IL-4 regulates IL-2 induction of lymphokine-activated killer activity from human lymphocytes

IL-4 is a pluripotent lymphokine acting on various cell types. We investigated the role of human IL-4 on the generation of lymphokine-activated killer (LAK) activity. Human IL-4 alone did not induce LAK activity and inhibited IL-2 induction of LAK activity from unstimulated PBMC, peripheral blood null cells, spleen cells, and lymph node cells in a dose-dependent manner. IL-4 also inhibited several phenomena induced by IL-2 such as cell proliferation, augmentation of NK activity, increase of Leu-19+ cells, and expression of IL-2R(p55) on either CD3+ or Leu-19+ cells. IL-4, however, augmented cell proliferation with other T cell mitogens including PHA, Con A, PMA, or allo-MHC Ag with or without IL-2. In contrast to unstimulated cells, IL-4 alone induced marked cell proliferation and LAK activity as well as Leu-19+ cells from in vitro IL-2 preactivated PBMC or null cells, and did not inhibit IL-2 induced cell proliferation, LAK activity, Leu-19+ cells and IL-2R(p55) expression, but rather augmented them with low doses of IL-2. Although IL-4 alone induced LAK activity from peripheral blood of some patients previously given IL-2, IL-4 inhibited in vitro LAK generation with IL-2 from these cells in most cases. Therefore, IL-4 appears to directly inhibit the IL-2 activation pathway via IL-2R(p70) and prevent resting LAK precursors from proliferating and differentiating into final effector cells. However, once cells were sufficiently preactivated by IL-2, IL-4 induced LAK activity and did not inhibit IL-2 activation of these cells. These data suggest an immunoregulatory role of IL-4 on human null cells and T cells.     

Modulation of lymphokine release and cytolytic activities by activating peripheral blood lymphocytes via CD2

We had previously shown that the signal of activation delivered via CD2 varies according to the mitogenic pair of CD2 mAb used. We had selected two typical mAb pairs, D66 + T11(1) and GT2 + T11(1), the former delivering the "richest" signal, the latter the poorest. Here we analyzed the cytolytic activities generated within PBL-stimulated by these two pairs. When purified CD2+,3- cells were cultured with either one of these two pairs, no significant lymphokine-activated killer (LAK) activity--namely the activity exerted on NK-resistant malignant cell lines or fresh tumor cells--was detected, thereby demonstrating the inability of CD2 mAb pairs to directly trigger the LAK precursors. By contrast, when purified CD2+,3+ cells were cultured, only D66 + T11(1) was able to trigger a potent CTL activity, as judged by targeting their activity, at the effector phase, with a bridging CD3 mAb on a FcR+ target cell or by using heteroaggregates on FcR- malignant cells. When whole PBL were used, a similar and moderate LAK activity was generated after culture with either one of the 2 CD2 mAb pairs. This, in fact, masked quite different events. The amounts of endogeneous IL-2 released in PBL cultures with GT2 + T11(1) was rather low, although it was sufficiently high in PBL cultures with D66 + T11(1) to generate a potent LAK activity. Yet, PBL stimulated with D66 + T11(1) released concomitantly a high amount of IL-4 which inhibited the development of the LAK activity, as demonstrated by unmasking this activity with an anti-IL4 antiserum and which did not inhibit the T CTL activity; this IL-4 secretion was not seen with GT2 + T11(1). Therefore, stimulation by these two typical CD2 mAb pairs induce a striking different pattern of IL synthesis.     

