Esterase Release Research Articles

Cytotoxic T-lymphocyte interaction with fibronectin and vitronectin: activated adhesion and cosignalling.

Stimulation of cloned cytotoxic T lymphocytes (CTL) with anti-T-cell receptor (TCR) monoclonal antibody (mAb) in solution resulted in rapid and sustained activation of adhesion to immobilized fibronectin (FN) but did not initiate degranulation. Addition of a second antibody (Ab) to further cross-link the TCR substantially increased the level of adhesion and also activated degranulation, as measured by release of serine esterase, in the presence of immobilized FN but not in its absence. Thus, binding to FN can provide a costimulatory signal to activate degranulation. TCR cross-linking also activated CD8-dependent adhesion to class I, and CD8 provided a costimulatory signal upon binding to class I. However, the requirements for activating adhesion and generating the costimulatory signal differed significantly for FN versus class I ligand, suggesting that these two receptor-ligand systems do not share a common mechanism of action. Co-immobilizing FN and alloantigen resulted in increased serine esterase release in comparison with that stimulated by antigen alone, and required the FN and class I be on the same surface. Peptide and antibody blocking demonstrated that CTL binding to FN, and to vitronectin (VN), was mediated by the alpha V beta 3 vitronectin receptor (VNR). Thus, VNR is activated by a signal from the TCR to mediate adhesion to FN or VN, and delivers a costimulatory signal for degranulation via a different mechanism than costimulation by CD8 binding to class I.

The Role of Phorbol Ester-Sensitive Protein Kinase C Isoforms in Lymphokine-Activated Killer Cell-Mediated Cytotoxicity: Dissociation between Perforin-Dependent and Fas-Dependent Cytotoxicity

Treatment of lymphokine-activated killer (LAK) cells with phorbol ester (PMA) caused the downmodulation of LAK activity concomitantly with the inhibition of serine esterase (SE) release, which has been shown as a marker for perforin-dependent cell-mediated cytotoxicity. The reduction of perforin-dependent LAK activity by PMA-treatment appeared to be due to the disappearance of PMA-sensitive protein kinase C (PKC) isoforms such as PKCα, γ, ϵ, θ. In contrast, Fas-mediated LAK activity was refractory against PMA-induced downregulation. Treatment of LAK cells with PMA caused a disappearance of cytotoxicity against Fas−L5178Y tumor cells, while cytotoxicity against Fas+transfectants was not affected by PMA treatment. Moreover, Fas-mediated LAK activity of perforin-knockout mice was not inhibited by PMA treatment. These results clearly demonstrated that Fas-mediated cytotoxicity could be dissociated from perforin-mediated cytotoxicity by their different requirement of PMA-sensitive PKC isoforms.

2-Chloroadenosine Stimulates Granule Exocytosis from Mouse Natural Killer Cells: Evidence for Signal Transduction through a Novel Extracellular Receptor

The effect of 2-chloroadenosine (2CA), an adenosine receptor agonist, on the activation status of mouse natural killer (NK) cells was determined. Splenic lymphocytes incubated with 2CA exocytosed an NK cell-associated granzyme withNα-CBZ-L-lysine thiobenzyl ester (BLT) esterase activity in a dose- and timedependent manner. Selective depletion of NK cells by anti-asialoGM1 antibody plus complement pretreatment confirmed that NK cells were the source of the BLT esterase activity. 2CA-induced granule exocytosis was not reduced in the presence of the nucleoside uptake blockers NBTI, dilazep, or dipyridamole, indicating the involvement of an extracellular receptor. However, adenosine or other A1, A2, or A3cell-surface adenosine receptor agonists failed to trigger the exocytotic process. Furthermore, the nonselective adenosine receptor antagonist theophylline, as well as the selective A1receptor antagonist DPCPX and the selective A2receptor antagonist DMPX, did not interfere with 2CA-induced BLT esterase secretion. These data suggest that 2CA acts on NK cells via a novel (non-A1/A2/A3) cell-surface receptor. Genistein, a protein tyrosine kinase inhibitor, and calphostin C, a protein kinase C inhibitor, both interfered with 2CA-induced granule exocytosis. Pertussis toxin, an ADP-ribosylating toxin to which certain GTP-binding proteins are sensitive, also inhibited 2CA-stimulated BLT esterase release. In addition, 2CA-induced granule exocytosis was reduced in the presence of cyclosporin A, an inhibitor of Ca2+-dependent signaling pathways, and the Ca2+-chelating agent EGTA . We conclude that 2CA, acting through a novel extracellular receptor on mouse NK cells, triggers granule exocytosis via a Ca2+-dependent signal transduction pathway that is coupled to GTP-binding proteins and involves protein tyrosine kinase and protein kinase C activation.

