor complex. This is suggested by the finding that the CD3+4-8- clones do virtually not express the common epitope of the T cell receptor alpha, beta-chains as identified by the WT31 MAb. These CD3+4-8- lymphocytes may represent functionally mature lymphocytes of a distinct T cell subpopulation having a particular immune function.     

Normal hematopoietic progenitor cells and malignant lymphohematopoietic cells show different susceptibility to direct cell-mediated MHC-non-restricted lysis by T cell receptor-/CD3-, T cell receptor gamma delta+/CD3+ and T cell receptor-alpha beta+/CD3+ lymphocytes

To evaluate the capability of NK cells and cytotoxic T lymphocytes to interact with normal hematopoietic progenitor cells (HPC), as compared to neoplastic lymphohematopoietic cells, we investigated inhibition of colony growth of these cell populations in semi-solid culture systems, after incubation with cloned cytotoxic effector cells. Three different types of cloned effector cells were investigated: TCR-/CD3- NK cells, TCR-gamma delta+/CD3+ cells, and TCR-alpha beta+/CD3+ cytotoxic T lymphocytes. Effector cells showed differential levels of tumor cell colony inhibition, but no MHC-non-restricted lysis of normal HPC was observed. Pre-stimulation of normal HPC by culturing on established stromal layers had no effect. Cell-mediated lysis of HPC only occurred by Ag-specific MHC-restricted lysis by CTL, or by antibody-dependent cellular cytotoxicity. In cell mixing experiments, irradiated tumor cells, but not normal bone marrow cells inhibited tumor cell lysis. Furthermore, cloned effector lymphocytes were able to specifically eliminate malignant cells from tumor contaminated bone marrow without damaging normal HPC. When fresh leukemic cells were used as targets, growth of acute myeloblastic leukemia colonies was inhibited after incubation with several cytotoxic effector clones, whereas chronic myeloid leukemia precursor cells showed limited sensitivity to MHC-non-restricted cytolysis. These results indicate that MHC-non-restricted cytolysis by NK cells is selectively directed against neoplastic cells and not against normal HPC.     

c-myc gene expression and interleukin-2 receptor levels in cloned human CD2+,CD3+ and CD2+,CD3- lymphocytes

The levels of c-myc mRNA and interleukin-2 receptors (IL-2 Rec) were studied in human peripheral blood lymphocytes (PBL); mature CD2+,CD3+ T cell clones and CD2+,CD3- natural killer (NK) cell clones, and CD2+,CD3+ and CD2-,CD3- T lymphoma cell lines. A transient induction of the expression of c-myc and IL-2 Rec was observed in PBL after activation with phytohemagglutinin (PHA). Expression of c-myc and IL-2 Rec was also found in the CD2+,CD3+ and CD2+,CD3- clones. The CD2+,CD3+ showed higher levels of c-myc mRNA and IL-2 Rec than the CD2+,CD3- clones. In three T lymphoma cell lines constitutively high levels of c-myc mRNA but no IL-2 Rec were found. Only in JURKAT (CD2+,CD3+), c-myc mRNA levels could be further enhanced by PHA. These results suggest that in the presence of PHA, expression of c-myc and IL-2 Rec is induced via the CD3 receptor, and in the absence of PHA and/or the CD3 receptor alternative routes of induction are involved.     

Phenotypic and functional analysis of murine CD3+,CD4-,CD8- TCR-gamma delta-expressing peripheral T cells

Murine CD3+,CD4-,CD8- peripheral T cells, which express various forms of the TCR-gamma delta on their cell surface, have been characterized in terms of their cell-surface phenotype, proliferative and lytic potential, and lymphokine-producing capabilities. Three-color flow cytofluorometric analysis demonstrated that freshly isolated CD3+,CD4-, CD8- TCR-gamma delta lymph node cells were predominantly Thy-1+,CD5dull,IL-2R-,HSA-,B220-, and approximately 70% Ly-6C+ and 70% Pgp-1+. After CD3+,CD4-,CD8-splenocytes were expanded for 7 days in vitro with anti-CD3-epsilon mAb (145-2C11) and IL-2, the majority of the TCR-gamma delta cells expressed B220 and IL-2R, and 10 to 20% were CD8+. In comparison to CD8+ TCR-alpha beta T cells, the population of CD8+ TCR-gamma delta-bearing T cells exhibited reduced levels of CD8, and about 70% of the CD8+ TCR-gamma delta cells did not express Lyt-3 on the cell surface. Functional studies demonstrated that splenic TCR-gamma delta cells proliferated when stimulated with mAb directed against CD3-epsilon, Thy-1, and Ly-6C, but not when incubated with an anti-TCR V beta 8 mAb, consistent with the lack of TCR-alpha beta expression. In addition, activated CD3+,CD4-,CD8- peripheral murine TCR-gamma delta cells were capable of lysing syngeneic FcR-bearing targets in the presence of anti-CD3-epsilon mAb and the NK-sensitive cell line, YAC-1, in the absence of anti-CD3-epsilon mAb. Finally, activated CD3+, CD4-,CD8-,TCR-gamma delta+ splenocytes were also capable of producing IL-2, IL-3, IFN-gamma, and TNF when stimulated in vitro with anti-CD3-epsilon mAb.     