Natural killer and lymphokine-activated killer cell activities from human marrow precursors. II. The effects of IL-3 and IL-4

Both IL-3 and IL-4 have multi-CSF activity on early marrow progenitors. We have examined the effect of IL-3 and IL-4 on the differentiation of NK cells from their marrow-derived precursors and have further examined the interactions of these cytokines with IL-2 and IL-1. We tested marrow which had been depleted of mature cells and of E rosette-positive cells (including NK cells) by treatment with soybean lectin and SRBC (SBA-E-BM). The cytolytic activities of the SBA-E-BM samples were tested in 51Cr-release assays after 7 days of liquid culture. K562 targets were used as a measure of NK activity and NK-resistant Daudi targets were used to measure lymphokine-activated killer (LAK) cell activity. Neither NK nor LAK activity was detectable in marrow cultured in medium without cytokines, or in medium containing IL-3, or IL-4 alone. Both of these cytokines were shown to be inhibitory to the IL-2-induced generation of NK and LAK activity from SBA-E-BM at concentrations as low as 1 U/ml. The inhibitory activity of both IL-3 and IL-4 was found to occur early in the marrow cultures, with little or no inhibitory effects seen if added 48 h after IL-2. IL-3 appeared to be specifically inhibitory to NK cell precursors since addition of IL-3 to cultures of PBMC did not inhibit IL-2-induced lytic activities. In contrast, IL-4 was equally inhibitory to the activation of marrow and peripheral blood NK cells by IL-2. Mixing experiments demonstrated that the reduced lytic activity in IL-3 or IL-4 containing marrow cultures were not due to suppression of the NK effectors, nor could marrow cultured in IL-3 or IL-4 serve as targets for IL-2-activated NK cells. Phenotype analysis of the lymphoid cells in marrow cultures containing IL-2 combined with IL-3 or IL-4 revealed fewer cells expressing Leu-11 (CD16), or Leu-19 (CD56) and fewer CD16, CD56 coexpressing cells compared with marrow cultured in medium containing IL-2 alone. The inhibitory activity of IL-4, but not IL-3, could be partially reversed if IL-1 was added to the cultures, suggesting that IL-1 and IL-4 have opposing activities on NK cells responsiveness to IL-2. These interactions between cytokines might be important in the regulation of NK cell differentiation and on the functional activity of mature NK cells.     

Differential sensitivity of cytotoxic T lymphocytes and lymphokine-activated killer cells to inhibition by L-ornithine

The selective inhibition of murine cytotoxic T lymphocyte (CTL) differentiation in C57B1/6 (B6) anti-DBA/2 mixed leukocyte cultures (MLC) by the amino acid L-ornithine (Orn) could not be reversed by addition of up to 1000 U/ml IL-2. Analysis of the effects of Orn on induction of lymphokine-activated killer (LAK cells), using dosages of IL-2 from 10-1000 U/ml and measuring cytolytic activity against two tumor targets (P815 and YAC-1) over the course of 5 days, indicated that LAK cells were not suppressed by Orn. LAK precursors and effector cells were CD8- and ASGM1+, indicating that they were derived from natural killer (NK) cells. We also found that the growth and maintenance of cloned CTL lines were not sensitive to inhibition by Orn; nor was their acquisition of nonspecific cytolytic activity in the presence of high lymphokine concentrations. Thus, induction of naive CTL shows differential susceptibility to Orn inhibition relative to LAK and LAK-like activities by NK and cloned CTL lines in response to IL-2.     

The role of IL-2 and T4+ cells in the generation of human influenza virus-specific CTL activity

Stimulation of human peripheral blood lymphocytes (PBL) with influenza A virus leads to the generation of virus-specific cytotoxic T lymphocyte (CTL) activity as well as natural killer (NK)-like activity. In this study, we show that exogenous IL-2 augments the in vitro generation of virus-specific CTL activity, only when added some days after the initiation of the culture. Apparently, the endogenously produced IL-2 can be a limiting factor in the in vitro generation of CTL activity. The increase of influenza virus-specific CTL activity after addition of exogenous IL-2 does not affect the restriction pattern of the CTL response. So, the preferential use of certain HLA antigens as restriction elements is not due to a limiting amount of endogenously produced IL-2. Depletion of T4+ cells completely abrogates the generation of virus-specific CTL activity. Addition of exogenous IL-2 to T4+-cell-depleted cultures fully restores the generation of HLA-restricted virus-specific CTL activity. We conclude that in the in vitro generation of virus-specific CTL activity in bulk cultures of human PBL the sole function of T4+ cells in human virus-specific CTL generation is the production of IL-2, no cognitive cell interaction of T8+ CTL precursors with T4+ cells is required, and in bulk cultures T8+ cells themselves are not able to produce sufficient amounts of IL-2 to ascertain the maturation of virus-specific CTL precursors into cytolytic T cells. Finally, we show that exogenous IL-2 also has a stimulatory effect on the NK-like or lymphokine-activated killer activity, which is always concomitantly induced in virus-specific CTL generation cultures, but has no influence on the levels of IFN produced in such cultures.     