Differential sensitivity of resting and IL-2 activated NK cells to R-verapamil.

Natural killer (NK) cells are the first lymphoid population to reconstitute the peripheral blood compartment of immunologically compromised bone marrow transplant (BMT) recipients. Recent data suggest that, among patients transplanted for leukemia, NK cells can prevent or delay disease relapse by mediating a cytotoxic graft vs leukemia (GvL) response. Although the major mechanism by which NK cells mediate target cell lysis involves degranulation and release of cytolytic effector molecules (granzymes, proteoglycans, perforin), accumulating evidence suggests that NK cells possess additional pathways to mediate target cell killing. In fact, it is well recognized that recombinant cytokines such as IL-2 enhance the in vitro cytolytic activity of NK cells. In this study, we observed that the lytic activity mediated by resting and IL-2 activated NK cells against the same target cell appears to occur via two distinct pathways, as distinguished by their differential response to R-verapamil. Specifically, we observed that 25 microM R-verapamil inhibited the lytic activity of resting NK cells against K562 targets by approximately 50%. However, the lytic activity of IL-2 activated NK cells was unaffected by this concentration of R-verapamil. Additional studies suggested that the inhibitory effect of R-verapamil on NK cytotoxic activity was associated with its ability to prevent degranulation of cytotoxic granules. Specifically, R-verapamil inhibited BLT esterase release from resting but not IL-2 activated NK cells. These data suggest that IL-2 activated NK cells can promote target cell lysis by a pathway (possibly degranulation independent) distinct from that used by resting NK cells. We speculate that the target of R-verapamil on resting NK cells is P-glycoprotein (Pgp), an ABC transporter that we recently reported was expressed on NK cells and whose functional activity is known to be inhibited by R-verapamil.

Partial signaling by CD8+ T cells in response to antagonist ligands.

Structural variants of an agonist peptide-major histocompatibility complex (MHC) molecule ligand can show partial agonist and/or antagonist properties. A number of such altered ligands appear to act as pure antagonists. They lack any detectable ability to induce T cell effector function and have been described as unable to induce calcium transients and turnover of inositol phosphates. This has been interpreted as an inability of these ligands to initiate any T cell receptor (TCR)-dependent signal transduction, with their antagonist properties ascribed to competition with offered agonist for TCR occupancy. Yet antagonists for mature CD8+ T cells can induce positive selection of thymocytes, implying active induction of T cell differentiation events, and partial agonists or agonist/antagonist combinations elicit a distinctive pattern of early TCR-associated tyrosine phosphorylation events in CD4+ T cells. We have therefore directly examined proximal TCR signaling in a CD8+ T cell line in response to various related ligands. TCR engagement with natural peptide-MHC class I agonist resulted in the same pattern of early TCR-associated tyrosine phosphorylation events as seen with CD4+ cells, including accumulation of both the p21 and p23 forms of phosphorylated zeta, phosphorylation of CD3 epsilon, and association of phosphorylated ZAP-70 with the TCR. Two antagonists that lacked the ability to induce any detectable CTL effector response (cytolysis, esterase release, gamma interferon secretion, interleukin-2 receptor alpha upregulation) were nevertheless found to also induce TCR-dependent phosphorylation events. In these cases, there was preferential accumulation of the p21 form of phospho-zeta without net phosphorylation of CD3 epsilon, as well as the association of nonphosphorylated ZAP-70 kinase with the receptor. These data show that variant ligands induce similar TCR-dependent phosphorylation events in CD8+ T cells as first observed in CD4+ cells. More importantly, they demonstrate that some putatively pure antagonists are actually a subset of partial agonists able to induce intracellular biochemical changes through the TCR. This delivery of a partial signal by antagonists raises the possibility that antagonism in some cases may result from active interference with stimulation of effector activity by agonist in mature T cells, while the same variant signal could selectively trigger intracellular events that allow positive without negative selection in thymocytes.