Identification of the anti-CD3-unresponsive subpopulation of CD4+, CD45RA+ peripheral T lymphocytes.

The majority of peripheral CD4+ T lymphocytes proliferate in vitro in response to anti-CD3 in presence of autologous APC. The present study describes a subpopulation of CD4+ T cells that cannot be activated and progress into cell cycle by stimulation with anti-CD3 plus APC or with mitogenic combinations of anti-CD2. The in vitro responses of these anti-CD3-unresponsive CD4+ T cells were investigated with a panel of mAb to CD2, CD3, and CD28, and found to be similar to those previously observed for mature thymocytes: only the combination of anti-CD2 plus anti-CD28 produced cell proliferation. Anti-CD3-unresponsive T cells were CD45RA+, but represented only 14 to 22% of the CD4+, CD45RA+ T cell population. Activation with anti-CD2 plus anti-CD28 mAb resulted in major changes in the cell surface phenotype and functional properties: a loss of CD45RA+ occurred and an increased expression of CD45RO, CD29, and CD58 (LFA3), as well as a gain in responsiveness to anti-CD3 and anti-CD2. This change in CD45 phenotype from CD45RA to CD45RO occurs in both the anti-CD3-responsive and in the anti-CD3-unresponsive subsets of the CD45RA+, CD4+ cells after cell proliferation. The anti-CD3-unresponsive subset may represent a pool of not yet fully differentiated peripheral T cells. The acquisition of anti-CD3 responsiveness could occur as a consequence of Ag priming or by an Ag-independent mechanism. Involvement of the CD28 Ag in this process is suggested from the present study.     

NK1.1+ thymocytes. Adult murine CD4-, CD8- thymocytes contain an NK1.1+, CD3+, CD5hi, CD44hi, TCR-V beta 8+ subset.

CD4-, CD8- thymocytes were purified from thymi obtained from normal C57BL/6 mice. By flow cytometry analysis, 5 to 10% of these double negative (DN) thymocytes were found to express NK1.1 on their surface. The NK1.1+ DN thymocytes were demonstrated, by two-color fluorescence, to be CD3lo, CD5hi, CD44hi, J11d-, B220-, MEL 14-, IL2R- with 60% expressing TCR-V beta 8 as determined by the mAb F23.1. In contrast, splenic and peripheral blood NK cells were NK1.1+, CD3-, CD5-, TCR-V beta 8- with 40 to 60% being MEL 14+. Unlike peripheral NK cells, fresh DN thymocytes enriched for NK1.1+ cells were unable to kill YAC-1, the classical murine NK cell target. However, these cells were able to mediate anti-CD3 redirected lysis even when they were assayed immediately after purification, i.e., with no culture or stimulation. These data demonstrate that adult murine thymocytes contain NK1.1+ cells which are distinct, both by function and phenotype, from peripheral NK cells. These data also raise the issue of a possible NK/T bipotential progenitor cell.     

Role of CD2 in regulation of CD3- LGL function.

