Inhibition of the lytic phase of murine T-cell-mediated alloimmune cytotoxicity by a rat antiactivated T-cell antiserum

Antisera produced in rats by immunization with alloimmune murine C57Bl/6 anti-P815 splenic lymphocytes or purified T cells activated in vitro by coculture with phytohemagglutinincoated L-929 cells were found to inhibit the in vitro cytolytic action of in vivo and in vitro alloimmune C57Bl/6 anti-P815 cytotoxic T cells in a 4-hr chromium-51 release assay. The rat anti-murine-activated lymphocyte (anti-MAL) or antiactivated T-cell (anti-ATC) serum inhibited lysis in the absence of exogenously added complement activity and were not directly cytotoxic to CTL. Absorption of anti-MAL with target cells P815, L-929, EL-4, and normal C57Bl/6 lymphocytes removed a limited amount of the CTL-inhibitory activity. In contrast, lectin-activated alloimmune lymphocytes fully absorbed the inhibitory activity indicating these antisera preferentially recognize unique antigenic determinants associated with the activated CTL cell surface. The anti-ATC was found to block alloimmune lysis by CTL from several inbred mouse strains suggesting these antisera recognized antigenic determinants of a common lytic mechanism. A kinetic analysis of the inhibitory activity of the anti-MAL on the CTL reaction scheme revealed this antiserum inhibited lysis at a post-Ca²⁺-dependent step, presumably during the target cell lytic phase. This result suggests the rat antiserum can neutralize the CTL lytic mechanism.     

An inhibitor specific for the mouse T-cell associated serine proteinase 1 (TSP-1) inhibits the cytolytic potential of cytoplasmic granules but not of intact cytolytic T cells

We have investigated a proteinase inhibitor, designed according to the preferred amino acid sequence that is cleaved by the murine T-cell specific serine proteinase 1 (TSP-1) for its effect on the cytolytic potential of cloned cytotoxic T-cell lines (CTLL) and of cytoplasmic granules, derived from these cells. Pretreatment of effector cells with H-D-Pro-Phe-Arg-chloromethyl-ketone (PFR-CK) prior to the cytotoxicity assay did not result in inhibition of cytolytic activity of three independent CTLL and did not effect their granule-associated TSP-1 activity after extraction with Triton X-100. Furthermore, PFR-CK did not interfere with cytolysis of target cells by CTLL when present for the entire incubation period. In contrast, PFR-CK inhibited in a dose-dependent manner both TSP-1 activity and the hemolytic/cytolytic potential of isolated cytoplasmic granules after their pretreatment with high-salt concentration. We interpret these results to mean that cytolysis of target cells by CTLL involves the granule-associated proteinase TSP-1, which probably becomes active upon exocytosis following effector-target cell interactions.     

Immunoregulation by mouse T-cell clones. I. Suppression and amplification of cytotoxic responses by cloned H-Y-specific cytolytic T lymphocytes

