Cytolytic activity of Ia-restricted T cell clones and hybridomas: evidence for a cytolytic mechanism independent of interferon-gamma, lymphotoxin, and tumor necrosis factor-alpha

Ten different helper T cell (Th) hybridomas that are specific to Ia or antigen plus Ia were found to express nonspecific cytolytic activity toward the cytotoxin (CT)-resistant P815 cells upon activation with either Con A or a monoclonal anti-T3 antibody (T3-mAb). In contrast to cytolytic Th1 clones which secrete high levels of interferon-gamma (IFN-gamma) and cytotoxin (CT) (lymphotoxin (LT, also known as TNF-beta) or tumor necrosis factor-alpha (TNF-alpha], these Th hybridomas produce low or undetectable levels of IFN-gamma and CT. No inhibitory activity of IFN-gamma and CT was observed in culture supernatants of activated Th hybridomas. Double-chamber experiments demonstrated that CT-sensitive L929 cells when physically separated from activated Th1 clones were killed by membrane-permeable CT. Under identical experimental conditions, lysis of P815 cells did not occur. Moreover, activation of Th hybridomas directly in wells containing the CT-sensitive L929 cells failed to induce target cell lysis. This confirms that these Th hybridomas produce little CT and argues against high local concentrations of CT being responsible for Th hybridoma-mediated killing of P815 cells. Finally, a polyclonal rabbit antiserum to rTNF-alpha, which strongly and specifically inhibited CT-mediated and Th1 clone-mediated killing of L929 cells, failed to inhibit P815 lysis by activated Th1 clones and Th hybridomas. These observations establish that a cytolytic mechanism independent of IFN-gamma, LT, and TNF-alpha is responsible for lysis of CT-resistant target cells.     

Distinct pathways of CD4 and CD8 cells induce rapid target DNA fragmentation.

When activated with either Con A, a CD3-specific mAb, or Ag-pulsed B lymphoma (LK35.2) cells, CD4 (Th1) clones quickly induce DNA fragmentation in target cells followed by release of 51Cr-labeled intracellular materials. Both activated CD4 clones and CD8 (CTL) cells fragment target DNA into electrophoretically identical "ladder" pattern made of approximately 200 bp. The effect of various metabolic inhibitors on the ability of CD4 and CD8 cells to induce target DNA fragmentation was studied. Little effect was observed with the DNA synthesis inhibitor, mitomycin C. The RNA synthesis inhibitor, actinomycin D, and the protein synthesis inhibitor, cycloheximide, strongly inhibited the ability of CD4 cells, but not CD8 cells, to induce target DNA fragmentation. In contrast, target DNA fragmentation by CD8 cells, but not by CD4 cells, was inhibited by cholera toxin. Although cyclosporin A inhibited CD4 cells to fragment target DNA during the early phase (90 min) of E:T interaction, this inhibition was not sustained in the later phase (210 min) of the assay. Zinc ions inhibited the ability of both CD4 and CD8 cells to fragment target DNA. Treatment of effectors and targets with these inhibitors, followed by washings, demonstrated that the action of these inhibitors on effector cells alone is sufficient to inhibit target DNA fragmentation. The strong correlation among these parameters of DNA fragmentation and Cr-release assays supports the hypothesis of programed cell death. Although distinct cytolytic pathways are used by CD4 and CD8 cells to kill targets, both pathways deliver a signal that activates endonuclease(s), fragments target DNA, causes Cr-release, and lyses target cells. Taken together with our previous studies, the present findings demonstrate that activated cytolytic CD4 clones do not use perforin, serine proteases, and TNF as mediators for resistant target DNA fragmentation.     