CD2 is a differentiation marker present on T cells and NK cells. Cytotoxic T lymphocytes (CTL) can be activated by antibodies directed against the CD3/T-cell receptor complex and CD2 structures; however, the role of CD2 in regulation of CD3- large granular lymphocyte (LGL) functions has only recently been studied. Anti-CD2 monoclonal antibodies (mAbs) may be either augmenting or inhibitory and T-cell activation via the CD2 molecule occurs only when mAb binds defined combinations of the CD2 epitopes. Since LGL can be activated by a single stimulus (e.g., IL-2) to proliferate, produce IFN gamma, and increase their cytolytic potential, these functions were chosen to examine the effects of the anti-CD2 mAb and its combinations. Anti-CD2 mAb (D66, GT2, and X11-1) were incubated with LGL for various times in the absence or presence of IL2 and IFN gamma production was monitored. Single anti-CD2 mAb treatment demonstrated minimal augmentation of IFN gamma production. However, combinations of anti-CD2 (9.6) and the other anti-CD2 mAb resulted in a significant, synergistic enhancement of the IFN gamma production. Anti-CD2 mAb treatment appeared to inhibit production generated by optimal doses of IL-2 (1,000 U/ml). The effect of anti-CD2 mAb on IFN gamma production parallel their effects on LGL NK and LAK activity. These data suggested that mAb against the CD2 molecule were important in regulating LGL functions in the absence of a functional CD3 receptor in LGL.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of the CD45 (T-200) molecule in anti-CD3-triggered T cell-mediated cytotoxicity

NK-depleted human peripheral blood lymphocytes can be modulated with anti-CD3 to kill certain targets during 3-hr cytotoxicity assays. When triggered by anti-CD3 antibody, these effector T cells killed only NK-sensitive targets, such as K562 and HEL 92.1.7, and NK-resistant targets, such as Daudi, whose killing is inhibited by anti-CD45 (T-200) monoclonal antibodies, such as 13.3. NK-sensitive targets, MOLT-4, U266/AF10, Jurkat, and CCFR-CEM, and 10 NK-resistant cell lines, including Raji, IM-9, U698, U937, and GM-1056, whose killing is not inhibited by anti-CD45 monoclonal antibodies, were not killed by alpha-CD3-T effectors, suggesting that the CD45 molecule may be involved in the killing process. Anti-CD3-triggered T cell killing of target cells was inhibited greater than 95% by the monoclonal antibody 13.3. This inhibition of cytotoxicity by 13.3 was not due to competition of this IgG1 antibody for Fc receptor binding site on the target cell, since the IgG1 monoclonal antibody anti-beta 2-microglobulin did not block cytotoxicity. Single cell assays and calcium pulse assays showed that CD45 is involved in a postbinding, pre-calcium-dependent stage, similar to that shown for NK cytotoxicity. There was a relative shift of importance of different epitopes of CD45 in anti-CD3-T cytotoxicity compared to NK cytotoxicity. Anti-CD45 antibodies which bind to the C terminus end of the molecule played a more important role in anti-CD3-T cytotoxicity than NK cytotoxicity. Thus, a subset of T cells exists that exhibits anti-CD3-triggered non-MHC-restricted killing of certain NK-sensitive and NK-resistant targets in association with a CD45 molecule which is functionally different from the NK CD45 molecule.     

CD16 on human gamma delta T lymphocytes: expression, function, and specificity for mouse IgG isotypes.

We examined the expression, the signal transduction capacity and mouse IgG-isotype specificity of CD16 on human gamma delta T cells. CD16 is expressed by the majority of gamma delta T cells in peripheral blood and by part of the gamma delta T cell clones. The amount of CD16 expressed on gamma delta T cell clones varied considerably with passaging of the cells, but was always significantly less than on freshly isolated gamma delta T cells. Like CD16 on CD3- CD16+ natural killer (NK) cells, CD16 on gamma delta T cells can act as an activation site triggering cytotoxic activity. CD16+ gamma delta T cell clones exerted antibody-dependent cellular cytotoxicity (ADCC) which could be blocked by anti-CD16 mAb. ADCC activity of gamma delta T cell clones was also inhibited by anti-CD3 mAb, suggesting a functional linkage between the CD16 and CD3 activation pathways. MAb directed against CD16 induced lysis of Fc gamma R+ target cells by CD16+ gamma delta T cell clones. The mouse IgG-isotype specificity of CD16 on gamma delta T cells was analyzed using isotype switch variants of a murine anti-glycophorin A mAb in EA rosette assays, and was found to be identical to that of CD16 on CD3- CD16+ NK cells, i.e., highest affinity for mIgG2a, intermediate affinity for mIgG2b, and undetectable binding of mIgG1-sensitized erythrocytes. CD16 was partly modulated from the cell surface of both gamma delta T cells and NK cells after rosette formation with mIgG2a-sensitized erythrocytes, indicating that the rosette formation was indeed mediated via the CD16 molecule.     

