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.     

Antigen-specific Lyt-2+ cytolytic T lymphocytes from mice infected with the intracellular bacterium Listeria monocytogenes

In vitro expanded T cell lines were used to determine whether antigen-specific cytolytic T lymphocytes are generated after infection with the intracellular bacterium, Listeria monocytogenes. Spleen cells from infected mice were cultured in the presence of syngeneic accessory cells, listerial antigen, and interleukin 2 containing supernatants. Cell lines were greater than 98% Thy-1+, L3T4-, Lyt-2+. Bone-marrow macrophages were used as target cells in two in vitro cytolytic assay systems. The Lyt-2+ T cells killed bone marrow macrophages only when infected with L. monocytogenes as assessed in a 4-hr 51Cr release assay and in an 18-hr neutral red uptake assay. Cytolysis was blocked by anti-LFA-1 and anti-Lyt-2 monoclonal antibodies. These cytolytic T cells produced interferon-gamma after co-stimulation with antigen, accessory cells, and recombinant interleukin 2. Bone marrow macrophages infected with Mycobacterium bovis were not killed by T cells from L. monocytogenes-infected mice but by T cell lines from M. bovis-infected mice, indicating that cytolysis was antigen specific. L. monocytogenes-infected target cells of different haplotype were lysed by the Lyt-2+ T cells. By using a low cell density split culture system, antigen-specific, H-2-restricted cytolytic T cells could be identified. These findings demonstrate that during infection with intracellular bacteria, Lyt-2+ T cells with cytolytic activity are generated that may be involved in antibacterial protection.     

Resistance of primary CD8+ cytotoxic T lymphocytes to lysis by cytotoxic granules from cloned T cell lines

Recent evidence has shown that cloned, murine CTL cell lines are resistant to the cytotoxic components of the toxic granules they release upon specific interaction with their target cells. Inasmuch as the resistance might be due to selection in culture over many months by repeated exposure to these cytolytic components (which are released repeatedly as a result of the cultured CTL being periodically stimulated by target cells), we asked whether primary CTL are also resistant. The primary CTL were elicited in vivo by i.p. injection of allogeneic tumor cells or in vitro by 5- to 6-day MLC or by 48-h exposure to the lectin Con A. The responding cells were separated into purified CD8+ (i.e., CD4-, CD8+) and purified CD4+ (i.e., CD4+, CD8-) T cell populations that were analyzed for cytolytic activity and for resistance to lysis by toxic secretory granules derived from cloned CTL cell lines. The CD8+ T cells were highly cytolytic and relatively resistant; they retained their cytolytic activity and were lysed to a minimal extent (0 to 10%) by quantities of isolated granules that lysed 80 to 90% of the P815 tumor cell line (tested as a representative standard cell line). The CD4+ T cells, in contrast, had only minimal cytolytic activity and were far more susceptible to granule-mediated lysis. Although the resistance of primary CD8+ T cells is impressive, it is not as pronounced as the resistance of the cloned CTL cell lines, indicating that during long-term culture there is some selection for increased resistance to granule-mediated lysis. In contrast to T cells (especially CD8+ T cells), Ia+ macrophages, isolated from primary immune peritoneal exudates, were highly susceptible to granule-mediated lysis.     

A monoclonal antibody reactive with a 15-kDa cytoplasmic granule-associated protein defines a subpopulation of CD8+ T lymphocytes

