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.     

Coordinate expression of cytolytic activity and cytotoxic T cell-specific carbohydrate antigens in a T cell hybridoma

The expression of cytotoxic T lymphocyte (CTL)-specific carbohydrate antigens (termed CT antigens) was studied by using a cytolytically inducible T cell hybridoma, KSH4.13.6. Expression of the CT determinants occurred concomitantly with the expression of cytolytic activity after induction of the hybrid with supernatants from Con A-activated rat spleen cells. Purified IL 2 was also proven to be effective in inducing cytolytic activity and CT antigen expression, but the time course of activation by IL 2 was prolonged as compared to activation by crude supernatants. Furthermore, the activation process was reversible because removal of the hybrid from inducing medium resulted in the loss of cytolytic capability and CT antigen expression. By separating the low and high expressors of CT antigen from an induced hybrid population, it was shown that the level of CT antigen expression correlated with the cytolytic ability of the hybrid. High expressors of CT antigen exhibited four- to 50-fold greater lytic activity than populations with low CT antigen levels. Binding experiments using lectins indicated that an increase in GalNAc-containing oligosaccharides also occurred on activation of the hybrid. This finding agrees with our results which indicated that the CT carbohydrate antigens are probably associated with O-linked glycans. Because our previous results with CTL clones indicated that the CT antigens were associated with the T200 glycoproteins, we performed immunoprecipitation experiments with surface-labeled induced and uninduced KSH4.13.6. The T200 glycoproteins were precipitated by the CT1 monoclonal antibody from the induced population, but not from the uninduced population. Furthermore, precipitation by the GalNAc-recognizing lectin from Vicia villosa revealed marked differences in the GalNAc-containing proteins between the induced and uninduced populations. Thus, the results indicate that the T cell-derived polypeptide hormone IL 2 is able to influence the glycosylation of specific proteins in CTL, which results in the appearance of carbohydrate antigens whose expression is linked to the activation state of the CTL.     

Interleukin 2 enhancement of lymphokine secretion by T lymphocytes: analysis of established clones and primary limiting dilution microcultures

The effect of exogenous interleukin 2 (IL 2) on lymphokine production by T lymphocytes was examined in two systems: the secretion of macrophage-activating factor (MAF) and interferon (IFN) by cloned long-term T cell lines, and a limiting dilution system for estimating the frequency of precursors of MAF-secreting cells in normal spleen. An IL 2-containing, MAF- and IFN-free supernatant from the EL-4 thymoma (EL-4 SN) significantly enhanced release of MAF and IFN by mitogen- or antigen-stimulated, cytolytic or noncytolytic T lymphocyte clones directed against alloantigens or Moloney leukemia virus-associated antigens. Highly purified IL 2 produced equivalent enhancement as EL-4 SN in cultures of alloreactive clones stimulated with concanavalin A. Kinetics experiments showed that EL-4 SN increased both the rate and duration of MAF release by T cell clones. EL-4 SN also increased MAF production when added during restimulation of limiting dilution cultures of positively selected Lyt-2+ and Lyt-2- C57BL/6 splenic T lymphocytes activated against DBA/2 alloantigens. This enhancement resulted in a threefold increase in the apparent precursor frequency of MAF-secreting cells among Lyt-2+ lymphocytes, but did not affect the frequency among Lyt-2- cells. Additional analysis indicated that average MAF production in cultures of Lyt-2-+ cells was sixfold lower than in cultures of Lyt-2- cells, and hence that EL-4 SN allowed detection of a significant proportion of Lyt-2+ cell cultures secreting low levels of MAF. Under these improved conditions, the MAF assay detected the majority of responding Lyt-2+ and Lyt-2- lymphocytes.     

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.     