Cytolysis of tumor necrosis factor (TNF)-resistant tumor targets. Differential cytotoxicity of monocytes activated by the interferons, IL-2, and TNF

Herein we demonstrate that IFN-alpha, IFN-gamma, and IL-2 can induce human peripheral blood monocyte-mediated lysis of tumor cells that are resistant to both the direct effects of TNF and to monocytes activated by TNF. Monocytes activated by TNF kill only TNF-sensitive tumor targets, whereas those activated by IFN and IL-2 can lyse both TNF-sensitive and TNF-resistant tumor targets. Monocyte cytotoxicity against TNF-sensitive lines induced by the IFN, IL-2, or TNF can be completely abrogated by the addition of anti-TNF antibodies. In contrast, anti-TNF antibodies have no effect on IFN- or IL-2-induced monocyte cytotoxicity against TNF resistant targets, confirming non-TNF-mediated lysis induced by lymphokine-activated monocytes. Neither induction of TNF receptors by IFN-gamma nor inhibition of RNA synthesis by actinomycin D increased the susceptibility of TNF-resistant tumor targets to TNF-mediated monocyte cytotoxicity. Thus, non-TNF-mediated modes of monocyte cytotoxicity are induced by IFN and IL-2, but not by TNF, indicating that different cytotoxic mechanisms are responsible for the lysis of TNF-sensitive and TNF-resistant tumor cells. In addition, these findings also suggest that TNF-sensitive lines are susceptible only to TNF-mediated killing and apparently insensitive to non-TNF-mediated monocyte cytotoxicity.     

IL-4 and IFN (alpha and gamma) exert opposite regulatory effects on the development of cytolytic potential by Th1 or Th2 human T cell clones.

The cytolytic potential of a total number of 118 CD4+ human T cell clones specific for purified protein derivative (PPD) from Mycobacterium tuberculosis, tetanus toxoid, Lolium perenne group I allergen (Lol p I), Poa pratensis group IX allergen (Poa p IX), or Toxocara canis excretory/secretory antigen(s) (TES) was assessed by both a lectin (PHA)-dependent and a MHC-restricted lytic assay and compared with their profile of cytokine secretion. The majority of clones with Th1 or Th0 cytokine profile exhibited cytolytic activity in both assays, whereas Th2 clones usually did not. There was an association between the cytolytic potential of T cell clones and their ability to produce IFN-gamma, even though IFN-gamma produced by T cell clones was not responsible for their cytolytic activity. IL-4 added in bulk culture before cloning inhibited not only the differentiation of PPD-specific T cells into Th1-like cell lines and clones, but also the development of their cytolytic potential. The depressive effect of IL-4 on the development of PPD-specific T cell lines with both Th1 cytokine profile and cytolytic potential was dependent on early addition of IL-4 in bulk cultures. In contrast, the addition in bulk culture of IFN-gamma enhanced both the cytolytic activity of PPD-specific T cell lines, as well as the proportion of PPD-specific T cell clones with cytolytic activity. The addition in bulk cultures before cloning of IFN-gamma or IFN-alpha favored the development of TES-specific and Poa p IX-specific T cells into T cell clones showing a Th0 or even a Th1, rather than a Th2, cytokine profile. Accordingly, most of TES- and Poa p IX-specific T cell clones derived from cultures containing IFN-gamma or IFN-alpha displayed strong cytolytic activity. These data indicate that the majority of human T cell clones that produce IFN-gamma, but not IL-4 (Th1-like), as well as of T cell clones that produce IFN-gamma in combination with IL-4 (Th0-like) are cytolytic. More importantly, they demonstrate that the addition of IFN (alpha and gamma) or IL-4 in bulk cultures before cloning may influence not only the cytokine profile of human CD4+ T cell clones but also their cytolytic potential.     