H-Y-specific and H-2Db-restricted, Lyt-1-2+ T-cell clones ( CTLL ) with graded specific cytotoxic activities on male C57BL/6 (B6) target cells ( 1E3 , ; 2C5 , ++; 2A5 , +, 3E6 , +/-) were tested for their capacity to inhibit the generation of H-Y-specific cytotoxic T lymphocytes (CTL) in vitro. Addition of irradiated lymphocytes of CTLL 1E3 and CTLL 3E6 but not those of CTLL 2A5 or CTLL 2C5 abolished the generation of CTL from in vivo primed H-Y-specific precursor cells (CTLP) when added to fresh mixed-lymphocyte cultures (MLC). Exogenous sources of T-cell growth factors (TCGF) did not overcome suppression. Rather the presence of TCGF resulted in a further enhancement of suppressive activities in CTLL 1E3 and 3E6 and the induction of similar activities in cells from CTLL 2A5 and 2C5 , which by themselves were not inhibitory. Moreover when added to similar MLC on Day 1 instead of Day 0, only irradiated cells of CTLL 3E6 but not those of the other three CTLL were suppressive. Induction of suppressive activities in H-Y-specific CTLL was independent of the appropriate male stimulator cells since it was also observed in MLC induced by irrelevant antigens (H-2, trinitrophenol). Furthermore at low cell numbers, irradiated lymphocytes from any of the CTLL consistently enhanced CTL activities generated from H-Y-specific CTLP. This augmenting activity, which was not TCGF, could be transferred by soluble mediators present in antigen-sensitized CTLL cultures. Thus, these data indicate (i) that cytotoxic effector cells can function as suppressor cells in the generation of CTL, (ii) that the cytotoxic activity of cloned CTL does not correlate with their capacity to suppress CTL responses, (iii) that the inhibition of CTL responses by CTLL is not due to simple consumption of T-cell growth factors produced in MLC, and (iv) that different CTL clones may interfere with the generation of CTL at different stages of their maturation. Moreover, the experiments suggest an antigen-independent enhancement of suppression by the interaction of CTL with lymphokines. Together with the augmenting activity evoked by cloned CTL the data provide strong evidence for the expression of multiple immunological functions by one particular subset of T cells and suggest that cytotoxic effector cells can differentially regulate the maturation and/or clonal expression of their precursor cells.     

T3 monoclonal antibody activation of nonspecific cytolysis: a mechanism of CTL inhibition

The T3 antigen is expressed on all cytotoxic T lymphocytes (CTL). Monoclonal antibodies (MAb) to the T3 antigen previously have been shown to inhibit CTL-mediated killing of cells expressing the relevant target antigens. The mechanism of T3 MAb inhibition, however, remains undefined. In this report, we describe a novel effect of the T3 MAb: the stimulation of allospecific CTL clones to kill target cells that do not express the relevant HLA antigens. The stimulation of nonspecific killing was seen only with MAb to the T3 antigen; MAb to other function-associated antigens (e.g., LFA-1, LFA-2, LFA-3, T4, T8, HLA-A,B,C, and DR) had no effect. T3 MAb stimulated nonspecific killing by CTL clones expressing both the T4+ and T8+ phenotype and by CTL clones specific for both class I and class II HLA alloantigens. Target cell susceptibility to T3 MAb stimulated killing was variable. CTL clones lysed some target cell lines very efficiently (e.g., K562, Daudi, and M124.1) but lysed other cell lines much less efficiently (e.g., 23.1, Mann, and L cells). In CTL-mediated cytotoxicity assays with target cells expressing the relevant HLA antigens, T3 MAb demonstrated the expected inhibition of cytolysis. Thus, the ability of T3 MAb to stimulate and inhibit CTL-mediated cytolysis suggests that both effects may be the result of a common mechanism of activation.     

Suppression of alloimmune cytotoxic T lymphocyte (CTL) generation by depletion of NK cells and restoration by interferon and/or interleukin 2