Generation of lymphokine-activated killer activity in T cells. Possible regulatory circuits.

CD4+ and CD8+ T cells do not develop significant lymphokine-activated killer (LAK) activity when PBL are cultured with IL-2 or even when they are activated with a T cell stimulus such as OKT3 mAb. The possibility that a T cell regulatory mechanism prevents the development of LAK activity by CD4+ or CD8+ cells in OKT3 mAb and IL-2 cultures was tested by depleting CD8+ or CD4+ cells from PBL before stimulation with OKT3 and IL-2. Under these conditions, the remaining CD4+ and CD8+ cells were able to generate non-MHC-restricted lysis of NK-resistant tumor targets. Our data suggested that a regulatory signal was present in the culture to prevent the development of lytic function by T cells. T cells removed from the PBL cultures were, upon culture with IL-2, able to generate high LAK activity, suggesting that inhibition of the CD4+ or CD8+ T cell-mediated LAK activity was an active ongoing process, which blocked the lysis at the level of the activated cell and not the precursor cell. Mixing experiments demonstrated that the CD4+ or the CD8+ cells isolated from the PBL cultures were able to inhibit the development of lytic function in the CD4-depleted and CD8-depleted cultures. Transforming growth factor-beta (TGF-beta) has been shown to block LAK activity of NK cells in IL-2-stimulated cultures. When TGF-beta was added to CD4(+)- or CD8(+)-depleted cultures, it also inhibited LAK activity of T cells in a dose-dependent fashion, without interfering with T cell growth. Lytic activity returned to activated levels when TGF-beta was removed from the culture medium, thereby demonstrating the reversibility of TGF-beta inhibition.     

Transforming growth factor-beta inhibits the in vitro generation of lymphokine-activated killer cells and cytotoxic T cells

Summary The effect(s) of purified transforming growth factor-beta (TGF-beta) and platelet-derived growth factor (PDGF) on the induction and function of lymphokine-activated killer (LAK) cells and cytotoxic T lymphocytes (CTL) was examined. The addition of TGF-beta, but not PDGF, to cultures containing fresh C57BL/6 mouse splenocytes or human peripheral blood lymphocytes plus recombinant interleukin-2 markedly inhibited the development of mouse and human LAK cell activity (measured after 3 days for cytotoxicity against cultured or fresh tumor targets in 4-h ⁵¹Cr release assays). The addition of TGF-beta, but not PDGF, to a one-way, C57BL/6 anti-DBA/2, mixed lymphocyte reaction effectively blocked the generation of allospecific CTL as well. However, TGF-beta did not inhibit the effector function of LAK cells or of allospecific CTL when added directly to the short-term cytolytic assay. A second form of homodimeric TGF-beta, type 2, was also found to be suppressive on the development of murine LAK cells and allospecific CTL. Collectively, these data demonstrate that the peptide TGF-beta is a potent inhibitor of LAK cell and CTL generation in vitro.     

IL-7 induces human lymphokine-activated killer cell activity and is regulated by IL-4.