We have recently described a novel method for the production and characterization of mAb reactive with T cell-restricted intracellular antigens. From a panel of antibodies that react specifically with permeabilized T lymphocytes but not with permeabilized B lymphocytes or native T cells, we have selected one, designated TIA-1, that reacts with 20 to 36% of digitonin permeabilized peripheral blood T lymphocytes. Flow cytometric analysis of purified CD4+ and CD8+ subsets showed TIA-1 to recognize a subpopulation of 49 to 64% of CD8+ lymphocytes. Little or no reactivity with CD4+ resting T lymphocytes was observed. TIA-1 did not react with any of a panel of T cell lines, B cell lines, or monocytoid cell lines. TIA-1 reacted strongly with NK cell clones and CD8+ cytolytic T cell clones, and less strongly with CD4+-activated T cell clones, suggesting a preferential expression in cells possessing cytolytic potential. Cell fractionation experiments showed TIA-1 to be membrane associated. Furthermore, Percoll gradient fractionation of a cytolytic T cell clone (T4T8C1) showed the majority of TIA-1 to be contained in a low density membrane fraction that also contained serine protease activity. Immunoelectron microscopy showed TIA-1 to decorate the membranes of electron lucent and electron dense cytoplasmic granules in this same cytolytic T cell clone. Biochemical analysis showed TIA-1 to be a 15-kDa protein in unstimulated T cells. Upon activation with Con A or anti-CD3 antibodies. TIA-1 was induced to form disulfide linked dimers, trimers, and tetramers of the basic 15-kDa unit. Taken together, our data suggest that TIA-1 is a cytolytic granule associated protein that may define a subpopulation of resting CD8+ T lymphocytes possessing cytolytic potential.     

Phytohemagglutinin-induced proliferation and cytolytic activity in T3+ but not in T3- cloned T lymphocytes requires the involvement of the T3 antigen for signal transmission

Proliferation and the cloning efficiency of T3+ but not T3- T cells are increased by the addition of lectins (phytohemagglutinin; PHA) to the culture medium. In contrast to that of T3+ cloned cell lines, the cytolytic activity of T3- clones is not enhanced by PHA, as we report here. We have investigated the effects of anti-T3 monoclonal antibody (MAb) and PHA on the proliferative capacity and cytolytic activity of various T3+ and T3- clones and cells to determine the possible involvement of the T3 receptor in these processes. We found that, in addition to inhibition of allospecific cytotoxicity, anti-T3 MAb can induce and/or enhance nonspecific cytolytic activity against particular target cells in cloned allospecific cytotoxic T cells (CTL) following preincubation of the effector cells with PHA or anti-T3. This enhancement of cytolytic activity is seen in T3+ but not T3- activated killer (AK) clones or fresh T3- natural killer (NK) cells and depends on the concentrations of anti-T3 MAb or PHA used. We conclude that the T3-Ti antigen-receptor complex is involved in the transmission of the activation signals by anti-T3 and PHA.     

Rapidly expanded activated human killer cell clones have strong antitumor cell activity and have the surface phenotype of either T gamma, T-non-gamma, or null cells

Cloned lymphoid cell lines showing cytolytic activity were derived from natural killer (NK) cell-enriched cell fractions obtained by fluorescence-activated cell sorting of cells that reacted with B73 .1, an NK cell-specific monoclonal antibody (MCA). The clones were cultured for more than 30 generations (i.e., more than 10(9) descendants from a single cell). The rapid expansion was achieved by using a special culture system developed for this purpose and based on the use of two types of allogeneic feeder cells. Three phenotypically different types of cytotoxic clones were obtained. These clones showed a broad spectrum of cytolytic activity against several NK-susceptible and NK-nonsusceptible tumor target cells. One of these clones had the following binding pattern to MCA: B73 .1+, T3-, T4-, T8-, HNK1 -, and Lyt-3-. These cells formed rosettes with IgG-coated erythrocytes but not with sheep erythrocytes, and therefore might be null cell-derived. Most of the cytotoxic clones showed the following phenotype: B73 .1+, T3-, T4-, T8-, HNK1 -, Lyt-3+, E+, and EA-gamma +. These clones were probably derived from T-gamma cells. In addition, one clone with cytolytic activity was derived from B73 .1- cells. This had the phenotype B73 .1-, T3+, T4-, T8-, HNK1 -, Lyt-3+, E+, and EA-gamma-, and may be of T-non-gamma cell origin. About 10 noncytolytic clones showed the phenotype B73 .1-, T3+, T4, or T8+, HNK1 -, Lyt-3+, Ia+, E+, and EA-gamma -. An absolute correlation was found between the presence of the B73 .1 antigen, the absence of the T3 marker, and the capacity of the cells to form EA rosettes. Furthermore, all clones except one (Lyt-3-) formed E rosettes. Although the in vitro life span varied from clone to clone, B73 .1- clones generally grew faster and for longer times (greater than or equal to 50 generations) than did B73 .1+ ones (less than or equal to 40 generations). The cytolytic activity, cell surface phenotype as determined with MCA, rosette formation, and target cell specificity spectrum remained stable over the entire culture period. We conclude that the majority of the activated MHC-nonrestricted cytolytic clones obtained in this culture system show a particular phenotype. These cells can be expanded to large numbers. Whether or not these clones might be derived from B73 .1+, HNK1 + NK cells with the morphologic appearance of large granular lymphocytes will be discussed.     