Expression of the tumor necrosis factor locus is not necessary for the cytolytic activity of T lymphocytes

In order to test whether tumor necrosis factors alpha (TNF-alpha) or beta (TNF-beta, also known as lymphotoxin) are involved in the lysis of target cells by cytolytic T lymphocytes, we probed for the presence of the TNF mRNAs in several quiescent and activated CTL clones. No TNF mRNA could be found in constitutively cytolytic Lyt-2+ clones, and only two out of three clones tested accumulated TNF mRNA after stimulation with phorbol myristate acetate and ionomycin. Of two L3T4+ clones that can be induced to become cytolytic by a combination of antigen and IL-1, only one accumulated TNF-beta mRNA in the process. The PC60 rat X mouse T cell hybrid, which becomes cytolytic in response to a combination of IL-1 and IL-2, also failed to accumulate TNF mRNA after stimulation with these agents. Our results strongly suggest that TNF-alpha or -beta are not necessary agents of the cytolytic activity exhibited by antigen-specific T lymphocytes.     

Production of TNF-alpha and TNF-beta by staphylococcal enterotoxin A activated human T cells

Staphylococcal enterotoxin at concentrations of less than 1 pg/ml induces significant TNF activity in human peripheral blood T cells and monocytes. Maximal TNF activity is routinely detected after 48 to 72 h of culture. IL-2 and IL-4 were both growth promoting for human T cells but only IL-2 could efficiently induce TNF production. The production of TNF-alpha and TNF-beta differed greatly in kinetics. An early intracytoplasmatic production of TNF-alpha after 6 h was detected in both monocytes and T cells whereas a late production of TNF-beta (lymphotoxin) after 48 h, occurred in the T cell population. Induction of TNF-alpha and TNF-beta production by Staphylococcal enterotoxin requires the presence of both monocytes and T cells. The CD4+45R- but not CD4+45R+ and CD8+ cells supported TNF-alpha production in monocytes. The main lytic component from Staphylococcal enterotoxin-activated mononuclear cells is TNF-beta. CD4+ and CD8+ T cells produced about equal amounts of biologically active TNF into the culture supernatants but a fourfold higher frequency of TNF-beta producing cells was demonstrated among CD4+ vs CD8+ cells. The CD4+45R- T cell subset was an efficient producer of TNF-beta and IFN-gamma whereas the CD4+45R+ T cell subset produced significant amounts of TNF-beta but only marginal amounts of IFN-gamma.     

Multiple cytolytic mechanisms displayed by activated human peripheral blood T cell subsets.

It has been proposed that CTL-mediated cytotoxicity may involve multiple lytic mechanisms. We have examined both the antibody-redirected cytolytic potential and the direct cytotoxicity of purified human peripheral blood high buoyant density CD4+ and CD8+ T cells activated with IL-2 and anti-CD3 mAb. TNF-sensitive and TNF-resistant targets and various metabolic inhibitors were used to compare the antibody-redirected cytotoxicity of T cell subsets and discern the role of potential lytic mediators. In a 4-h assay against several different nitrophenyl-modified targets, the heteroconjugated antibody (anti-CD3-anti-nitrophenyl) redirected cytolytic potential of 72-h activated CD4+ T cells was inhibited by the continuous presence of actinomycin D, cycloheximide, and EGTA, but not mitomycin C, cyclosporin A, or cholera toxin (CT). Conversely, only CT and EGTA inhibited the antibody-redirected cytolytic potential of activated CD8+ T cells. Despite both CD4+ and CD8+ T cell subsets expressing granzymes, pore-forming protein, TNF-beta, and TNF-alpha, these T cell subsets displayed distinct pathways of antibody-redirected lysis against TNF-sensitive and TNF-resistant targets, even in the presence of anti-TNF antibodies. In addition, these same effector T cell subsets were also directly cytotoxic (in the absence of heteroconjugated antibody) against TNF-sensitive targets in an 18-h assay. Indeed, this direct cytotoxicity was completely abrogated by anti-TNF-alpha antibody and was sensitive to the metabolic inhibitors (cyclosporin A, CT, cycloheximide, and actinomycin D), all of which blocked CD4+/CD8+ T cell TNF-alpha production. Therefore, both CD4+ and CD8+ T cells were demonstrated to utilize antibody and lymphokine-mediated lytic mechanisms. CD4+ and CD8+ effector subsets were demonstrated to lyse the same TNF-sensitive target by these two different mechanisms. Although it cannot be excluded that the redirected lytic mechanisms of both CD4+ and CD8+ effectors share common elements, it is likely that other important events in this cytolytic process are fundamentally distinct between these subsets of T cells.     