Induction of lymphokine-activated killer (LAK) activity by IL-2 has been described and characterized as broadly cytolytic activity against both fresh and cultured tumors. rIL-7 in the absence of IL-2 also induces LAK activity in human cells. This activity is unique for IL-7, because it is not shared by other cytokines including IL-1, IL-4, IL-6, and TNF-alpha. IL-7 also induces either de novo or increased expression of the surface markers CD25 (Tac, IL-2R alpha-chain), CD54 (ICAM-1), Mic beta 1 (IL-2R beta-chain) and CD69 (early T cell activation Ag). IL-7-induced LAK activity is independent of IL-2 secretion, because it is not abrogated by IL-2 antisera. The LAK precursor responding to IL-7 stimulation is enriched in the null cell fraction as has been demonstrated for IL-2-induced LAK cells. TGF-beta and IL-4 interfere with generation of LAK activity by IL-7. Anti-IL-4 antiserum enhances IL-7-induced LAK activity and augments induction of surface marker expression by IL-7. This may be indirect evidence that IL-7 stimulation leads to induction of IL-4 activity. Our results describe the activation of mature lymphoid cells by IL-7. This and the previously described role of IL-7 in lymphohemopoiesis makes it a cytokine of potential therapeutic value for treatment of immunodeficiency states and possibly the immunotherapy of cancer.     

IL-10: a novel cytotoxic T cell differentiation factor

A previous report concluded that a new cytokine, designated IL-10, is a growth cofactor for thymocytes, spleen, and lymph node cells. In this report, we have focused on the effects of IL-10 on CD8+ spleen T cells. We first observed that IL-10 enhances the growth of CD8+ T cells to IL-2. We then investigated the effect of murine rIL-10 on the induction of murine effector CTL from CTL precursors (CTL-p) using both bulk and filler cell-free limiting-dilution cultures. IL-10 alone could not induce Con A-activated FACS-sorted CD8+ T cells either to proliferate or to generate effector CTL. In combination with IL-2, however, IL-10 augmented the cytolytic activity of effector CTL generated from Con A-activated spleen CD8+ T cells in bulk cultures incubated for 5 days. In limiting-dilution cultures (using solid-phase anti-CD3 mAb as stimulus), IL-10, in combination with IL-2, substantially increased the CTL-p frequency and augmented the cytolytic activity per clone expanded from one CD8+ T cell when compared with cells cultured in IL-2 alone. Kinetic studies showed that IL-10 is required at both early and late culture stages for optimal generation of effector CTL. The potentiating effects of IL-10 on CTL function were neutralized by an anti-IL-10 mAb. These results indicate that IL-10 has direct effects on mature T cells, and suggest that IL-10 also functions as a cytotoxic T cell differentiation factor, which promotes a higher number of IL-2-activated CTL-p to proliferate and differentiate into effector CTL. In contrast, IL-10 did not enhance significantly the lymphokine-activated killer cell activity of IL-2-grown CD8+ cytotoxic T cells.     

Interleukin-6 does not support interleukin-2 induced generation of human lymphokine-activated killer cells

Summary The activity of lymphokine-activated killer (LAK) cells is supported by various cytokines. The objective of this study was to see if recombinant interleukin-6 (IL-6) either alone or in combination with interleukin-2 (IL-2) has any effect on the generation of LAK cells. Peripheral blood mononuclear cells of healthy donors were cultured for 4 or 6 days with both cytokines either alone or in combination. LAK activity against K562 and natural killer-resistant Daudi cells was assessed by a 4-h and an 18-h⁵¹Cr-release assay at various effector to target ratios. IL-6 alone in increasing concentrations did not induce LAK cell activity. Neither additive nor synergistic effects of IL-6 with IL-2 were observed. Immunofluorescence analysis with phycoerythrin-conjugated anti-CD56 antibody demonstrated that IL-6 could not maintain or increase the number of CD56-positive cells over a 6-day culture period. These results suggest that IL-6 does not support LAK cell generation by itself or increase LAK cell activity in combination with IL-2.     