By using rabbit antiserum to a glycolipid, ganglio-n-tetraosylceramide (ASGM1), the accessory effect of natural killer (NK) cells on the generation of alloimmune CTL in mice was investigated. When normal C3H/He mice were immunized with C57BL/6 or BALB/c spleen cells, they generated alloimmune CTL with a surface marker phenotype of Thy-1+ Lyt-1-2+ ASGM1-, preceded by early augmentation of cytotoxic activity of NK cells with a Thy-1-Lyt-1-2-ASGM1+ phenotype. Administration of anti-ASGM1 (10 microliters) in mice resulted in a complete depletion of NK activity and ASGM1+ cells in the spleen even 1 day after injection, but no changes in the proportions of T (Thy-1+) cells and their Lyt-1 and Lyt-2 subsets as revealed by an immunofluorescence analyzer (FACS) and phagocytic cells. When these anti-ASGM1-treated mice were immunized with allogeneic cells, they showed neither augmented NK activity nor generation of alloimmune CTL, and spleen cells isolated from these anti-ASGM1-treated mice produced no CTL response to alloimmunization in vitro. Normal spleen cells treated with the antiserum and complement in vitro also showed a complete NK depletion without any deterioration of T cells and their Lyt-1 and Lyt-2 subsets, and when stimulated with allogeneic cells they generated no CTL. Spleen NK (ASGM1+) cells were purified by Percoll-gradient centrifugations followed by complement-dependent killing of T cells with the use of anti-Thy-1 monoclonal antibody, and were further purified by panning methods with anti-ASGM1, giving a preparation consisting of greater than 90% ASGM1+, Ly-5+ cells, and less than 0.5% of Thy-1+, Lyt-1+, and Lyt-2+ cells. These purified ASGM1+ Thy-1- cells alone generated no alloimmune CTL in response to alloantigens, suggesting that ASGM1+ NK cells contained no precursors of alloimmune CTL. When added into NK-depleted spleen cells, they restored the normal alloimmune CTL response of the spleen cells, indicating that ASGM1+ fractions contained cells to provide an accessory function for CTL generation. Lyt-1+ cells purified by panning methods did not restore the CTL response of NK-depleted spleen cells. These results indicate that ASGM1+ NK cells, but not Lyt-1+ helper T cells contaminating ASGM1+ fractions at undetectable levels, are responsible for the accessory function. When these purified ASGM1+ Thy-1- cells were stimulated with allogeneic cells, they produced IL 2 and IFN.(ABSTRACT TRUNCATED AT 400 WORDS)     

Requirement for three distinct lymphokines for the induction of cytotoxic T lymphocytes from thymocytes

The induction of cytotoxic T lymphocytes (CTL) from CTL precursors requires a combination of antigen and lymphokine signals. To investigate lymphokine requirements for CTL generation, we used an assay in which helper T cell and accessory cell-depleted spleen cells or whole thymocytes were cultured with lectin (Con A) and lymphokines. This culture was followed by assessment of lectin-dependent cytolysis. High concentrations of recombinant interleukin 2 (R-IL 2) (100 U/ml) alone were not sufficient for lectin-mediated CTL induction from thymocytes, whereas 20 to 100 U/ml of R-IL 2 alone could induce a significant lectin-mediated CTL response from accessory cell-depleted spleen cells. Using thymocytes as responders, we found purified or recombinant interferon-gamma (IFN-gamma) did not cause cytolytic activity either in the absence of or in the presence of R-IL 2. However, supernatant from Con A-stimulated rat spleen cells (rat Con A SN) in combination with R-IL 2 could induce cytolytic activity, suggesting that several factors are required for CTL induction. Con A SN was fractionated by gel filtration and the fractions were tested for ability to induce CTL. In the presence of a low level of R-IL 2 (5 U/ml), fractions with a Mr of approximately 31,000 could induce CTL, and this activity was referred to as CTL differentiation factor (CDF). The peak fractions containing CDF activity did not have detectable IL 1, IL 2, IFN-gamma, or CSF activity. However, by add-back experiments and the use of blocking antibodies, a monoclonal antibody against the IL 2 receptor or antibodies against murine IFN-gamma, we demonstrated that CTL induction from mature thymocytes (L3T4-, Lyt-2+) requires CDF activity in addition to IL 2 and IFN-gamma.     

A novel cytotoxic T-cell clone that exhibits differential modes of recognition in the proliferative and cytolytic phase

A T-cell clone (1G8-H7) cytotoxic to P815Y mastocytoma (H-2d) has been established from spleen cells of a C3H/He mouse (H-2k) primed with P815Y cells by means of in vitro stimulation with irradiated C3H.H-2o(H-2KdDk) spleen cells. The clone 1G8-H7 was an interleukin 2 (IL-2)-dependent and H-2Kd antigen-dependent CTL clone and it killed P815Y cells but not Concanavalin A-induced spleen blast cells bearing H-2Kd antigen. The involvement of H-2Kd antigen in the cytolytic recognition mechanism was shown by the inhibition of lysis by anti-H-2Kd monoclonal antibody and also by the cold inhibition experiment that employed H-2Kd-bearing spleen cells. Comparison of cytotoxic activities between 1G8-H7 and Kd-specific CTL clones showed that the killing of P815Y cells by clone 1G8-H7 was not explained by the susceptibility to cell-mediated cytolysis of P815Y cells. These results suggest that H-2Kd antigen on the stimulating cell is sufficient to deliver a proliferation signal in the proliferative phase of this clone, but in the cytolytic phase an additional interaction with surface structure on the target cell other than that with H-2Kd antigen is required for the induction of cytolysis. Possible elucidations for the differential modes of recognition are discussed.     