Inhibition of T cell-mediated functions by MVM(i), a parvovirus closely related to minute virus of mice

A purified preparation of MVM(i), a murine parvovirus closely related to minute virus of mice (MVM), was found to inhibit various functions mediated by murine T cells in vitro. Addition of MVM(i) virus to secondary allogeneic mixed leukocyte cultures resulted in the inhibition of both lymphocyte proliferation (3H-thymidine incorporation) and the generation of cytolytic T lymphocyte activity but not interferon production. MVM(i) virus also inhibited the growth and cytolytic activity of several cloned, long-term Lyt-2+ cytolytic T cell lines. Furthermore, the antigen-induced proliferative responses of parasite- (Leishmania) specific Lyt-1+ T cells in vitro was abrogated by the addition of MVM(i) virus to the culture. Finally, the suppression of an in vitro antibody response to SRBC by MVM(i) virus was the result of the inhibition of T helper cells required for the B cell response. These suppressive effects were specific for MVM(i); parallel studies in which the prototype MVM parvovirus was used showed no significant inhibition in the various systems tested.     

Protein-antigen specific Ia-restricted cytolytic T cells: analysis of frequency, target cell susceptibility, and mechanism of cytolysis

We previously showed that cloned, antigen-specific, Ia-restricted L3T4a+ T cell lines can be cytolytic for antigen-pulsed B cell lymphoma targets. Such cells can also, under different experimental conditions, activate B cells to proliferate and secrete immunoglobulin. In the present experiments, we show that this functional phenotype is a common one among a panel of cloned T cell lines. In keeping with this finding, freshly isolated, antigen-activated lymph node T cells show similar functional properties. Such cytolytic L3T4a+ T cells differ from classical H-2K/D-restricted cytolytic T cells in two distinct ways. First, Ia-restricted cytolytic T cells can kill bystander targets, whereas H-2K/D-specific cytolytic T cells do not. Second, in testing a panel of target cells by using lectin-mediated cytolysis, Ia-restricted cytolytic clones reveal large differences in target cell susceptibility, whereas all targets are similarly susceptible to H-2K/D-specific killer cells. Finally, evidence is presented that both direct and bystander killing effected by L3T4a+ T cells are mediated by the same soluble factors, in that there is a strong positive correlation of these two activities for individual cloned lines. The relevant mediators appear to be lymphotoxin and IFN-gamma, although the latter molecule by itself is not cytolytic on our target lines.     