Ox40 costimulation enhances the development of T cell responses induced by dendritic cells in vivo.

Dendritic cells (DCs) are bone marrow-derived APCs that display unique properties aimed at stimulating naive T cells. Several members of the TNF/TNFR families have been implicated in T cell functions. In this study, we examined the role that Ox40 costimulation might play on the ability of DCs to regulate CD4(+) and CD8(+) T cell responses in vivo. Administration of anti-mouse Ox40 mAb enhanced the Th response induced by immunization with Ag-pulsed DCs, and introduced a bias toward a Th1 immune response. However, anti-Ox40 treatment enhanced the production of Th2 cytokines in IFN-gamma(-/-) mice after immunization with Ag-pulsed DCs, suggesting that the production of IFN-gamma during the immune response could interfere with the development of Th2 lymphocytes induced by DCs. Coadministration of anti-Ox40 with DCs during Ag rechallenge enhanced both Th1 and Th2 responses induced during a primary immunization with DCs, and did not reverse an existing Th2 response. This suggests that Ox40 costimulation amplifies an ongoing immune response, regardless of Th differentiation potential. In an OVA-TCR class II-restricted adoptive transfer system, anti-Ox40 treatment greatly enhanced the level of cytokine secretion per Ag-specific CD4(+) T cell induced by immunization with DCs. In an OVA-TCR class I-restricted adoptive transfer system, administration of anti-Ox40 strongly enhanced expansion, IFN-gamma secretion, and cytotoxic activity of Ag-specific CD8(+) T cells induced by immunization with DCs. Thus, by enhancing immune responses induced by DCs in vivo, the Ox40 pathway might be a target for immune intervention in therapeutic settings that use DCs as Ag-delivery vehicles.     

Functional heterogeneity among human inducer T cell clones

Analysis of mouse CD4+ inducer T cells at the clonal level has established that a dichotomy among CD4+ T cell clones exists with regard to types of lymphokines secreted. Mouse T cell clones designated Th1 have been shown to secrete IL-2 and IFN-gamma, whereas T cell clones designated Th2 have been shown to produce IL-4 but not IL-2 or IFN-gamma. To determine if such a dichotomy in the helper inducer T cell subset occurred in man, we examined a panel of human CD4+ helper/inducer T cell clones for patterns of lymphokine secretion and for functional activity. We identified human T cell clones which secrete IL-4 but not IL-2 or IFN-gamma, and which appeared to correspond to murine Th2 clones. In marked contrast to murine IL-2 secreting Th1 clones which do not produce IL-4 or IFN-gamma, we observed that some human T cell clones secrete IL-2, and IFN-gamma as well as IL-4. Southern blot analysis indicated that these multi-lymphokine-secreting clones represented the progeny of a single T cell. IL-4 secretion did not always correlated with enhanced ability to induce Ig synthesis. Although one T cell clone which secreted IL-2, IL-4, and IFN-gamma could efficiently induce Ig synthesis, another expressed potent cytolytic and growth inhibitory activity for B cells, and was ineffective or inhibitory in inducing Ig synthesis. These results indicate that although the equivalent of murine Th2 type cells appears to be present in man, the simple division of T cells into a Th1 and Th2 dichotomy may not hold true for human T cells.     