Selective activation of Fas/Fas ligand-mediated cytotoxicity by a self peptide.

To study how MHC-associated self antigens may regulate the function of T cells in the periphery, we generated CD8+ T cell lines specific for a single residue variant of a self peptide. The self peptide (GAYEFTTL) was isolated from H-2-Kb class I MHC molecules immunopurified from tumor cells. CD8+ CTL lines from H-2b mice were generated against a variant peptide, pE4R, (arginine for glutamic acid at the TCR contact position 4). In short-term 51Cr-release assays, these CTL lysed H-2Kb targets that were pulsed with picomolar levels of pE4R but did not lyse target cells coated with the self peptide at micromolar levels. However, in overnight assays the CTL lysed Fas-positive target cells in the presence of nanomolar levels of the self peptide. This killing was shown to be entirely Fas/Fas ligand mediated by blocking with anti-Fas antibody and Fas-Fc chimeric molecules. While the self peptide was unable to induce serine esterase release from the CTL, it did induce secretion of IFN-gamma. By these criteria then, the unmodified self ligand served as a partial agonist for the CTL raised against a single-residue variant. CD8+ T cell lines raised by in vitro stimulation with the self peptide were likewise unable to kill self peptide-coated targets via the perforin pathway but did lyse targets via Fas. These and similar data from other groups show that self antigens (i.e., MHC/peptide complexes) may be recognized by mature peripheral T cells. The T cell population is tolerant of the self antigen in the sense that they do not respond to physiological levels of the MHC/peptide complex. However, when the level of self antigen is increased (by using synthetic peptide loading) CD8+ T cells may respond by proliferation, IFN-gamma secretion, Fas ligand upregulation, and Fas-mediated cytolysis but are still unable to respond by perforin-mediated cytolysis or granzyme release. The physiological significance of such partial activation in regulation of the immune system remains to be demonstrated.

Involvement of Two Distinct Killing Mechanisms in Bystander Target Cell Lysis Induced by a Cytotoxic T Lymphocyte Clone

Cytotoxic T lymphocyte (CTL) can lyse target cells by mainly two different mechanisms including granule exocytosis- and Fas-based cytotoxicity. In addition, CTL also lyse bystander target cells. In this study, we examined whether these two different killing mechanisms also cause bystander target cells lysis. EL-4 cells, representing bystander target cells, were incubated with CD8+CTL clone B7B7 and antigen-treated P815 cells. EGTA–MgCl2inhibited bystander lysis and reduced the release of BLT esterase. In addition, lysis of Fas-negative bystander cells (thymocytes from C57BL/6J-lpr/lprnot expressing Fas antigen) was also detected. CTL preactivated with antigen-treated P815 cells maintained a killing activity on bystander cells in the presence of cycloheximide (CHX). Furthermore, the presence of anti-Fas mAb inhibited the lysis of EL-4 cells by CTL stimulated with anti-TCR mAb. Thus, our results suggest that granule exocytosis- and Fas-mediated signal pathways cause the lysis of bystander target cells.

Alpha and beta chemokines induce NK cell migration and enhance NK-mediated cytolysis.

Chemokines have been shown to play an important role in both the adhesion and migration of numerous leukocytic cell types, including granulocytes, monocytes, mast cells, and T lymphocytes. However, the biologic effects of chemokines on NK cells remain to be defined. Chemotaxis studies using purified human NK cells and a panel of human recombinant chemokines revealed that macrophage inflammatory protein (MIP)-1 alpha and IFN-inducible protein-10 (IP-10) are potent NK cell chemoattractants in vitro. Modest but significant chemotactic (not chemokinetic) responses were also observed in response to RANTES, MCP-1, MCP-2, MCP-3, and MIP-1 beta. Chemokine receptor expression on human NK cells was determined through displacement and Scatchard analyses, using a panel of radiolabeled chemokines, and revealed the presence of both distinct and shared chemokine receptors with affinities similar to those previously described for other cell types. Functional studies have also revealed that the beta chemokines and IP-10 are capable of augmenting NK- but not LAK- or ADCC-specific cytolytic responses in both a dose- and donor-dependent fashion. Neutralization analysis using Abs specific for various adhesion molecules revealed that NK:tumor cell conjugate formation is required for chemokine-induced NK killing. In addition, NK cells incubated in the presence of beta chemokines and IP-10 for 4 h induced the release of granule-derived serine esterases, suggesting a possible mechanism for chemokine-mediated NK killing. These results suggest that chemokines not only play an important role in the recruitment of NK cells, but also may be important mediators of NK cell degranulation augmenting local tumor cell destruction.