Interleukin-2 receptor monoclonal antibodies have no effect on anti-CD3 monoclonal antibody-mediated cytotoxicity in CD3+ leukemic large granular lymphocytes

We studied the role of Fc receptors and interleukin-2 (IL-2) receptor subunits in anti-CD3 monoclonal antibody (MAb)-mediated cytotoxicity of CD3+ leukemic large granular lymphocytes (LGL). Peripheral blood mononuclear cells from four patients with CD3+ LGL leukemia were cultured with 1 microgram/ml of anti-CD3 MAb. Anti-CD3 MAb-mediated cytotoxicity was not inhibited when K562 target cells were preincubated with heat-aggregated human IgG, suggesting that binding of the effector cell-bound anti-CD3 MAb to Fc receptors of target was not involved in cytotoxicity. Induction of cytotoxicity was not blocked by the addition of either anti-p55 or anti-p75 IL-2 receptor MAbs. These results show that the induction of cytotoxicity by anti-CD3 MAb is not mediated through IL-2 receptor subunits in CD3+ leukemic LGL.     

Cloned Listeria monocytogenes specific non-MHC-restricted Lyt-2+ T cells with cytolytic and protective activity

Mice were infected with Listeria monocytogenes and Lyt-2+ T cell clones capable of lysing Ag-primed bone marrow macrophages were established. In accordance with earlier findings obtained at the population level, some T cell clones were identified which lysed bone marrow macrophages of different MHC type provided the relevant Ag was present. This unusual target cell recognition was further analyzed using a T3+, L3T4-, Lyt-2+, F23+, KJ16+ T cell clone, designated L-28. Target cell lysis by this clone was Ag specific, apparently non-MHC restricted. In contrast, YAC cells and P815 cells were not lysed by clone L-28. However, lysis of irrelevant targets could be induced by anti-T3, F23, or KJ16 mAb. Furthermore, Ag-specific lysis was blocked by anti-Lyt-2 mAb and by F(ab)2 fragments of F23 mAb. In addition to its cytolytic activity, clone L-28 produced IFN-gamma after co-stimulation with accessory cells, Ag, and rIL-2 and conferred significant protection on recipient mice when given together with rIL-2. These data suggest that non-MHC-restricted Lyt-2+ killer cells generated during listeriosis are cytolytic T lymphocytes that interact with their target Ag via the T cell receptor/T3 complex and the Lyt-2 molecule and, furthermore, that these cells play a role in anti-listerial resistance. The possible relevance of IFN-gamma secretion and target cell lysis for antibacterial protection is discussed.     

Effects of anti-Lyt-2 and anti-L3T4 monoclonal antibodies on the function of cytotoxic T lymphocyte/helper T lymphocyte hybrid T cell clones

CTL/HTL hybrid clones provide a unique system that allows detailed analysis of the role of Lyt-2, L3T4, and other structures involved in T cell functions. We have demonstrated previously that the fusion of cloned murine CTL and helper T lymphocytes with defined specificity generated hybrid cells that expressed both Lyt-2 and L3T4 as well as two TCR. Data obtained with these hybrid clones demonstrated that cytolysis is closely linked to the CTL TCR. We have analyzed the effects of anti-Lyt-2 and anti-L3T4 as well as anti-TCR mAb on cytolysis, proliferation, and lymphokine release by a number of hybrid clones. We found that anti-Lyt-2 and anti-L3T4 mAb were able to inhibit both proliferation and lymphokine release by the hybrid clones in response to stimulation of either the CTL or helper T lymphocyte parent TCR. In contrast, only anti-Lyt-2 and anti-CTL TCR mAb were able to block cytolysis of target cells bearing the Ag recognized by the CTL TCR. These results provide further evidence that cytolysis is closely linked to the CTL TCR and that Lyt-2 and L3T4 have more than a passive role as accessory molecules on the surface of T lymphocytes.     