Reversal of phorbol ester-mediated reduction of cloned T lymphocyte cytolysis by interleukin 2

During previous studies on the regulation of cloned T lymphocyte function, we observed that murine cytotoxic T lymphocyte (CTL) clones progressively lose the ability to lyse appropriate target cells during prolonged (24 to 48 hr) incubation with the tumor promoter phorbol myristic acetate (PMA). We further observed that the cytolytic function of PMA-treated CTL clones can be restored by incubation with secondary MLC supernatant (2 degrees MLC SN), a potent source of cytokines. We now report our observations on the nature of the cytokine(s) responsible for recovery of CTL activity. Like 2 degrees MLC SN, the lectin-induced SN from a cloned helper T cell and the lectin-induced SN from a T cell hybridoma can restore cytolytic activity to cloned CTL treated with PMA. In contrast, supernatants from L929 cells, WEHI-3 cells, and P388D1 cells fail to restore cytolytic activity to similarly treated cloned CTL. These data suggest that IL 2 and/or gamma-IFN, but not CSF-1, CSF-GM, IL 3, or IL 1, can influence expression of cytolysis by cloned CTL. Furthermore, highly purified IL 2 can restore cytolytic activity, even when cytosine arabinoside is present to inhibit clonal expansion. Our studies indicate that cytolysis is a reversible function of cloned CTL, and that cytolysis may not necessarily represent an end-stage feature of CTL maturation. Our studies further show that IL 2 is both necessary and sufficient for resumption of cytolytic function by "deactivated" CTL. As such, these observations suggest that IL 2 can regulate not only T cell proliferation but also the expression of cytolysis by some cytolytic T cell populations.     

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.     

Coordinate production by a T cell hybridoma of gamma interferon and three other lymphokine activities: multiple activities of a single lymphokine?

The T cell hybridoma FS7-20, produced by the fusion of normal B10.BR T cells to the AKR thymoma BW5147, was found when stimulated with concanavalin A (Con A) to produce the lymphokines: interleukin 2 (IL 2), interferon-gamma (IFN gamma), macrophage-activating factor (MAF), Ia induction factor IaIF), and the B cell helper factor interleukin X (IL X). The clones and subclones of FS7-20 varied dramatically in their ability to produce these lymphokines, presumably because of karyotypic variations. The ability to produce IL 2 segregated independently from the ability to produce the four other lymphokine activities; however, production of the latter activities showed a strong correlation. This coordinate production of IFN gamma, MAF, IaIF, and IL X was also observed with a cloned normal cytotoxic T cell line, cr15. These results suggest either that IFN gamma, MAF, IaIF, and IL X are all manifestations of a single molecular species or that, although these activities are different structurally, their production is controlled by a common genetic mechanism. In support of the first possibility, the IFN gamma, MAF, IaIF, and IL X activity produced by FS7-20 were all found to be equally sensitive to inactivation at pH 2. These results illustrate the usefulness of using T cell hybridomas for the study of lymphokines.     

A helper factor needed for the generation of mouse cytolytic T lymphocytes is made by tumor cell lines, cloned T cells, and spleen cells exposed to a variety of stimuli

A helper factor termed cytolytic T lymphocyte helper factor (CHF) that is needed for the generation of allospecific mouse cytolytic T lymphocytes (CTL) in vitro was produced by mouse spleen cells 3 to 4 days after the time when interleukin 2 (IL 2) had reached its maximal production. These kinetics were observed by stimulation of immune spleen cells with allogeneic tumor or spleen cells, with Sendai or influenza viral peptides, with virus infected cells, or with concanavalin A (Con A). CHF produced by rat spleen cells was able to help in the generation of mouse CTL, indicating that this cytokine was not restricted genetically. CHF could also be made by WEHI-3 and EL4 cell lines, as well as cloned cytolytic and helper T cells. The production of CHF by WEHI-3 cells argues that CHF is not IL 2. In addition, if CHF was not present early in the in vitro stimulation no CTL were generated, suggesting that CHF participated in the activation of CTL precursors. The addition of IL 2-containing conditioned medium to the CHF assay resulted in no substantial CTL generation, although significant cellular proliferation was observed. In contrast, CHF-containing conditioned medium allowed the generation of CTL in the absence of the same level of proliferation.     

Antigen-reactive cloned helper T cells. II. Exposure of murine cloned helper T cells to IL 2-containing supernatant induces unresponsiveness to antigenic restimulation and inhibits lymphokine production after antigenic stimulation