T cell receptor γδ repertoire is skewed in cerebrospinal fluid of multiple sclerosis patients: molecular and functional analyses of antigen‐reactive γδ clones

To study the relevance of gamma delta T cells in multiple sclerosis (MS) we analyzed the T cell receptor (TCR) gamma delta repertoire and the antigen reactivity of gamma delta clones isolated from cerebrospinal fluid (CSF). In T cell cultures derived from CSF we found an increased percentage of V delta 1+ cells as compared to peripheral blood of the same donors. Phenotypic analysis of cells from MS CSF with V gamma- and V delta-specific monoclonal antibodies (mAb) showed that the V delta 1 chain is most frequently associated with gamma chains belonging to the V gamma 1 family. Sequence analysis of TCR genes revealed heterogeneity of junctional regions in both delta and gamma genes indicating polyclonal expansion. gamma delta clones were established and some recognized glioblastoma, astrocytoma or monocytic cell lines. Stimulation with these targets induced serine esterase release and lymphokine expression characteristic of the TH0-like phenotype. Remarkably, these tumor-reactive gamma delta cells were not detected in the peripheral blood using PCR oligotyping, but were found in other CSF lines independently established from the same MS patient. Altogether, these results demonstrate that in the CSF there is a skewed TCR gamma delta repertoire and suggest that gamma delta cells reacting against brain-derived antigens might have been locally expanded.

The inhibitory effect of FK506 on cytotoxic T-lymphocyte killing

The immunosuppressant FK506 inhibits N-α- benzyloxylcarbonyl- l-lysine thiobenzyl ester (BLT) esterase release from cytotoxic T lymphocytes (CTL). In addition, serine esterase has been demonstrated to be strongly associated with CTL killing. In the present study, the effect of FK506 on the activity of CTL killing against target cells was examined. FK506 inhibited lysis of antigen (Ag)-treated CTL target cells by auto-CTL, but failed to inhibit lysis of conventional P815 target cells by CTL. Moreover, FK506 inhibited DNA fragmentation of CTL target cells lysed by auto-CTL. Killing of CTL target cells by FK506-pretreated auto-CTL was inhibited, but FK506-pretreated CTL target cells were killed by auto-CTL. Incubation of both FK506 and Ag-pretreated CTL target cells with untreated auto-CTL induced DNA fragmentation. These indicated that FK506 inhibited CTL killing by influencing effector, but not CTL target cells. These results suggest that FK506 may function by inhibiting alloreactive CTL killing in organ transplantation in addition to the interruption of the T-cell receptor signal transduction leading to cytokine production.

Chronic Morphine Treatment Suppresses CTL-Mediated Cytolysis, Granulation, and cAMP Responses to Alloantigen

Exposure to opioid drugs (e.g., morphine) in vivo has been shown to suppress natural killer cell activity. However, the effects of in vivo exposure to opioids on cytotoxic T lymphocyte (CTL) activity has not been investigated. The administration of morphine (50.0 mg/kg, sc) to alloimmunized mice for II days resulted in a significant decrease in peritoneal and splenic CTL activity. Moreover, the intracellular content of serine esterases and esterase release by CD8+ effector cells from chronic morphine-treated mice was reduced compared to that of effector cells from vehicle-treated controls. In addition, the CD8+ cAMP response to alloantigen was diminished compared to CD8+-enriched cells from vehicle-treated animals. However, conjugate formation between effector and target and subsequent killing of target by effector cells did not reveal significant differences between vehicle- and chronic morphine-treated animals. Serum corticosterone and dehydroepiandrosterone levels were significantly lower in the chronic morphine-treated animals while proopiomelanocortin gene expression (exon 3) in splenic lymphocytes did not correlate with morphine-mediated suppression of CTL activity. These results indicate that CTL activity is sensitive to chronic morphine exposure, implicating opioids as important cofactors during viral infections in suppressing cell-mediated immunity.