Poly-(ADP-ribose) polymerase partially contributes to target cell death triggered by cytolytic T lymphocytes.

We hypothesized that CTL-induced target cell (TC) death is partially due to processes that follow the DNA damage in target cells and include the activation of poly-ADP-ribose transferase (PADPRT) by DNA strand breaks. According to this model, the activated PADPRT is expected to deplete NAD, ATP, and to contribute to the TC death. We used inhibitors of PADPRT and a PADPRT-deficient cell mutant, as well as other nucleated TC and SRBC to test the role of PADPRT in CTL-induced cytotoxicity. It is found that inhibitors of PADPRT (3-aminobenzamide, benzamide (aromatic amides)) and nicotinamide all inhibit the CTL-mediated lysis of both Ag-specific TC and of Ag-nonbearing TC. The effect of PADPRT inhibitors was not due to inhibition of the lethal hit delivery by CTL, because in parallel control experiments, the same inhibitors did not interfere with CTL-induced lysis of SRBC, cells that are devoid of nuclei and PADPRT. Moreover, the effect of inhibitors of PADPRT did not affect earlier stages of lethal hit delivery because 3-aminobenzamide and benzamide did not interfere with CTL-induced DNA fragmentation in TC at concentration which protected TC lysis. Importantly, a PADPRT-deficient cell line was also much more resistant to CTL-induced lysis as tested in retargeting (4 and 8 h) assays; this was expected if activation of PADPRT is indeed involved in TC death. Control experiments reveal that the relative resistance of the PADPRT-deficient cell mutant to CTL-induced lysis was not related to its impaired ability to form conjugates and to trigger CTL (as tested in granule exocytosis assay). In addition, PADPRT-deficient cells were as susceptible to CTL-induced DNA fragmentation as were the control cells; yet, they were resistant to CTL-induced 51Cr-release. Control cells and PADPRT-deficient mutant were equally susceptible to antibody+C'-mediated lysis. Our data support the view that the activation of PADPRT can contribute to the CTL-induced cytolysis of some TC, but is not involved in lysis of other TC, as evidenced by the ability of CTL to efficiently lyse SRBC. These data suggest that there could be multiple molecular pathways of TC death in CTL-mediated cytotoxicity and the relative contribution of PADPRT and/or other enzymes will reflect the individual make-up of a particular TC.     

Cytotoxic T lymphocyte unresponsiveness induced by prolonged treatment with immobilized anti-CD3 antibody. Association of impairment of cytolytic activity with temporary depletion of intracellular protein kinase C

In our study we investigated the effect of pretreatment of bulk CTL and CTL clones with immobilized anti-CD3 antibody (Ab) or PMA. Primary CTL and CTL clones were cultured in dishes coated with anti-CD3 Ab or in medium containing PMA (5 nM) and assayed for Ag-specific or Ag-nonspecific "redirected" cytolysis using FcR+ P815 cells as targets. Cytotoxic activity of bulk CTL and five of six CTL clones tested in this study were inhibited by prolonged (longer than 6 h) pretreatment with immobilized anti-CD3 Ab or PMA, whereas proliferation of CTL clones or expression of surface CD3 molecules were not. The intracellular granule enzyme (N-alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester esterase) activity of CTL clones was not reduced under these suppressive conditions, indicating that the incompetence of CTL is not merely due to depletion of cytolytic granules by chronic stimulation. The suppressed cytotoxicity could be recovered by culturing CTL without perturbation of CD3 molecules for 24 h. In one exceptional clone, BM10-37, pretreatment with immobilized anti-CD3 Ab or PMA did not suppress the cytotoxic activity. Immunostaining of intracellular protein kinase C (PKC) revealed that PKC was depleted after prolonged treatment with immobilized anti-CD3 Ab or PMA in those susceptible CTL clones but not in the resistant BM10-37. These findings lead us to conclude that prolonged stimulation of CD3 of CTL results in depletion of PKC and that PKC may be essential for signal transduction to deliver a lethal hit to the target cells.     