Phenotypic and functional heterogeneity of thymic and splenic lymphokine activated killer cells relative to ornithine sensitivity

We have previously reported the selective inhibition of cytotoxic T lymphocytes (CTL) by 10 mM ornithine (ORN) relative to natural killer (NK) cell-derived lymphokine activated killer cells (LAK). To determine if this were due to differences in the progenitor cells or the type of stimulus, we used cortisone-resistant thymocytes (CRT) as a source of mature T cells for induction of LAK and CTL, and compared the results with spleen. Thymic and splenic CTL precursors (CTLp) from C57B1/6 (B6) mice were CD8+, ASGM1-, ORN sensitive. Splenic LAK precursors (LAKp) were CD8-, ASGM1+, ORN resistant when assayed against both YAC-1 and P815 tumor targets. In contrast, CRT-derived LAKp were CD8-, ASGM1+, ORN resistant against YAC-1, whereas LAKp against P815 were CD8+, ASGM1+, ORN sensitive. ORN sensitivity was also observed among CTL and LAK in DBA/2 mice and was associated with CD8+ phenotype. Therefore, our initial observation of differential ORN sensitivity in CTL vs LAK was a function of the progenitor cells; furthermore, CD8+ cytolytic cells are ORN sensitive whether activated by antigen (CTL) or IL-2 (T-LAK).     

Induction of murine lymphokine-activated killer cells by recombinant IL-7

The data demonstrate that IL-7, a cytokine that was originally identified, purified, and cloned based upon its ability to support the growth of pre-B cells in vitro, also induces proliferation and promotes the generation of lymphokine-activated killer (LAK) cell activity in populations of resting peripheral lymphoid cells. Although the kinetics of LAK induction by IL-7 (which peaked at days 6 to 8 of culture) was slower than that detected in cultures containing IL-2 (which peaked at day 4), IL-7 was significantly more effective at maintaining cytotoxic activity over longer periods of time, and greater viable cell recoveries, than was IL-2. A wide range of murine tumor target cells were found to be lysed in an MHC-unrestricted fashion by IL-7 induced LAK, but syngeneic Con A-induced lymphoblasts were not; nor were target cells from the human tumors K562 or Daudi lysed by IL-7 LAK. IL-7 LAK were induced in populations of lymphoid cells obtained from secondary lymphoid tissues (peripheral lymph nodes and spleen), but not from primary lymphoid tissues (thymus and bone marrow). LAK induced by IL-7 from unfractionated populations of lymphoid cells were completely eliminated by treatment with anti-CD8 or anti-Thy-1+C, and unaffected by treatment with anti-CD4, anti-asialo GM1 or anti-NK1.1+C. Interestingly, although no detectable CD4+ effector cells could be detected in populations of LAK generated from unfractionated populations of lymphoid cells stimulated by IL-7, they were found to be generated from populations of lymphoid cells from which CD8+ cells had been eliminated before being cultured in medium containing IL-7. These data suggest that CD4+ T cells do not normally give rise to IL-7-induced LAK unless they are first separated from CD8+ T cells. LAK induced by IL-7 appear to be distinct from LAK activity induced by IL-2 in that there is no detectable involvement of NK-like effector cells at either the precursor or effector cell stages.     

Regulation of human cytolytic lymphocyte responses by interleukin-12.

IL-12 is a heterodimeric cytokine which has been shown to cause the proliferation of activated T and NK cells, to enhance the lytic activity of NK cells, and to induce IFN-gamma production by resting and activated T and NK cells. We previously reported that IL-12 could synergize with IL-2 to activate human LAK cells in the presence of hydrocortisone but that IL-12 alone was inactive. We herein show that in the absence of hydrocortisone, IL-12 by itself can activate human LAK cells. IL-12-induced LAK cell activity was mediated predominantly by CD56+ lymphocytes. Activation of LAK cells by IL-12 appeared to be independent of IL-2 since it was not inhibited by neutralizing anti-human IL-2. However, IL-12- and IL-2-induced LAK cell activation could be partially inhibited by anti-human TNF-alpha. Moreover, IL-12 produced in situ appeared to play a role in IL-2-induced LAK cell activation since rat monoclonal antibodies to human IL-12 could partially inhibit the generation of LAK cells in response to IL-2. In addition to its effects on LAK cell responses, IL-12 could facilitate specific allogeneic human CTL responses. However, IL-12-facilitated CTL responses were blocked by neutralizing anti-human IL-2 indicating a requirement for IL-2 produced in situ. The ability of IL-12 to facilitate both nonspecific LAK and specific CTL responses suggests that it may be useful as a therapeutic agent against some tumors and infectious diseases.     