Hyaluronate is costimulatory for human T cell effector functions and binds to CD44 on activated T cells.

Lymphohematopoiesis, cell matrix adhesion, homing of leukocytes, T cell activation, and tumor metastasis are mediated through the CD44 family of cell surface receptors. We have recently shown that anti-CD44 mAb trigger protein tyrosine kinase-dependent activation of T cell effector functions. Here, we show that hyaluronate (HA), a CD44 ligand, in conjunction with CD3/TCR-mediated stimuli, is costimulatory for human peripheral blood T cell proliferation, for IL-2 production by Th clones, and for release of trypsin-like esterase by cytolytic T cell clones. A human T cell line, HUT-78, was found to bind HA and on HA coating it was used as a target for cytolytic T cell clones. After anti-CD3 stimulation, CD3+/CD8+ clones acquire the ability of lysing HA-coated HUT-78 cells more efficiently than the same HA-uncoated targets. Resting peripheral blood T cells and T cell clones do not adhere to HA-coated plates. However, 24-h anti-CD3 mAb stimulation gives them the transient ability to bind HA. HA adhesion of activated T cells and T cell clones, as well as that of T cell lines, is blocked by one anti-CD44 mAb (J-173). Two other anti-CD44 mAbs induce a 10-fold increase in HA adhesiveness of anti-CD3-stimulated peripheral blood T cells. This impressive HA adhesiveness is also readily blocked by J-173 anti-CD44 mAb. These data indicate that 1) HA is costimulatory for human T cell effector functions in conjunction with CD3/TCR-mediated stimuli, 2) the capacity to bind HA is acquired by resting T cells and T cell clones after anti-CD3 stimulation, and 3) HA binding occurs via specific interaction with CD44 molecules expressed on activated T cells.

Effect of prostaglandin E 2 on cytotoxic activity and granzyme a protease release by murine adherent IL-2 activated killer cells

The effects of prostaglandin E 2 (PGE 2) have been studied on a highly purified population of murine IL-2 activated killer cells obtained by selecting plastic-adherent splenocytes (AK cells) after incubation with high doses of recombinant IL-2. AK cells were highly cytotoxic for YAC-1 target cells. The cytotoxic activity was detectable at one hour after initiation of the cytotoxic assay and then increased with time. Cytotoxic activity of AK cells was inhibited by the addition of PGE 2 or forskolin during the cytotoxic assay. When AK cells were generated in the presence of PGE 2, the yielding cytotoxic activity was lower than the one expressed by «regular» AK cells but were insensitive to the inhibitory effect of PGE 2 even if their lytic capability was still suppressed by forskolin. The presence of PGE 2 during the AK cell culture had no effect on the cellular proliferation. Moreover, using tetrazolium-based colorimetric assay which reflects the cellular activation, it was observed that AK cells cultured in presence of PGE 2 had an increased capacity to cleave the tetrazolium salt to formazan. Since the cytotoxic activity of killer cells is related to expression of serine esterase enzymes we evaluated the effects of PGE 2 on serine esterase (Granzyme A) release after one hour of incubation of AK cells either alone or in presence of PGE 2, YAC-1 cells or both. We observed that (i) AK cells spontaneously release granzyme A, (ii) the level of granzyme A was significantly increased when AK cells were incubated either with YAC-1 cells or PGE 2 but did not change when YAC-1 cells and PGE 2 were both associated with AK cells.

Target cell-directed degradation of perforin mRNA in CTL: Lack of correlation with loss of protein and lytic ability

We have previously shown that CTL and NK cells rapidly down regulate perforin mRNA and become functionally inactive within 4–6 hr after exposure to sensitive target cells (TC). We report here for the first time that CTL also down regulate perforin mRNA upon exposure to resistant, but binding, TC. When three separate human MHC-restricted CTL lines were exposed to resistant TC, perforin mRNA was rapidly degraded. Removal of both extracellular Ca ++ and Mg ++ prevented perforin message down regulation, whereas removal of Ca ++ alone did not, indicating that CTL:TC binding was required. Unlike the response of CTL exposed to sensitive TC, resistant TC did not trigger serine esterase (SE) release, suggesting distinct signalling pathways for perforin mRNA down regulation and granule exocytosis. Moreover, using western analysis, we showed that there was limited (< 10%) perforin protein release after CTL:TC interaction, suggesting that CTL loss of lytic activity after exposure to sensitive TC is not due to massive depletion of perforin. Treatment of CTL with mAb to CD2, CD3, CD2 + CD3, CD8, Class I and LFA-1 did not induce perforin mRNA down regulation. Furthermore, mAb to CD2, CD3, CD8, Class I, Class II, CD54 and LFA-1 did not block TC-mediated perforin mRNA down regulation although lysis of TC was inhibited.