Interactions between T and B lymphocytes and macrophages in the production of leukocyte adherence inhibition factor

Increasing concentrations of concanavalin A (ConA) were found to increasingly inhibit immunologically specific cytotoxic T lymphocyte (CTL)-mediated cytolysis. Even concentrations of ConA that best enabled nonspecific cytolysis were found to inhibit immunologically specific cytolysis by the same population of effector cells. Higher concentrations of ConA inhibited both specific and nonspecific cytolysis. Similar increasing concentrations of succinyl ConA enabled nonspecific lysis by CTL but did not appreciably inhibit specific lysis by the same cells. Increasing concentrations of ConA inhibited cytolysis and capping of the Thy 1.2 surface antigen to comparable degrees in the same effector cell population. These results indicate that ConA may inhibit CTL-mediated cytolysis by interfering with the mobility of certain moieties on the effector cell surface.     

The protein kinase C inhibitor 1-(5-isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride (H-7) inhibits PMA-induced promiscuous cytolytic activity but not specific cytolytic activity by a cloned cytolytic T lymphocyte

Phorbol 12-myristate 13-acetate (PMA) induces the cytolytic T lymphocyte (CTL) clone 4D (H-2b anti-H-2d) to promiscuously kill the inappropriate target EL-4 (H-2b). The protein kinase C (PKC) inhibitor 1-(5-isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride (H-7) inhibited the PMA-induced promiscuous lympholysis. The concentration of H-7 that inhibited PMA-induced lympholysis by 50% (IC50) was calculated to be 4 microM, which closely approximates the reported IC50 of H-7 of 6 microM for PKC activity in vitro. In striking contrast, specific cytolysis of appropriate P815 (H-2d) target cell by CTL clone 4D was not inhibited by concentrations of H-7 which inhibited PMA-induced promiscuous lympholysis. These results indicate that PMA-induced promiscuous lympholysis of inappropriate target cell is triggered via activation of PKC, whereas PKC activation is not obligatory in triggering CTL clone 4D to specifically kill appropriate target cells. Thus, these data suggest that cloned CTL have two or more triggering mechanisms than may initiate one or more cytolytic pathways.     

Cytotoxic T lymphocyte (CTL)-mediated cytolysis proceeds in the absence of Na+/H+ antiport activity: regulation of cytosolic pH by the Na+/H+ antiport in a cloned CTL.

Cytotoxic T lymphocyte (CTL)-mediated cytolysis of specifically bound target cells (TC) is thought to be triggered by cross-linking the T-cell antigen receptor (TcR). Biochemical events associated with TcR cross-linking include increased intracellular calcium levels [Ca2+]i, hydrolysis of phosphatidylinositol (PI), and an increase in intracellular pH [pH]i. Whereas CTL-mediated cytolysis of some TC is calcium-dependent, and PI hydrolysis is speculated to trigger the CTL lethal hit via activation of PKC, little is known about changes in [pH]i relating to activation of the lethal hit stage. We report regulation of [pH]i in a cloned CTL by the electroneutral Na+/H+ antiport during activation with PMA and specific antigen-bearing TC. Furthermore, using 5-(N-methyl-N-isobutyl) amiloride (MIBA), a potent antiport inhibitor, we demonstrate that Na+/H+ exchange is not required for activation of CTL cytolytic activity.     

In vitro secondary generation of cytotoxic T lymphocytes in mice with mumps virus and their mumps-specific cytotoxicity among paramyxoviruses.