Cloned murine helper T lymphocytes (HTL) reactive to alloantigen or to ovalbumin (OVA) become unresponsive to antigenic restimulation after exposure to antigen or to culture supernatant fluids (SF) containing multiple lymphokine activities. Unresponsiveness is manifest by a failure of antigen-stimulated cells to incorporate thymidine or to produce lymphokines after antigenic challenge. Antigen-unresponsive HTL, however, will incorporate thymidine when exposed to an exogenous source of interleukin 2 (IL 2). The duration of unresponsiveness to antigen is correlated with the concentration of IL 2 in SF to which the cloned HTL had been exposed. Chromatographic fractionation of IL 2-containing supernatant from EL-4 thymoma cells (EL-4 SF) yielded a pool of SF that was enriched for IL 2 activity. Exposure of HTL to lymphokines contained in this pool induced unresponsiveness to antigen that was comparable to that observed when HTL were exposed to unfractionated EL-4 SF. Unresponsiveness to antigen also developed after cloned HTL were stimulated with concanavalin A (Con A) or with OVA and syngeneic splenic filler cells. We have used monoclonal antibody (mAb) GK1.5 (anti-L3T4) to investigate the role of lymphokine production in the induction of unresponsiveness. This antibody did not inhibit IL 2-induced thymidine incorporation by cloned HTL, and did not inhibit the induction of unresponsiveness after exposure of cloned HTL to EL-4 SF. In the presence of mAb GK1.5, however, HTL that were stimulated with Con A or OVA did not become unresponsive to antigenic restimulation, an effect that was overcome by the addition of EL-4 SF. These results suggest that HTL become unresponsive to antigen after exposure to IL 2-containing SF, and that stimulation by antigen or Con A can induce the unresponsive state by virtue of stimulating lymphokine production.     

Positively selected Lyt-2+ and Lyt-2- mouse T lymphocytes are comparable, after Con A stimulation, in release of IL 2 and of lymphokines acting on B cells, macrophages, and mast cells, but differ in interferon production

Purified mouse T lymphocytes were separated into Lyt-2+ and Lyt-2- populations by the procedure of panning, in which a monoclonal rat anti-Lyt-2 antibody and dishes coated with affinity-purified mouse anti-rat Ig antibodies were used. The populations obtained were 95 to 99% pure as determined by immunofluorescence. Graded doses of these T cells were cultured with optimal mitogenic doses of concanavalin A and the 0 to 24 and 24 to 48-hr culture supernatants were collected. The dose-curve assays of the supernatants of Lyt-2+ and Lyt-2- cells showed comparable activity in interleukin 2 (IL 2) and T cell-replacing factor (TRF), assayed on antigen-stimulated culture of T-depleted spleen cells. Limiting dilution assays of IL 2-secreting precursor cells stimulated by Con A showed a high frequency of precursors in both populations, slightly higher among Lyt-2- cells. The supernatants also contained comparable levels of IPA (inducer of plasminogen activator production by the macrophages), MAF (macrophage-activating factor, assayed by induction of their cytolytic function), and MCGF (mast cells growth factor, assayed on a mast cell line). IPA and MAF were not produced with the same kinetics and in the same T cell concentration conditions as IL 2 and TRF. In contrast, interferon was principally produced by the Lyt-2+ cells.     

Retrovirus-mediated immunosuppression. II. FeLV-UV alters in vitro murine T lymphocyte behavior by reversibly impairing lymphokine secretion

Murine splenocytes and cloned murine T cells were used to study the in vitro immunosuppressive effects of UV-inactivated feline leukemia virus (FeLV-UV) on lymphokine secretion. FeLV-UV can significantly depress the accumulation of IL 2 in cultures of Con A-stimulated C57BL/6 splenocytes and in cultures containing the alloreactive helper T cell clone B6D/2-2m plus Con A. Inhibition of lymphokine accumulation in these cultures could not be attributed to absorption or inactivation of IL 2 by the FeLV-UV or to the FeLV-UV-induced production of substances which interfere with the IL 2 bioassay. Thus, FeLV-UV appears to block production and/or secretion of IL 2 by a direct inhibitory effect on IL 2-secreting murine T lymphocytes. Additional studies indicate that FeLV-UV impairs IL 2 production only if added very soon after lymphocyte contact with lymphokine-inducing agents and that IL 2 secretion resumes when FeLV-UV is removed from the culture. FeLV-UV also impairs accumulation of MAF (interferon-gamma?) in cultures of Con A-stimulated C57BL/6 splenocytes and in cultures containing the alloreactive cytotoxic T lymphocyte clone B6D/2-7c plus Con A. The latter observation again suggests that FeLV-UV impairs lymphokine secretion by a direct effect on lymphokine-producing T lymphocytes. Furthermore, it suggests that FeLV-UV does not selectively impair production of IL 2 nor does it have selective inhibitory effects on helper T cells. Rather, FeLV-UV appears to have a general inhibitory effect on lymphokine production by T lymphocytes. Finally, concentrations of FeLV-UV which suppress MAF production by the CTL clone have little influence on the cytolysis mediated by the same cloned T cell population. Thus, the immunosuppressive influence of FeLV-UV is selective for phenomena associated with induction of new T lymphocyte functions, such as lymphokine secretion, and spares other immune functions already expressed by the same cells.     