Three different signals are required for the induction of cytolytic T lymphocytes from resting precursors

The requirement for the signals in induction of cytolytic T lymphocytes (CTL) has been investigated. C57BL/6 X CBA/T6 F1 spleen cells stimulated with the lectin leukoagglutinin (L-A) failed to show CTL activity in a PHA-facilitated assay, although L-A-activated splenic T cells were able to respond to T cell growth factor (TCGF). Concanavalin A (Con A) on the other hand was able to induce cytolytic activity from CTL-P, as well as to render splenic T cells responsive to TCGF. Furthermore, L-A-activated splenic T cells could generate cytolytic activity upon subsequent culture in secondary mixed leukocyte culture supernatant (2 degrees MLC SN). In contrast, EL-4-derived SN (EL-4 SN) was unable to induce cytolytic activity from L-A-activated spleen cells. In addition, proliferation of L-A-activated spleen cells cultured in EL-4 SN was similar to those cultured in 2 degrees MLC SN. Nonactivated spleen cells were totally unresponsive to both SN in proliferation and generation of CTL. Analysis of T cell clones for the production of a factor necessary for induction of cytolytic activity revealed that both cytolytic and noncytolytic T cell clones were able to produce a factor(s) for the generation of cytolytic activity from L-A-activated T cells. On the other hand, SN from certain antigen-stimulated T cell clones produced factors capable of inducing cytocytic activity by L-A-activated T cells only in the presence of EL-4 SN. Neither EL-4 SN nor cloned T cell SN alone had such a capacity. The nature of the necessary lymphokines in the SN from the clone cells or from the EL-4 is unknown. In the case of the EL-4 SN, it is not known whether the presence of TCGF plays a role or whether that role is perhaps more differentiative than proliferative. This study provides evidence that the induction of CTL from CTL-P can be dissociated into activation, which is required to render T cells responsive to second signals, and differentiation, which is mediated by two different factors.     

Telomere Length Dynamics in Telomerase-Positive Immortal Human Cell Populations

It has been proposed that the progressive shortening of telomeres in somatic cells eventually results in senescence. Previous experiments have demonstrated that many immortal cell lines have acquired telomerase activity leading to stabilization of telomere length. Telomere dynamics and telomerase activity were examined in the telomerase-positive immortal cell lines HeLa and 293 and subclones derived from them. A mass culture of HeLa cells had a stable mean telomere length over 60 population doublings (PD)in vitro.Subclones of this culture, however, had a range of mean telomere lengths indicating that telomeric heterogeneity exists within a population with a stable mean telomere length. Some of the subclones lacked detectable telomerase activity soon after isolation but regained it by PD 18, suggesting that at least some of the variation in telomere length can be attributed to variations in telomerase activity levels. 293 subclones also varied in telomere length and telomerase activity. Some telomerase-positive 293 subclones contained long telomeres that gradually shortened, demonstrating that factors other than telomerase also act to modulate telomere length. Fluctuations in telomere length in telomerase-positive immortalized cells may contribute to chromosomal instability and clonal evolution.     

Role of different lymphocyte subsets in human anti-viral T cell cultures

We have systematically studied uncloned human cell lines derived from anti-influenza A virus or anti-Epstein-Barr virus (EBV) bulk cultures, or from cultures highly enriched for CD4+ or CD8+ lymphocytes. The most noteworthy results are the following: (1) Anti-viral bulk cultures consisted of more than 90% of CD8+ cells in all cases. In contrast, anti-HLA cell lines are composed of approximately 50% CD8+ and 50% CD4+ cells. All of the CD8+ and CD4+ cells present in the culture were also 4B4+/2H4-. (2) In anti-viral bulk cultures, the cytolytic activity was restricted by HLA class I molecules and almost exclusively through a single HLA class I molecule. (3) Positively or negatively selected CD8+ lines showed the same restriction pattern. They grew less efficiently than bulk cultures but could be maintained in the absence of CD4+ cells. The CD4+ cells were however necessary at the beginning of the culture for the development of cytolytic anti-influenza virus CD8+ cells, whereas they were not required for the development of cytolytic anti-EBV CD8+ cells. (4) The CD4+ cell lines grew more actively than bulk cultures. A cytolytic activity for virus-infected cells was constantly detected in these culture from the third passage onward and it was always restricted by HLA class II molecules. This activity was maintained throughout the culture period. However, class II-restricted cytolytic cells were not detected during primary or secondary responses in vitro.     