Cytolytic mechanisms of activated macrophages. Tumor necrosis factor and L-arginine-dependent mechanisms act synergistically as the major cytolytic mechanisms of activated macrophages

We examined the cytolytic mechanisms of activated macrophages by using proteose peptone- or thioglycollate broth-induced mouse peritoneal macrophages or mouse macrophage hybridomas as effector cells, L.P3 cells, a clone of L929 cells, and P815 cells as target cells, and IFN-gamma and LPS as activators. It was determined that TNF is the main cytolytic molecule against L.P3 cells from the following results: 1) activated macrophages can produce TNF; 2) TNF shows cytotoxic activity against L.P3 cells; 3) the addition of anti-TNF antibody inhibited most of the cytolytic activity of activated macrophages against L.P3 cells. On the other hand, it was concluded that the main cytolytic mechanism against P815 cells is the production of NO2-/NO3- from L-arginine, from the following results: 1) activated macrophages can produce NO2-; 2) NaNO2 shows high cytotoxic activity against P815 cells; 3) the depletion of L-arginine from the medium inhibited most of the cytolytic activity of activated macrophages against P815 cells and NO2- production by activated macrophages. In this study, however, cytostatic effects of L-arginine-dependent effector mechanism were not studied. Thus, these results show that activated macrophages can express at least two cytolytic mechanisms independently, namely, the one that appears to be mediated by the L-arginine-dependent effector mechanism and the second that appears to be mediated directly by TNF. Furthermore, it was demonstrated that TNF and L-arginine-dependent NO2- production act synergistically as killing mechanisms of activated macrophages. These mechanisms can explain the cytolytic activity of activated macrophages against a variety of target cells.     

The requirements for triggering of lysis by cytolytic T lymphocyte clones. II. Cyclosporin A inhibits TCR-mediated exocytosis by only selectively inhibits TCR-mediated lytic activity by cloned CTL

TCR-mediated granule exocytosis, as measured by the release of serine esterase activity, has been implicated in the lytic process of Ag-specific CTL. Exocytosis appears to be the mechanism of release of other lysis-relevant molecules including cytotoxic lymphokines and proteins that have the capacity to induce membrane lesions as measured by the hemolysis of non-nucleated SRBC. In the studies presented here, we assessed the contribution of exocytosis and lymphokine production in CTL lysis of nucleated and non-nucleated target cells by using a panel of murine CTL clones. Ag-mediated activation of cytolysis, lymphokine production, and exocytosis could be mimicked by mAb against the TCR/CD3 complex, or by stimulation with the combination of PMA + calcium ionophore, which appear to bypass the TCR (neither PMA nor calcium ionophore alone induced these functions efficiently in our CD8+ CTL clones). Although lysis, IFN-gamma production and exocytosis of N-alpha-benzyloxycarbonyl-L-lysin esterase (BLTE) activity were induced by either stimulus, we were able to identify distinct activation requirements for each of these functions. We found that lymphokine production, exocytosis, and cytolysis could be selectively inhibited. Cycloheximide inhibited IFN-gamma production, but did not inhibit exocytosis of BLTE activity or cytolysis. In addition we showed that cyclosporine A (CsA) profoundly inhibited IFN-gamma production as well as exocytosis induced by stimulation through the Ag receptor or by PMA + calcium ionophore. In contrast, CsA had little or no effect on lysis of nucleated target cells that bear the relevant Ag. These findings indicate that our CTL clones can lyse target cells by a mechanism independent of exocytosis or (de novo) lymphokine production. To directly assess the capacity of our CTL clones to lyse target cells without inducing nuclear damage we developed a system of coating non-nucleated SRBC with anti-CD3 mAb for use as stimuli and as targets for lysis. We found that our cloned CTL were indeed activated to produce IFN-gamma by SRBC that were coated with anti-CD3 mAb, and, furthermore, they were able to lyse the SRBC in a short term cytolytic assay. Thus our CD8+ CTL are capable of lysing certain target cells by a mechanism independent of DNA degradation, presumably by inducing a membrane lesion. In addition, CsA did inhibit lysis of the non-nucleated SRBC targets as well as exocytosis of BLTE activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Involvement of prostaglandin-producing pathway in the cytotoxic action of tumor necrosis factor.