Murine cells (L929, MC57G, and P815 mastocytoma) defectively infected with the egg-adapted vaccine strain of mumps virus were found to be susceptible to cytotoxic T-lymphocyte (CTL)-mediated lysis. In vitro secondary, but not in vivo primary, generated CTL caused cytolysis of these targets in an H-2-restricted manner. UV-inactivated-mumps virus-coated murine cells were also found to be susceptible to CTL-mediated lysis. Comparisons of murine CTL-mediated lysis by three paramyxoviruses (mumps, Sendai, and Newcastle disease viruses) indicated that no cross-reactivity occurred. The CTL response with mumps virus exhibited specific unresponsiveness patterns, as influenced by the H-2 K/D regions of the mouse strains, that were partially different from those of Sendai virus and Newcastle disease virus.     

Mechanisms of lymphocyte-mediated cytotoxicity. I. The effects of anti-human lymphotoxin antisera on the cytolysis of allogeneic B cell lines by MLC-sensitized human lymphocytes in vitro

Goat and rabbit anti-human lymphotoxin sera, IgG and F(ab')2 reagents were investigated for their capacity to effect a specific alloimmune lymphocyte-mediated cytotoxic reaction. The cytotoxic reaction employed human peripheral blood or adenoid lymphocytes sensitized in MLC to allogeneic B lymphocyte cell lines and lysis was measured in a short-term 51Cr-release assay. A polyspecific anti-LT sera (anti-WS), made against unfractionated whole supernatants from lectin-activated lymphocytes and its IgG and F(ab')2 fragments, was found to be a potent inhibitor of this reaction when the anti-WS reagent was present throughout the assay period. Absorption studies indicated the anti-WS was inhibiting cytolysis at the level of effector cell or its products. Two broadly defined antibody specificities were involved in the cytolytic-inhibitory activity of the polyspecific anti-LT; i) antigens present on the normal lymphocyte cell surface; and ii) lymphocyte surface antigens associated with activated cells. These results correlate with the previously defined antigenic structure of the LT Cx and alpha H classes. Anti-LT sera reactive with the smaller m.w. alpha and beta classes and subclasses were not inhibitory, although the anti-beta sera showed a moderate enhancing activity. The results indicated that several anti-LT antibody specificities may be required to inhibit alloimmune cytolysis. The results suggest LT molecules may mediate lymphocyte-induced alloimmune cytolysis as a multi-component toxin system, rather than as an individual toxin.     

Ontogeny of cell-mediated cytotoxicity: induction of CTL in early postnatal thymocytes.

In this study we characterized the time when cytotoxic T lymphocytes (CTL) can be induced in the thymus and spleen from their immediate CTL precursors (CTL-P). In contrast to fetal or newborn thymus, the thymus of 1 to 2-day-old C57BL/6 mice contained cells that, after cultivation in vitro with allogeneic DBA/2 stimulating cells, exhibited high levels (as great or greater than that induced in adult thymocytes) of CTL activity as measured by the ability to lyse P815 (DBA/2) tumor target cells. However, CTL activity induced in spleen cells remained how during the first 5 days of life, increased sharply between 6 to 9 days, and reached adult levels at 11 to 20 days. Furthermore, early postnatal spleen cells did not suppress the adult splenic CTL response. These results suggest 1) that the full potential to generate CTL in response to an allogeneic stimulus commences in the thymus on the first day after birth and 2) a different temporal appearance of immediate CTL precursors in the thymus and spleen.     

Generation of cytolytic T lymphocytes in vitro. X. Induction of primary and secondary CTL responses by the mitogen sodium periodate.

Short-term (15 min) sodium periodate (NaIO4) treatment of mouse spleen cells previously primed in vivo or in vitro against alloantigens induced the formation of secondary (2 degree) cytolytic T lymphocytes (CTL) specific for the priming antigens. CTL formation was readily demonstrable within 24 hr after treatment.This early CTL response occurred equally well in the presence or absence of cytosine arabinoside (Ara C), indicating that NaIO4 could induce CTL independently of DNA synthesis. Forty-eight hours after periodate treatment, the lytic activity was similar to that observed in parallel cultures stimulated with irradiated allogeneic spleen cells, although the peak activity was reached earlier (day 4) and was somewhat lower than that induced by alloantigen. The addition of irradiated NaIO4-treated unprimed syngeneic spleen cells to cultures of untreated alloimmune spleen cells also led to CTL formation, which suggests an indirect mechanism of activation. In contrast to alloimmune spleen cells, normal spleen cells treated with NaIO4 developed only very low levels of cytotoxicity after 4 days of incubation. However, in the presence of PHA, such cells were capable of lysing syngeneic and allogeneic target cells.     