Heritable lymphocyte function-associated antigen-1 deficiency: abnormalities of cytotoxicity and proliferation associated with abnormal expression of LFA-1

The effect of heritable LFA-1 deficiency on T lymphocyte function was measured. After primary mixed lymphocyte stimulation, all six patients studied showed diminished allospecific T lymphocyte cytolytic and NK activity as compared with kindred and normal controls. MLR and mitogen-induced proliferative responses were consistently depressed. LFA-1-deficient, EBV-transformed B cell lines were poor stimulators of T cell responses. Primary cytolytic responses by lymphocytes from severely LFA-1-deficient patients (less than 0.2% of normal surface expression) were consistently more profoundly depressed than those by lymphocytes from moderately deficient patients (about 5% of normal surface expression). These results demonstrate the importance of LFA-1 in lymphocyte function. After repeated MLR restimulation, proliferative and cytolytic capacity improved and CTL lines could be established from all patients. Cytolysis by lines from one but not a second severe patient, and by four of four moderate patients, was inhibited by anti-LFA-1 MAb, and at 10-fold lower concentrations than required for inhibition of killing by control CTL lines. The locus of inhibition was on the target cell for the severely deficient CTL line, and on both the target and effector cells for moderately deficient CTL lines. In contrast, the locus of inhibition for normal CTL is on the effector cell. These findings show that LFA-1 can participate bidirectionally in cell interactions. The in vitro results are discussed in terms of the clinical findings in patients.     

Vitronectin secretion by hepatic and non-hepatic human cancer cells

Summary Thirty-eight human cancer cell lines and subclones derived from 12 different organs were screened for vitronectin secretion in their culture media. By immunoblotting analysis we detected high secretion by three out of five hepatoma cell lines tested but no secretion by the others. In addition, significant secretion was observed in seven non-hepatic cancer cell lines and subclones derived from the cervix, lung, and pancreas. These vitronectin-secreting cells included PLC/PRF/5, HuH-6 #5, HuH-7, HeLa S3, HeLa · P3 #2, #3, #6, #8, A549, and MIAPaCa-2. The results were further confirmed by quantitative analysis using sandwich enzyme-linked immunoassay, and activity analysis of cell attachment promotion on Western blotted filters.     

Intercellular adhesion molecule-1 (ICAM-1) is involved in the cytolytic T lymphocyte interaction with a human synovial cell line

The cell surface molecules involved in the human cytolytic T lymphocyte (CTL)-synovial cell interaction may play an important role in T cell interactions with connective tissue mesenchymal cells. To examine the molecular basis for the CTL-synovial cell interaction, we immortalized synovial cell explants to establish the cell line SYN.SPP. The SYN.SPP cell line was compared to the established B lymphoblastoid cell line JY. Cell surface immunofluorescence demonstrated significantly different levels of the immunologically relevant cell surface molecules ICAM-1 and LFA-3. Both cell lines were used to stimulate CTL precursors. After several months in culture, CTL lines stimulated by the SYN.SPP and JY cell lines demonstrated HLA class I-directed cytolytic activity. The cell surface molecules utilized by the anti-SYN.SPP and anti-JY CTL lines were identified by monoclonal antibody (MAb) inhibition. MAb recognizing the CTL cell surface molecules CD3, CD8 and LFA-1 (CD11a) significantly inhibited CTL-mediated lysis of both target cells. An interesting observation was that the anti-SYN.SPP CTL line appeared to utilize the ICAM-1 and not the LFA-3 target cell molecule. In contrast, the anti-JY CTL line utilized the LFA-3 and not the ICAM-1 membrane molecule. These results indicate that CTL interactions with connective tissue mesenchymal cells may be regulated by a unique pattern of antigen nonspecific cell-cell interaction molecules.     

Optimization of sorting conditions for the selection of stable, high-producing mammalian cell lines.