To elucidate the cytotoxic mechanism of tumor necrosis factor (TNF), we isolated TNF-resistant sublines of L929 cells. As compared with L929 cells, TNF-resistant cells retained similar number and affinity of TNF-binding sites, and showed a similar growth rate. TNF stimulated arachidonate release from L929 cells, while no stimulation was observed at all in TNF-resistant cells tested. The cytotoxic action of TNF on L929 cells was inhibited by indomethacin, suggesting that prostaglandin may be involved in the action. Therefore, TNF-stimulated prostaglandin production was examined in L929 and TNF-resistant sublines. The amount of PGE2 produced by L929 cells was increased more than 5-fold after the addition of TNF, whereas the amount of PGE2 did not change in the resistant sublines following addition of the factor. TNF-stimulated arachidonate release and PGE2 production were reversed by islet-activating protein (IAP)-treatment of L929 cells. These results suggest that arachidonate release and subsequent prostaglandin production are important for the cytotoxic action of TNF and that these processes are mediated by GTP-binding protein (G protein) that is coupled to the TNF-receptor.     

Role of tumor necrosis factor-alpha in E1A oncogene-induced susceptibility of neoplastic cells to lysis by natural killer cells and activated macrophages

NIH-3T3 cells transfected with adenovirus E1A oncogene cDNA were found to exhibit cytolytic susceptibility to murine NK cells and activated macrophages associated with a threshold level of oncogene product expression exceeding that required for morphological transformation. A similar correlation was observed between threshold levels of E1A gene product expression and target cell susceptibility to direct cytotoxicity by rTNF. Inhibition of splenic NK cell and peritoneal macrophage cytolysis by antisera specific for murine rTNF confirmed the importance of E1A-induced TNF susceptibility as one determinant of target cell cytolytic susceptibility. Anti-TNF antibody was, however, unable to block killing of E1A-expressing targets by the NK cell line, NKB61A2. These results suggest a direct link between the functions of E1A oncogene products and cellular mechanisms of action of TNF elaborated by host effector cells and indicate that E1A expression also affects target cell susceptibility to TNF-independent cytolytic mechanisms.     

Stimulation of macrophage antibody-dependent killing of tumor targets by recombinant lymphokine factors and M-CSF

Macrophage colony-stimulating factor (M-CSF) was investigated as a stimulator of ADCC to the murine R1.1 thymoma target by murine peritoneal exudate macrophages which were elicited by proteose peptone. Both an 125IUdR release and a viable cell count assay were used. The latter assay avoids radiation damage, and the fate of the targets can be determined over a long period. Pretreatment of macrophages for several days in culture with lymphokine (LK) from concanavalin A-induced mouse spleen cells moderately stimulated ADCC. Preincubation of macrophages with conventional or recombinant human M-CSF or immunoaffinity-purified mouse M-CSF alone had little effect. However, M-CSF greatly enhanced ADCC to the tumor target when used as a costimulant with LK, IFN-gamma, IFN-alpha, IFN-beta, or IL-2 to pretreat macrophages. Incubation of macrophages with LK or LK plus M-CSF for 2 days generated stronger ADCC than 1- or 3-day incubations. Enhancement of LK-stimulated ADCC by M-CSF appeared to plateau at about 1000 U/ml. The enhancement of macrophage cytotoxicity when stimulated with IFNs or IL-2 was most effective at the lowest active concentration of these LKs. At 1 U/ml IFN-gamma or IL-2, or 5 U/ml IFN-alpha or IFN-beta, M-CSF boosted ADCC activity to that using 10-fold of the LK alone. IL-1, IL-4, and TNF had little or no stimulating activity for ADCC alone or with M-CSF, and the other hemopoietic growth factors IL-3 and GM-CSF did not promote this effector function alone or with IFN-gamma. We previously showed that M-CSF boosted macrophage antibody-independent killing of TU5 sarcoma targets with or without LK (Cell. Immunol. 105, 270, 1987). These studies thus show that M-CSF is a positive regulator of both macrophage-nonspecific tumor lysis and ADCC.     