The immunobiology of T cell responses to Mls-locus-disparate stimulator cells. III. Helper and cytolytic functions of cloned, Mls-reactive T cell lines

Mls-specific T cell clones derived by limiting dilution were tested for cytotoxic activity in a lectin-dependent 51Cr-release assay. All the T cell clones tested were cytotoxic in such an assay in apparent contrast to previous reports. However, only those target cells sensitive to cytolysis by other L3T4a+ cytolytic T cells were killed by Mls-specific T cell clones in short term 51Cr-release assays, possibly explaining this discrepancy. All the T cell clones tested were L3T4a+, Lyt-2- and stimulated B cells from Mlsa,d strains of mice to proliferate and secrete immunoglobulin. Furthermore, lysis of innocent bystander targets was observed when the T cells were stimulated with Mls-disparate stimulator cells. These results are consistent with those obtained with L3T4a+ T cells specific for protein antigen:self Ia and that express cytotoxic potential.     

MHC-unrestricted cytotoxic and proliferative responses of two distinct human gamma/delta T cell subsets to Daudi cells.

Human V gamma 9/V delta 2 T cells, the major subset of gamma/delta T cells in peripheral blood of adults, mediate proliferative and cytotoxic responses to Daudi Burkitt's lymphoma cells without previous in vitro exposure to Daudi. Our experiments show that some gamma/delta T cells coexpressing V gamma 9 and V delta 1 genes also react to Daudi cells in cytotoxic and proliferative assays. Expression of V gamma 9 is not sufficient for the recognition of Daudi cells because most gamma/delta T cells expressing V delta 1 paired with V gamma 9 or other V gamma genes neither kill Daudi cells nor proliferate to Daudi. V gamma 9/V delta 2 T cells do not proliferate to other cell lines such as K562 or Molt4 that are sensitive to MHC-unrestricted cytolysis by NK cells and by most IL-2-activated gamma/delta T cell clones. Cold target inhibition assays demonstrate that Daudi cells are stronger inhibitors than K562 and Molt4 of MHC-unrestricted lysis by V gamma 9/V delta 2 clones. However, cold Daudi cells are relatively weaker inhibitors of MHC-unrestricted lysis by NK cell clones, most gamma/delta T cell clones expressing V delta 1 and alpha/beta T cell clones. Thus, recognition by V gamma 9/V delta 2 T cells and certain V gamma 9/V delta 1 T cells of Daudi appears to involve a specific triggering pathway that is distinct from recognition by these gamma/delta T cells of Molt4, K562, and other target cells. NK cell clones and most other gamma/delta and alpha/beta T cell clones derived from the same normal volunteer blood donors do not show this specific interaction with Daudi cells. These data show that distinct subsets of human gamma/delta T cells recognize Daudi cells and support the idea that the gamma/delta TCR may be directly involved.     

Functional and phenotypic differences between CD4+ and CD4- T cell receptor-gamma delta clones from peripheral blood.

CD4+ TCR-gamma delta+ T cells comprise a very small subset of TCR-gamma delta+ T cells. CD4+ TCR gamma delta+ T cell clones were established to study the phenotypical and functional characteristics of these cells. Thirty-four CD4+ TCR-gamma delta+ T cell clones were established after sorting CD4+ T cells from a pre-expanded TCR-gamma delta+ T cell population. These clones as well as the CD4- TCR-gamma delta+ T cells from the same donor used V gamma 2 and V delta 2. In a second cloning experiment CD4+ TCR-gamma delta+ T cells were cloned directly from freshly isolated TCR-gamma delta+ T cells using a cloning device coupled to a FACS sorter. Forty-three clones were obtained, which all expressed CD4 and TCR-gamma delta. Eleven of these clones used V delta 1 and three of them coexpressed V gamma 2. The other CD4+ TCR-gamma delta+ T cell clones used both V delta 2 and V gamma 2. CD4+ TCR-gamma delta+ T cell clones expressed CD28 irrespective of the V gamma or V delta usage, and were CD11b negative. Three CD4-CD8+ TCR-gamma delta+ clones expressed CD8 alpha but not CD8 beta and were CD11b positive. CD28 expression among CD4-CD8+ and CD4-CD8- was variable but lower than on CD4+ T cell clones. CD4- TCR-gamma delta+ T cell clones using V gamma 2 and V delta 2 specifically lyse the Burkitt lymphoma cell line Daudi and secrete low levels of IFN-gamma and granulocyte-macrophage-CSF upon stimulation with Daudi. In contrast, most CD4+ T cell clones that use V gamma 2 and V delta 2 had a very low lytic activity against Daudi cells and secrete high levels of IFN-gamma and granulocyte-macrophage-CSF after stimulation with Daudi cells. The NK-sensitive cell line K562 was killed efficiently by the CD4- TCR-gamma delta+ T cell clones, but not by CD4+ TCR-gamma delta+ T cell clones, and could not induce cytokine secretion in CD4+ or CD4- T cell clones. CD4+ TCR-gamma delta+ T cell clones, but not the CD4- clones, could provide bystander cognate T cell help for production of IgG, IgM, and IgA in the presence of IL-2 and IgE in the presence of IL-4. Thus, CD4+ TCR-gamma delta+ T cells are similar to CD4+ TCR-alpha beta+ T cells in their abilities to secrete high levels of cytokines and to provide T cell help in antibody production.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of the CD4+ and CD8+ tumor infiltrating lymphocytes propagated with bispecific monoclonal antibodies