IL-6 enhances the cytotoxic activity of thymocyte-derived CD56+ cells.

Thymocyte-derived lymphokine-activated killer (LAK) cells were used as a model for the study of the cytokine driven development of cytotoxicity. These cells are devoid of initial cytotoxic activity but upon culture in IL-2 they develop into cytotoxic effectors. The parameters of the response of thymocytes to IL-6 are similar to that of PBL in that IL-6, at concentrations as low as 1 mu/ml, increases cytotoxicity of thymocyte-LAK cells when generated in low doses (25-50 mu/ml) of IL-2. IL-6-enhanced thymocyte-LAK cytotoxicity is observed when tested against both NK-resistant and NK-sensitive tumor cell lines. IL-6 alone does not induce any cytotoxicity from thymocytes nor does IL-6 change the time course of thymocyte-LAK cell generation in IL-2 culture. IL-6 does not affect DNA synthesis, total cell number, proportion of CD56+ cells, or the expression of IL-2R (both P55 and P75 glycoproteins) in IL-2-cultured thymocytes. Instead, IL-6 used to treat mature thymocyte-LAK effector cells for as little as 1 hr prior to 51Cr-release assay increases LAK cytotoxicity. This enhancement is abrogated by pretreatment of effector cells with cycloheximide, suggesting that protein synthesis is required for IL-6 to enhance LAK cell activity. The precursor phenotypes of IL-6-responsive thymocyte-LAK cells are CD3-/CD5-. The effector phenotypes of IL-6-enhanced thymocyte-LAK cells are CD5-/CD56+. Thus, IL-6 depends on synthesis of rapid-turnover proteins to act on mature CD56+/CD5- LAK cells to increase their cytotoxic function.     

Effects of IL-7 and IL-2 on highly enriched CD56+ natural killer cells. A comparative study.

IL-7 has been shown to induce low levels of lymphokine-activated killer cell (LAK) activity in bulk PBMC populations. We report here that immunomagnetically purified CD56+ cells from peripheral blood generated high LAK activity in response to IL-7. The LAK activity induced by IL-7 was comparable to, or slightly lower than, the LAK activity induced by IL-2. When analyzing cells from the same donor, no detectable LAK-generating effect of IL-7 was registered in the PBMC population, in contrast to a substantial effect in the CD56+ population. IL-2 induced 8- to 15-fold higher proliferative activity in CD56+ cells, relative to IL-7. At suboptimal concentrations of IL-2, IL-7 had a synergistic effect on the proliferation. IL-2-neutralizing antibodies did not abrogate the IL-7-induced proliferation or LAK generation. Both IL-7 and IL-2 induced comparable levels of 75-kDa TNFR expression, whereas IL-2R alpha expression was higher in IL-7-stimulated CD56+ cells. Low levels of TNF were produced in response to IL-7 at day 5, as opposed to a 50-fold higher TNF production in response to IL-2. No IL-2 or IL-6 production was detected. Our data indicate that IL-7 has profound and direct effects on CD56+ cells.     

IL-4 regulation of murine lymphokine-activated killer activity in vitro. Effects on the IL-2-induced expansion, cytotoxicity, and phenotype of lymphokine-activated killer effectors