Phorbol ester-induced reversible inactivation of cytotoxic T cell function: correlation with down-regulation of protein kinase C activity.

When an H-2d-specific cytotoxic T lymphocytes (CTL) clone, FC1, was incubated in the presence of 10(-7) M phorbol myristate acetate (PMA) for 10-12 hr, the cytolytic activity of the CTL against H-2d target cells was abrogated, but was reversibly restored to the normal level after subsequent incubation of the cells in PMA-free medium for more than 10 hr. These effects of PMA have been reported (Russell, J.H.: J. Immunol. 133, 907-912 (1984)), but the mode of its action has not been fully investigated. Here, we analyzed the biochemical basis of the PMA-induced loss of cytolytic activity. Cycloheximide completely blocked the restoration of the PMA-suppressed cytolytic activity, suggesting that protein synthesis was required in this process. PMA-treatment did not affect the levels of CD3 and CD8 molecules expressed on the CTL, nor was the level of a CTL-specific serine esterase, BLT esterase, affected by this treatment. However, the target cell-induced release of BLT esterase from the CTL was suppressed if the cells were pretreated with PMA. PMA-treatment of the CTL led to the down-regulation of protein kinase C (PKC) activity by about 50%. On the other hand, staurosporin, an inhibitor of PKC, completely blocked the target cell lysis when added at 10(-6) M. These results suggest that the down-regulation of at least some isoform(s) of PKC is responsible for the PMA-induced loss of the cytotolytic activity of CTL.

Clone-specific T cell receptor antagonists of major histocompatibility complex class I-restricted cytotoxic T cells.

A previous report showed that the proliferative response of helper T cells to class II major histocompatibility complex (MHC)-restricted antigens can be inhibited by analogues of the antigen, which act as T cell receptor (TCR) antagonists. Here we define and analyze peptide variants that antagonize various functions of class I MHC-restricted cytotoxic T lymphocyte (CTL) clones. Of 64 variants at individual TCR contact sites of the Kb-restricted octamer peptide ovalbumin257-264 (OVAp), a very high proportion (40%) antagonized lysis by three OVAp-specific CTL clones. This effect was highly clone specific, since many antagonists for one T cell clone have differential effects on another. We show that this inhibition of CTL function is not a result of T cell-T cell interaction, precluding veto-like phenomena as a mechanism for antagonism. Moreover, we present evidence for direct interaction between the TCR and antagonist-MHC complexes. In further analysis of the T cell response, we found that serine esterase release and cytokine production are susceptible to TCR antagonism similarly to lysis. Ca2+ flux, an early event in signaling, is also inhibited by antagonists but may be more resistant to the antagonist effect than downstream responses.

Cholera toxin inhibits lethal hit stage of natural killer cell-mediated cytotoxicity.

Cytolytic process which was affected by cholera toxin (CT) resulting in the loss of natural killer (NK) cell activity was analyzed. Conjugate formation assay, membrane phospholipid methylation assay and serine esterase (granzyme A) release assay were used to determine the stage of the CT-induced inhibition of NK cell-mediated cytotoxicity. A human NK cell line YT cell-mediated cytotoxicity was completely abolished by CT pretreatment or addition of CT to the assay system. The conjugate formation assay revealed that the binding between YT cells and target cells was not affected by CT. The defined triggering stage which is coupled with membrane phospholipid methylation was not affected by CT treatment, either. On the other hand, the lethal hit stage which is represented by serine esterase (SE) release was completely inhibited by CT treatment of YT cells. Therefore, CT inhibits the stage after binding and triggering--i.e., lethal hit stage of NK cell-mediated cytotoxicity. The results also suggest that there exists a CT-sensitive negative cytotoxic signal transduction pathway as well as usual positive signal transduction pathway and these pathways might cross talk each other in the NK cell cytotoxic process.