Cytolytic activities of activated macrophages versus paraformaldehyde-fixed macrophages; soluble versus membrane-associated TNF.

Membrane-associated tumor necrosis factor (TNF) and soluble TNF were compared as to their lytic activities, and as to the kinetics of their expression by macrophages activated with LPS and/or IFN-gamma in the presence or absence of cycloheximide. EL 4 tumor cells, resistant and sensitive to lysis by recombinant TNF or membrane-associated TNF (paraformaldehyde (PF)-fixed activated macrophages) were used as targets. In the presence of cycloheximide the TNF-resistant S-EL4 cells were lysed by both TNFs. PF-fixed macrophages was cytolytic after 1 hr activation but not after 3 or more hours of activation. Their activity was totally inhibited by anti-TNF antibodies and was a composite of transmembrane (integral) TNF and soluble TNF conjugated to macrophage membrane TNF receptors. Treatment of the macrophages with glycine pH 3.0 buffer dissociated the conjugated TNF without affecting the integral membrane TNF. When macrophages were activated with LPS +/- IFN-gamma in the presence of cycloheximide or activated just with IFN-gamma their activity after fixation with paraformaldehyde was no longer detected. Nonfixed macrophages under these conditions still remained cytotoxic. Tumor cell susceptibility to membrane-associated TNF activity, in contrast to recombinant (soluble) TNF, was greatly reduced in the presence of nicotinamide, an inhibitor of ADP-ribosyltransferase, suggesting that the mechanisms of lysis by these TNFs may be different. The lytic activity of both TNFs was found to be receptor-dependent in that tumor cells, whose TNF binding sites were "down-regulated" by TPA, were rendered resistant to lysis by both membrane-associated and soluble TNFs.     

Mycobacterial lipopeptides elicit CD4+ CTLs in Mycobacterium tuberculosis-infected humans

In searching for immunogenic molecules with the potential to induce protective immune responses against tuberculosis, we developed an ex vivo model to study frequency, phenotype, and effector functions of human T lymphocytes recognizing hydrophobic Ags of Mycobacterium tuberculosis (M.Tb). To obtain unbiased results, we characterized T lymphocytes responding to a crude cell wall extract (chloroform methanol extract of M.Tb (M.Tb-CME)) containing a broad spectrum of mycobacterial glycolipids and lipopeptides. A significant proportion of T lymphocytes recognized M.Tb-CME (290 IFN-gamma+ T cells/10(5) PBMCs) and developed to effector memory cells as determined by the expression of CD45RO and the chemokine receptors CXCR3 and CCR5. Expanded lymphocytes fulfilled all criteria required for an efficient immune response against tuberculosis: 1) release of macrophage-activating Th1 cytokines and chemokines required for the spatial organization of local immune responses, 2) cytolytic activity against Ag-pulsed macrophages, and 3) recognition of infected macrophages and killing of the intracellular bacteria. Phenotypically, M.Tb-CME-expanded cells were CD4+ and MHC class II restricted, challenging current concepts that cytotoxic and antimicrobial effector cells are restricted to the CD8+ T cell subset. Pretreatment of M.Tb-CME with protease or chemical delipidation abrogated the biological activity, suggesting that responses were directed toward mycobacterial lipopeptides. These findings suggest that lipidated peptides are presented by M.Tb-infected macrophages and elicit CD4+ cytolytic and antimicrobial T lymphocytes. Our data support an emerging concept to include hydrophobic microbial Ags in vaccines against tuberculosis.     