The in vitro incubation of B6 splenocytes with purified, mouse rIL-4 for 4 to 5 days was sufficient to generate lymphokine-activated killer (LAK) activity. In addition, rIL-4 augmented LAK cytotoxic activity when combined with rIL-2, as measured in a 4 h 51Cr-release assay against fresh, syngeneic MCA-sarcoma (MCA-102 and MCA-105) cells. Interestingly, this augmentation was not observed against the cultured YAC-1 target. LAK generation and augmentation of cytotoxicity by rIL-4 was species-specific, because human rIL-4 (up to 20,000 U/ml) failed to elicit these effects in the mouse splenocyte cultures. When 5-day B6 LAK cells (splenocytes incubated in rIL-2 at 1000 U/ml for 5 days) were split and recultured in the combination of rIL-2 plus rIL-4 for 4 additional days at least a twofold greater expansion in cell number resulted compared to similar cells cultured in either rIL-2 or rIL-4 alone. Moreover, LAK cells expanded in rIL-2 plus rIL-4 exhibited substantial increases in in vitro cytolytic activity (on a per cell basis) against MCA-102 and MCA-105 sarcoma cells, but not against YAC-1 targets. FACS analysis or negative selection using Lyt-2 or NK-1.1 mAb plus C revealed no differences in effector phenotype(s) of LAK cells expanded in rIL-2 alone compared to rIL-2 plus rIL-4 to account for the differences observed in both expansion and cytolytic activity by rIL-4. The majority of cells was Thy-1+, Lyt-2+, T3+, and ASGM-1+. However, a marked increase in the granule-associated serine esterase, BLT-E, was found only in LAK cells expanded in the combination of both lymphokines. Collectively, these studies show that rIL-4 has potent regulatory activities on splenic LAK generation, expansion, and cytotoxic function in the mouse.     

Lymphokine-activated killer (LAK) cells. V. 8-Mercaptoguanosine as an IL-2-sparing agent in LAK generation.

Guanine ribonucleosides, substituted at the C8 position with either a bromine or a thiol group, have recently been shown to regulate several immunologic responses. We have previously shown that 8-mercaptoguanosine (8MG) can replace the requirement for cytokines in the generation of MHC-restricted CTL. In this paper, we examined the ability of 8MG to induce MHC-nonrestricted killer cells. We found that 8MG did not induce significant lytic activity from normal resting lymphocytes. However, 8MG was able to synergize with minimal amounts of IL-2 in inducing lytic activity similar to lymphokine-activated killers (LAK) in that both NK-sensitive and NK-resistant tumor cells were killed. Both the precursors and effectors of 8MG-LAK activity were similar to NK cells and were CD4- CD8- asialo-GM1+ NK1.1+. Similar to IL-2-induced LAK, 8MG-LAK were B220+. 8MG appeared to "stage" these precursor lymphocytes to become more responsive to IL-2 because optimal induction of 8MG-LAK required preincubation with 8MG before the addition of IL-2. This "staging" appeared to be due to the release of a "second signal" since it was readily inhibited by cyclosporine A. Anti-IFN-alpha beta was as efficient as cyclosporine A in inhibiting 8MG-LAK generation, whereas anti-IFN-gamma and anti-IL-1 did not exhibit significant inhibition. These findings suggest that 8MG can be of possible utility as an IL-2-sparing agent in LAK generation from NK cells.     

IL-6/BSF-2 functions as a killer helper factor in the in vitro induction of cytotoxic T cells

rIL-6/B cell stimulatory factor 2 was found to augment CTL generation from mature as well as immature human T cells stimulated with UV-treated allogeneic cells. rIL-6 also acted on peanut agglutinin-positive murine thymocytes and Lyt-2-positive splenic T cells to give rise to CTL. rIL-6 alone could not induce CTL generation, the presence of IL-2 during the early phase of culture period was found to be essential for the IL-6 activity in the induction of CTL. The effect of rIL-6 was not mediated by the induction of IL-2 inasmuch as rIL-6 did not augment IL-2 production in MLC and anti-IL-2 antibody could not neutralize IL-6 activity. rIL-6 augmented CTL generation even when added 72 h after the initiation of cultures. The enhancing activity of rIL-6 could be neutralized with anti-IL-6 antibodies even when added 72 h after the initiation of cultures. The present data indicate that IL-6 acts in the late phase of CTL generation.     