B cell helper factors. II. Synergy among three helper factors in the response of T cell- and macrophage-depleted B cells

The concanavalin A- (Con A) stimulated supernatant of normal spleen cells (normal Con A SN) was shown to contain a set of helper factors sufficient to allow T cell- and macrophage- (M phi) depleted murine splenic B cells to produce a plaque-forming cell response to the antigen sheep red blood cells (SRBC). The activity of normal Con A SN could be reconstituted by a mixture of three helper factor preparations. The first was the interleukin 2- (IL 2) containing Con A SN of the T cell hybridoma, FS6-14.13. The second was a normal Con A SN depleted of IL 2 by extended culture with T cell blasts from which the 30,000 to 50,000 m.w. factors were isolated (interleukin X, IL X). The third was a SN either from the M phi tumor cell line P388D1 or from normal M phi taken from Corynebacterium parvum-immune mice. The combination of all three helper factor preparations was required to equal the activity of normal Con A SN; however, the M phi SN had the least overall effect. The M phi SN and IL 2 had to be added at the initiation of the culture period for a maximal effect, but the IL X preparation was most effective when added 24 hr after the initiation of culture. These results indicate that at least three nonspecific helper factors contribute to the helper activity in normal Con A SN.     

Human T-cell hybridomas producing lymphokines. II. Enhancement of lymphotoxin secretion from human T-cell hybridomas by phorbol myristate acetate

Human lymphotoxin (LT)-producing T-cell hybridomas were constructed by fusing concanavalin A-activated human peripheral blood lymphocytes with emetine-actinomycin D-pretreated human acute lymphatic leukemia cells. LT secretion from these hybridomas was considerably enhanced by stimulation with phorbol-12-myristate-13-acetate (PMA) and concanavalin A or PMA alone. A study using cloned hybrid lines revealed that PMA/Con A acted directly on the LT-producing clones. Furthermore, PMA/Con A stimulated A-B9-24, one of the cloned hybridomas, and secreted fourfold larger amounts of LT under serum-free conditions than under serum-containing conditions. However, MIF/MAF and LT-producing cloned hybrid line E10-20 secreted rather decreased amounts of MIF/MAF when stimulated with PMA, while the LT secretion from the same hybridoma was enhanced with PMA.     

The mitogenic activity of staphylococcal enterotoxin B (SEB): a monovalent T cell mitogen that stimulates cytolytic T lymphocytes but cannot mediate their lytic interaction

Staphylococcal enterotoxin B (SEB), a monovalent T cell mitogen and inducer of T suppressor cells, was found to be a potent polyclonal activator of cytolytic T lymphocytes (CTL) effective against concanavalin A (Con A)-treated target cells. In addition to polyclonal stimulation of CTL, SEB could reactivate "memory" CTL, alloimmunized 60 to 90 days earlier, into "secondary" CTL detectable as early as 24 hr after onset of stimulation and specific for the original priming target cells. Optimal cytolytic activity was induced at 0.5 to 10 micrograms/ml SEB; optimal priming time was 3 days, correlating well with the proliferative activity and morphologic transformation of small lymphocytes into large T lymphoblasts. Long-term cultures of splenocytes, stimulated by SEB, continued to express high cytolytic activity. It is noteworthy that although SEB and Con A are comparable CTL inducers, SEB, unlike Con A, is an ineffective mediator of nonspecific, CTL/target cell interactions. To the best of our knowledge this is the first example of a CTL inducer unable to mediate CTL-target interaction and lysis. The latter observations suggests that different receptors are involved in CTL activation and in CTL-target interaction resulting in lysis.     