The production of Green Fluorescent Protein in recombinant NIH3T3 mouse fibroblast cells was used as a model to determine the optimal conditions for the rapid isolation of high-producing cell lines with a fluorescence-activated cell sorter. "Bulk sorting", that is, sorting of a large number of positive cells, did not result in a stable, high-producing cell line due to overgrowth of high-producing cells by low- or nonproducing cells. The production kinetics and expression of GFP during batch culture was found to differ between NIH3T3 cells and HepG2 hepatoma cells, even though the same plasmid was used for transfection. The kinetics of product formation need therefore to be determined from case to case to select the optimal timepoint for analysis and sorting. Subcloning of sorted cells into microtiter plates only resulted in high-producing subclones when 1 or 2 cells were seeded per well. Higher seeding rates again resulted in overgrowth of low- or nonproducers. By subcloning, two high-producing cells lines could be isolated. They had a 10- and 15-fold higher fluorescent signal compared to the negative control. While one of these subclones started to decrease it's GFP expression after 2 months, the other clone stably expressed GFP for 4 months.     

Interferon-beta and recombinant IL 2 can both enhance, but by different pathways, the nonspecific cytolytic potential of T3- natural killer cell-derived clones rather than that of T3+ clones

We studied the enhancement of cytolytic activity of T3- natural killer cell-derived clones, of T3+ T cell activated killer (AK) clones, and of fresh peripheral blood lymphocytes (PBL) by various crude and recombinant interferon (r-IFN) as well as IL 2 preparations. It was found that IFN-beta had the highest cytotoxicity inducing potency as compared to crude or r-IFN-alpha or -gamma preparations. This enhancement was blocked by anti-IFN-beta antibodies but not by anti-IFN-gamma antibodies. IL 2 also strongly enhances cytolytic activity in cloned T3- killer cells that express the IL 2 receptors as determined with the anti-Tac monoclonal antibody (MAb) at concentrations of IL 2 (25 U/ml) which induced one-half of the maximal proliferation capacity in human T cells and murine CTLL cells. For enhancement of cytolytic activity in fresh NK cells, a much higher concentration of IL 2 is required. In addition, the enhancement of cytolytic activity by r-IL 2 but not that by IFN-beta can be reduced by anti-Tac MAb, suggesting that the IL 2 receptor is involved in the enhancement by IL 2, but not by IFN. Both IFN-beta and IL 2 were able to enhance (over threefold) the cytolytic activity of T3- cloned killer cells against a variety of tumor target cell types. Another remarkable observation was that K562 cells, the most commonly used target cell for determining NK cell cytolytic activity, are not the most suitable targets to assess enhancement of nonspecific lytic activity as compared to Daudi or lung tumor-derived cell lines. No enhancement of anti-body-dependent cellular cytotoxicity was observed. Finally, the effects of these biological response modifiers were much more pronounced on "fresh" and cloned T3- natural killer cell-derived than on T3+-activated killer mature T cell-derived clones.     

The generation of cytolytic activity in mixed leukocyte cultures: cortisone-resistant thymocytes are deficient in helper T lymphocytes

Cortisone-resistant (CR) thymocytes did not generate cytolytic activity toward H-2 K or D alloantigen unless they were also stimulated by H-2 I or non-H-2 alloantigens, even though spleen cells generated brisk cytolytic activity toward H-2 K or D alone. Backstimulation by stimulating strain T lymphocytes accounted for neither the response of spleen cells toward H-2 K or D alloantigen nor the response of CR thymocytes to a full set of alloantigens. In addition, lack of non-T accessory cells did not account for the CR thymocyte pattern of reactivity. Rather, CR thymocytes appeared to be relatively deficient in helper T lymphocytes (HTL). CR thymocytes generated specific cytolytic activity toward H-2 D alloantigen when T cell growth factors (TCGF) or cloned alloreactive helper T lymphocytes were added to culture. CR thymocytes contained fewer HTL precursors detected at limit dilution than spleen cells did. Thus spleen cells generated cytolytic activity toward class I alloantigens alone, but under the same culture conditions CR thymocytes had to be stimulated by both class I and class II alloantigens. Class II alloantigens may be required to stimulate cytolytic activity only under culture conditions in which class I-reactive HTL are not sufficient to provide a minimal threshold of help.     