Tolerance induction by transcutaneous immunization through ultraviolet-irradiated skin is transferable through CD4+CD25+ T regulatory cells and is dependent on host-derived IL-10

UV radiation of the skin impairs immune responses to haptens and to tumor Ags. Transcutaneous immunization (TCI) is an effective method of inducing immune responses to protein and peptide Ag. We explore the effect of UV irradiation on TCI. The generation of Ag-specific CTL to OVA protein, but not class I MHC-restricted OVA peptide, is inhibited by TCI through UV-irradiated skin. Consequently, the induction of protein contact hypersensitivity and in vivo Ag-specific CTL activity following OVA protein immunization is prevented. Application of haptens to UV-exposed skin induces hapten-specific tolerance. We demonstrate that application of protein or class II MHC-restricted OVA peptide to UV-irradiated skin induces transferable Ag-specific tolerance. This tolerance is mediated by CD4(+)CD25(+) T regulatory (T(reg)) cells. These Ag-specific T(reg) cells inhibit the priming of CTL following protein immunization in the presence of CpG adjuvant. IL-10 deficiency is known to prevent hapten-specific tolerance induction. In this study, we demonstrate, using IL-10-deficient mice and adoptive T cell transfer, that IL-10 is required for the direct inhibition of CTL priming following immunization through UV-irradiated skin. However, IL-10 is not required for the induction of T(reg) cells through UV-irradiated skin as IL-10-deficient T(reg) cells are able to mediate tolerance. Rather, host-derived IL-10 is required for the function of UV-generated T(reg) cells. These experiments indicate that protein and peptide TCI through UV-irradiated skin may be used to induce robust Ag-specific tolerance to neo-Ags and that UV-induced T(reg) cells mediate their effects in part through the modulation of IL-10.     

Antigen specific and MHC nonrestricted cytotoxicity of T cell receptor alpha beta+ and gamma delta+ human T cell clones isolated in IL-4

IL-4 has been shown to act as a growth factor for human T cells. In addition, IL-4 can enhance CTL activity in MLC, but blocks IL-2 induced lymphokine activated killer cell activity in PBL. In our study, the cloning efficiencies, Ag-specific CTL activity and non-MHC-restricted cytotoxicity of CTL clones generated in IL-2 were compared to those generated in IL-4. In a first experiment, T cells were stimulated with the EBV-transformed B cell line JY and cloned 7 days later with feeder cells and either IL-2 or IL-4. In a second experiment, stimulation of the T cells was carried out in the presence of IL-2 plus anti-IL-4 antibodies or IL-4 plus anti-IL-2 antibodies in order to block the effects of IL-4 and IL-2, respectively, produced by the feeder cells. Although the cloning efficiencies in the second experiment were lower than those obtained in the first experiment, the cloning efficiencies obtained with IL-2 or IL-4 were similar in both experiments. The overall proportion of TCR alpha beta+ T cell clones cytotoxic for the stimulator cell JY established in IL-2 or IL-4 were comparable. A striking difference between the clones obtained in IL-2 or IL-4 was that a large proportion of the clones obtained in IL-4 expressed CD4 and CD8 simultaneously, whereas none of the clones isolated in IL-2 were double positive. Also gamma delta+ T cell clones could be established with IL-4 as a growth factor. TCR gamma delta+ T cell clones isolated in either IL-2 or IL-4 were CD4-CD8- or CD4-CD8+, but the proportion of CD4-CD8+ clones isolated in IL-4 was higher. Interestingly, one TCR gamma delta+ clone isolated in IL-2 was CD4+CD8-. Most of the TCR alpha beta+ and TCR gamma delta+ CTL-clones isolated in IL-2 lysed the NK cell sensitive target cell K562. In contrast, only a small proportion of the TCR alpha beta+ or TCR gamma delta+ CTL clones isolated in IL-4, lysed K562. One TCR gamma delta+ T cell clone (CD-124) isolated in IL-4 and subsequently incubated in IL-2 acquired lytic activity against K562.(ABSTRACT TRUNCATED AT 400 WORDS)