CD137-deficient mice have reduced NK/NKT cell numbers and function, are resistant to lipopolysaccharide-induced shock syndromes, and have lower IL-4 responses

CD137, a member of the TNF superfamily, is involved in T cell and NK cell activation and cytokine production. To establish its in vivo role in systems dependent on NK and NKT cells, we studied the response of CD137-/- mice to LPS-induced shock, tumor killing, and their IL-4-controlled Th2 responses. In both high and low dose shock models, all the CD137-deficient mice, but none of the wild-type BALB/c mice, survived. After injection of LPS/2-amino-2-deoxy-D-galactose (D-gal), CD137-/- mice had reduced serum cytokine levels and substantially impaired liver IFN-gamma and TNF-alpha mRNA levels. Phenotypic analysis of mononuclear cells revealed fewer NK and NKT cells in the CD137-/- mice. The knockout mice did not generate a rapid IL-4 response after systemic T cell activation, or effective Ag-specific Th2 responses. In addition, both in vitro and in vivo NK-specific cytolytic activities were reduced. These findings suggest that CD137-directed NK/NKT cells play an important role in the inflammatory response leading to the production of proinflammatory cytokines, LPS-induced septic shock, and tumor killing, as well as IL-4-dependent Th2 responses.     

Natural cytotoxic cells and tumor necrosis factor activate similar lytic mechanisms

The lytic activity of natural cytotoxic (NC) cells has several characteristics which clearly distinguish it from other cell-mediated lytic activities and from most soluble cytolytic factors. An exception is the lytic activity mediated by tumor necrosis factor (TNF). In this paper, we report a detailed comparison of NC and TNF lysis of target cells which are used as prototype NC targets or TNF targets, and show that the two cytolytic activities have very similar, if not identical, lytic mechanisms. We present data showing that target cells which are NC-sensitive are also TNF-sensitive and that target cells which are NC-resistant are also TNF-resistant. Moreover, cells selected either in vivo or in vitro for NC resistance are selected for TNF resistance, and cells selected for TNF resistance are selected for NC resistance. The analysis of the kinetics of 51Cr release mediated by NC cells or by TNF show that both activities affect similar kinetics, in that there is no cell lysis for several hours after targets and effectors first interact. However, NC and TNF lytic activities can be distinguished. By using the cell lines 10ME or B/C-N as targets, it can be shown that whereas NC-mediated lysis is dependent on protein synthesis, TNF-mediated lysis is not. We also show that targets which are resistant to NC-mediated lysis because they express a protein synthesis-dependent resistance mechanism also require protein synthesis to resist TNF-mediated lysis, suggesting that the same resistance mechanism protects cells against both NC cells and TNF. Together, these data strongly support the hypothesis that NC cells and TNF activate the same lytic mechanism within target cells and that TNF may mediate the lytic activity of NC effector cells.     

Potentiation of lymphokine-induced macrophage activation by tumor necrosis factor-alpha

In this study, we examined the possible role of TNF-alpha and lymphotoxin (TNF-beta) as cofactors of macrophage activation. The results demonstrate that both TNF were capable of enhancing the cytostatic and cytolytic activity of murine peritoneal macrophages against Eb lymphoma cells. The potentiation of tumor cytotoxicity became apparent when macrophages from DBA/2 mice were suboptimally activated by either a T cell clone-derived macrophage-activating factor or by IFN-gamma plus LPS. Neither TNF-alpha nor TNF-beta could induce tumor cytotoxicity in IFN-gamma-primed macrophages, indicating that TNF cannot replace LPS as a triggering signal of activation. In LPS-resistant C3H/HeJ macrophages, which were unresponsive to IFN-gamma plus LPS, a supplementation with TNF fully restored activation to tumor cytotoxicity. Furthermore, TNF-alpha potentiated a variety of other functions in low-level activated macrophages such as a lactate production and release of cytotoxic factors. At the same time, TNF-alpha produced a further down-regulation of pinocytosis, tumor cell binding and RNA synthesis observed in activated macrophages. These data demonstrate new activities for both TNF-alpha and TNF-beta as helper factors that facilitate macrophage activation. In particular, the macrophage product TNF-alpha may serve as an autocrine signal to potentiate those macrophage functions that were insufficiently activated by lymphokines.