Cytolytically active murine T-lymphocyte/polyoma virus-transformed fibroblast hybrids

It would be of great interest to obtain permanent T-cell lines retaining specific activity without either allogeneic or xenogeneic stimulation. Functionally active hybrids between cytolytic T cells and thymoma were previously reported, but they had to be selected in a TCGF-containing medium. This study contains new results and reports the preparation of a hybrid cell from a cytolytic T cell and a polyoma virus-infected fibroblast, in which the T-cell characteristics dominate over the polyoma-transformed characteristics. A differentiated T-cell function (i.e., cytolysis) persists and the differentiated line does not require TCGF. The loss of cytolytic activity during in vitro evolution may be due to a selection favouring transformed cells, as suggested by concomitant enhancement of the transformed phenotype and chromosome loss.     

Lymphokine-mediated induction of cytolytic activity in a T cell hybridoma

Functionally inducible CTL hybridomas were constructed by fusing alloantigen-specific T cells (C57BL/6 alpha-DBA/2) with cells from the rat thymoma line W/FU (C58NT)D. A cloned hybridoma line (KSH.4.13.6) that was specifically cytolytic in the presence of activated rat spleen cell supernatant fluid (rat Con A SN) lost activity when transferred to normal medium. However, a cytolytic activity could be reinduced by culturing KSH.4.13.6 cells in medium containing rat Con A SN or secondary mixed leukocyte culture SN. By using various sources of SN, it was found that cytolytic induction required two different factors. PMA-induced EL-4 SN and SN from antigen-activated cloned T cells, neither of which were capable of inducing cytolytic activity alone, were able to synergize in the cytolytic induction of KSH.4.13.6 IFN-gamma and IL 1 failed to induce cytolytic activity even in the presence of EL-4 SN. Furthermore, this hybridoma produced macrophage activating factor (MAF) upon culture in rat Con A SN, although MAF production could not be induced by either specific antigen or lectins. The kinetics of induction and loss of cytolytic activity mediated by rat Con A SN were similar to those of the induction of MAF production. However, EL-4 SN, which by itself was incapable of inducing cytolytic activity, was able to induce MAF production in the KSH.4.13.6 hybrid to an extent similar to that induced by rat Con A SN. These results suggest that the induction of cytolytic activity and of MAF production in this cloned hybridoma cell line are regulated by different mechanisms. Such a functionally inducible T cell hybrid may provide a tool for biochemical and molecular analysis of T cell function and regulation, and of the characterization of cytokines required for CTL differentiation.     

Perforin mRNA in primary peritoneal exudate cytotoxic T lymphocytes

Considerable evidence indicates that cloned CTL cell lines kill target cells by releasing toxic granules that contain a cytolytic protein, called perforin, and several serine esterases (granzymes A to F). However, primary CTL, such as the highly cytolytic peritoneal exudate lymphocyte (PEL) cell population, have been found by a hemolytic assay to have no perforin, or perhaps only borderline levels of that protein, suggesting that these cells use a different lytic mechanism. To determine whether or not primary CTL express the perforin gene, we have here compared mRNA from PEL CTL and from a cloned CTL cell line, 2C, by Northern blot analysis using a perforin cDNA probe. CD8+ PEL CTL contain approximately 30% of the amount of perforin message present in 2C. Moreover, depletion of CD8+ T cells from the total peritoneal exudate cell population removes both cytolytic activity and perforin message. We have previously shown that PEL CTL elicit the same changes in target cells as cloned CTL cell lines and are resistant to lysis by the toxic granules purified from these cells lines. Taken together these results are consistent with the view that primary CTL, as well as long term cloned CTL cell lines, exercise their cytolytic activity by means of perforin.