To study the CD4+ and CD8+ tumor infiltrating lymphocytes (TIL) in the antitumor response, we propagated these subsets directly from tumor tissues with anti-CD3:anti-CD8 (CD3,8) and anti-CD3:anti-CD4 (CD3,4) bispecific mAb (BSMAB). CD3,8 BSMAB cause selective cytolysis of CD8+ lymphocytes by bridging the CD8 molecules of target lymphocytes to the CD3 molecular complex of cytolytic T lymphocytes with concurrent activation and proliferation of residual CD3+CD4+ T lymphocytes. Similarly, CD3,4 BSMAB cause selective lysis of CD4+ lymphocytes whereas concurrently activating the residual CD3+CD8+ T cells. Small tumor fragments from four malignant melanoma and three renal cell carcinoma patients were cultured in medium containing CD3,8 + IL-2, CD3,4 + IL-2, or IL-2 alone. CD3,8 led to selective propagation of the CD4+ TIL whereas CD3,4 led to selective propagation of the CD8+ TIL from each of the tumors. The phenotypes of the TIL subset cultures were generally stable when assayed over a 1 to 3 months period and after further expansion with anti-CD3 mAb or lectins. Specific 51Cr release of labeled target cells that were bridged to the CD3 molecular complexes of TIL suggested that both CD4+ and CD8+ TIL cultures have the capacity of mediating cytolysis via their Ti/CD3 TCR complexes. In addition, both CD4+ and CD8+ TIL cultures from most patients caused substantial (greater than 20%) lysis of the NK-sensitive K562 cell line. The majority of CD4+ but not CD8+ TIL cultures also produced substantial lysis of the NK-resistant Daudi cell line. Lysis of the autologous tumor by the TIL subsets was assessed in two patients with malignant melanoma. The CD8+ TIL from one tumor demonstrated cytotoxic activity against the autologous tumor but negligible lysis of allogeneic melanoma targets. In conclusion, immunocompetent CD4+ and CD8+ TIL subsets can be isolated and expanded directly from small tumor fragments of malignant melanoma and renal cell carcinoma using BSMAB. The resultant TIL subsets can be further expanded for detailed studies or for adoptive immunotherapy.     

The functional significance, distribution, and structure of LFA-1, LFA-2, and LFA-3: cell surface antigens associated with CTL-target interactions

Three cell surface antigens associated with the cytolytic T lymphocyte(CTL)-target cell interaction were identified by generation of monoclonal antibodies (MAb) against OKT4+, HLA-DR-specific CTL and selection for inhibition of cytolysis in a 51Cr-release assay. These MAb block cytolysis by both OKT4+ and OKT8+ CTL and the proliferative responses to PHA and the mixed lymphocyte response (MLR). LFA-1 is an antigen widely distributed on lymphoid tissues and is composed of two polypeptides of 177,000 and 95,000 Mr on all cell types studied. Anti-LFA-1 MAb block NK cell-mediated cytolysis in addition to T lymphocyte-mediated cytotoxicity and proliferation. LFA-2 (Mr = 55,000 to 47,000), a determinant on the sheep red blood cell receptor, is expressed by T cells but not B cells and appears specific for T cell functions. LFA-3 (Mr = 60,000) is a widely distributed antigen present on both hematopoietic and nonhematopoietic tissues and appears to only be involved in T cell functions. MAb to LFA-1 and LFA-2 inhibit function by binding to effector cell surface molecules, whereas anti-LFA-3 MAb appear to block by binding to the target cells. Together with previously described molecules, LFA-1, LFA-2, and LFA-3 demonstrate the complexity of CTL-mediated cytotoxicity at the molecular level.