Intestinal intraepithelial lymphocytes are activated and cytolytic but do not proliferate as well as other T cells in response to mitogenic signals.

Compared with T lymphocytes from other organs, intestinal intraepithelial lymphocytes (IEL) proliferate weakly in response to CD3/TCR ligation, and they do not respond at all to treatment with other mitogenic stimuli. These signals also failed to induce expression of the IL-2R alpha-chain on the surface of most IEL. IEL from germ-free mice, from V gamma 1.1-transgenic mice, and from beta 2-microglobulin-deficient mice also gave a weak proliferative response. Therefore, the low proliferative response is not linked to the level of exposure to gut bacterial flora, the V gamma region expressed by the TCR-gamma delta + IEL, or the presence of class I molecules that may be recognized by CD8+ IEL. The relatively small amount of proliferation in response to TCR signaling, therefore, is not likely to be the result of induction of anergy caused by previous contact with Ag. In contrast, ligation of the CD3/TCR complex could elicit a rapid cytotoxic response and serine esterase release by IEL. The unusual functional capabilities and the activation state of IEL are independent of the TCR isotype expressed by these cells. Freshly isolated IEL have a high intracellular microtubule-associated protein kinase-2 (MAP-2K) activity level, further suggesting that these cells are activated despite their weak proliferative response. Consistent with this, MAP-2K is tyrosine-phosphorylated in both untreated and PMA-treated IEL. In contrast, MAP-2K activation and tyrosine phosphorylation occur in other T cells only when they are activated by PMA or other treatments. MAP-2K activity also is elevated in IEL from germ-free mice, demonstrating that activation does not depend on normal levels of exposure to bacterial flora. The activation of protein kinases such as MAP-2K could reflect the differentiation state of IEL or Ag receptor stimulation of some of these cells by epithelial cells in the preparation.

Herpes virus saimiri-transformed human T lymphocytes: normal functional phenotype and preserved T cell receptor signalling.

Herpes virus saimiri (HVS), a primate herpes virus, transforms human CD4+ and CD8+ T lymphocytes to continuous growth in vitro. We have previously shown that HVS-transformed human T cells (HVS-T cells) respond to stimulation via CD2 with autocrine growth. In the present study we have investigated the functional characteristics of HVS-T cells. We describe that these cells can perform all the functions of normal T cells, i.e. cytokine secretion, cytotoxicity, and exocytosis of granule esterases. All these activities can be triggered via CD2 by binding to its natural ligand or via the TCR, e.g. by anti-TCR antibodies, by recognition of a bacterial superantigen and by MHC-restricted recognition of specific antigen. The pattern of tyrosine-phosphorylated proteins after TCR triggering was identical in HVS-T cells and normal T cells. We conclude that HVS-T cells can respond to TCR-mediated signals with the functions of normal T lymphocytes. Furthermore, HVS-T cells are the only transformed human T cells that can be specifically triggered by cytotoxicity and esterase release. The finding that the TCR functions normally in these cells will make HVS a convenient means to immortalize antigen-specific human T lymphocytes.

Expression of perforin in murine natural killer cells and cytotoxic T lymphocytes in vivo.

We have previously detected perforin expression in a subpopulation of asialo GM1+ natural killer (NK) cells and CD8+ T lymphocytes in murine spleen cells by immunocytochemical staining with an anti-perforin monoclonal antibody. In the present study, more detailed analyses of perforin expression in murine cytotoxic lymphocyte subpopulations were performed. The expression of perforin in asialo GM1+ spleen cells was predominantly confined to the NK1.1+ subset, where all NK activity also resided. Perforin expression was also studied on alloreactive cytotoxic T lymphocyte (CTL) induced in vivo. The cells expressing perforin in peritoneal exudate lymphocytes predominantly resided in the CD8+ T cell subpopulation co-expressing asialo GM1 where an allospecific CTL activity also resided. Furthermore, the percentage of perforin-positive cells in this population was greatly reduced after stimulation with anti-CD3 or anti-T cell receptors antibodies, which induce serine esterase release from the cytoplasmic granules. These findings highly suggest that perforin is involved in in vivo NK cell- and CTL-mediated cytolysis.