A rat anti-mouse T4 monoclonal antibody (H129.19) inhibits the proliferation of Ia-reactive T cell clones and delineates two phenotypically distinct (T4+, Lyt-2,3-, and T4-, Lyt-2,3+) subsets among anti-Ia cytolytic T cell clones

Hybridoma H129 .19 was derived by fusion between spleen cells of a Lou / Ws1 rat immunized with an Lyt-1+,2- anti-I-Ak cytolytic T lymphocyte (CTL) clone and the nonsecreting myeloma X63-Ag8.653. The monoclonal antibody (mAb) H129 .19 (IgG2a, kappa) was selected for its capacity to inhibit the lytic potential of the immunizing clone. H129 .19 identified a monomorphic determinant on a 55 m.w. murine T cell differentiation antigen, which appeared to be homologous to the human T4 molecule in that: 1) H129 .19 reacted with 80% adult thymocytes, with a subset of splenic T cells, and with the interleukin 2 (IL 2)-producing EL4 thymoma; 2) The mAb bound to and inhibited the IL 2 production and the proliferation of various allo- or soluble antigen-reactive T cell clones that recognized restriction or activating determinants on the I-A or I-E molecules, respectively; 3) H129 .19 did not inhibit the proliferation and/or cytolysis of Lyt-2,3+ T cells specific for class I MHC antigen; and 4) Among six anti-Iak CTL clones examined in this study, the mAb H129 .19 reacted with two I-Ak-specific, Lyt-2,3- clones on which it exerted strong cytolysis inhibiting effect at the effector cell level. By contrast, two other anti-I-Ak and two anti-I-Ek CTL clones were found to express the Lyt-2,3+,T4- cell surface phenotype. The cytolytic potential of the latter clones was not inhibited by anti-Lyt-2,3 mAb. These studies strongly suggest that the mouse T4 molecule facilitates the recognition of class II MHC antigen by most but not all T cells.     

Isolation and characterization of novel suppressor T cell clones from murine fetal thymus

Murine fetal thymus from C57BL/6J (B6) and DBA/2J contains a cell population that suppresses CTL responses to alloantigens. This suppressor cell population was found to exist in high frequency in murine fetal thymus at the 14th day of gestation. The activity of this cell in the thymus declined rapidly with increasing time of gestation, and suppressor activity in the thymus was undetectable by the time of birth. On the other hand, suppressor activity could be detected in organ cultures of 14-day fetal thymus even after the organs were cultured for 14 or 21 days. Fetal thymocytes from B6 or DBA/2J mice were grown as long-term lines in interleukin 2 (IL 2)-containing medium. Clones of suppressor cells were derived from long-term cultures by micromanipulation. The clones had an average doubling time of 13 to 16 hr and were dependent on IL 2 for growth. The clones were 10- to 100-fold more efficient in suppressing CTL responses to alloantigens than day 15 fetal thymocytes. Analyses of cell surface molecules with the use of monoclonal antibodies and conventional anti-H-2 sera by radioactive binding assays showed that cloned suppressor cells from B6 fetal thymus were Thy-1 and Lyt-2+, and expressed little or no L3T4, Lyt-1, H-2K, H-2D, and class II molecules. The suppressor clones lacked the cytolytic activity of conventional CTL and also served as very poor target cells in CTL-mediated cytolysis. The suppressor function of the cloned cells was radiation-resistant, and this suppression could not be reversed by the addition of excess exogenous IL 2. The cloned cells suppressed CTL responses only when they were added within the first 48 hr of a 5-day culture period. Analyses of the antigen specificity of the suppressor cells showed that they suppressed CTL responses in a nonantigen-specific manner.