Molecular mechanisms involved in T cell activation. II. The phosphatidylinositol signal-transducing mechanism mediates antigen-induced lymphokine production but not interleukin 2-induced proliferation in cloned cytotoxic T lymphocytes

The phospholipid metabolism of cloned murine cytotoxic T lymphocytes (CTL) was examined under conditions in which the induction of proliferation by interleukin 2 (IL 2) and the stimulated production of lymphokine (macrophage-activating factor (MAF] by concanavalin A (Con A) and specific antigen occurred independently of each other. Activation of the CTL by either of the latter two stimuli resulted in changes in the metabolism of phosphatidylinositol (PI) that were early (less than 2.5 min), specific, and prolonged (6 to 8 hr). These changes were primarily characterized by an increase in phosphatidic acid (PA) and PI, with a decrease in phosphatidylinositol-4,5-bisphosphate. The duration of these phospholipid responses, particularly PA and PI, approximated the minimum time of CTL-stimulus interaction required to produce maximal titers of MAF. No changes were observed in other major classes of phospholipids during 8 hr of continuous stimulation. Stimulation with an irrelevant antigen had no effect on CTL phospholipid metabolism. In contrast to specific antigen or Con A, the T cell growth factor IL 2 failed to elicit specific and early biosynthetic responses from PA and PI. Instead, there were nonspecific biosynthetic responses from all major phospholipid classes (including phosphatidylcholine and phosphatidylethanolamine, as well as PA and PI) which occurred between 1 and 6 hr after IL 2 stimulation. Both 1,2-diacylglycerol (DAG) and inositol phosphates (IP), the hydrolytic products of PI turnover, were produced in response to MAF-inducing stimuli, but neither were detected in response to the proliferative stimulus IL 2. Together, these results indicate that the hydrolysis of PI and the concomitant production of the putative second messengers DAG and IP are involved in signaling the production of lymphokines (MAF) by CTL. On the other hand, the failure of IL 2 to elicit a full-spectrum PI response suggests that signals mediating CTL proliferation may utilize an alternate and still undefined pathway.     

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.     

Increased ornithine decarboxylase activity and polyamine biosynthesis are required for optimal cytolytic T lymphocyte induction

The objective of the present investigation was to evaluate the requirement for increased ornithine decarboxylase (ODC) activity and polyamine biosynthesis in the induction of cytolytic T lymphocytes (CTL). In this regard, we have utilized alpha-difluoromethylornithine (DFMO), an irreversible inhibitor of ODC. DFMO treatment completely abrogated Con A-induced NW T-cell ODC activity. Similarly, DFMO treatment reduced putrescine and spermidine biosynthesis 100 and 87% respectively by the end of a 48-hr incubation period. Polyamine depletion reduced the Con A-mediated polyclonal induction of CTL by 52 and 81% at 24 and 48 hr of culture, respectively. The effect of DFMO on CTL induction could be reversed by the addition of exogenous putrescine. These data indicate that the observed effects of DFMO on CTL induction were mediated through inhibition of polyamine biosynthesis. Therefore, increased ODC activity and polyamine biosynthesis are required for optimal CTL induction. Furthermore, polyamine depletion did not impair IL-2 production; however, IL-2-dependent proliferation was reduced. These data are the first to discriminate between the requirement for polyamines with regard to IL-2 responsiveness, rather than IL-2 production, during a primary T-cell mitogenic response.     

Separable helper factors support B cell proliferation and maturation to Ig secretion

The 24-hr culture supernatant of Con A-activated spleen cells (SN) contains helper factors that enable maturation to high-rate polyclonal Ig secretion and enhance proliferation in cultures of mouse B cells activated with the F(ab')2 fragment of class-specific rabbit antimouse IgM antibody (anti-Ig). When interleukin 2 (IL 2), also called T cell growth factor, is removed from SN by absorption with an IL 2-dependent cell line at either 4 degrees C or 37 degrees C, all the helper activity for anti-Ig-activated B cells is also removed. Partial removal of IL 2 results in partial removal of helper activity for B cells. However, the IL 2-depleted SN appears to contain another helper factor, TRF, that enables anti-Ig-activated B cell cultures to mature to high-rate Ig secretion. This TRF activity is revealed by adding purified human IL 2 or an IL 2-containing supernatant of a cloned, lectin-activated T cell hybridoma line (FS6-14.13) to Il 2-depleted SN, which restores the polyclonal antibody response to anti-Ig. The hybridoma supernatant by itself supports proliferation of anti-Ig-activated B cell cultures, as measured by an increase in cell number, but not maturation to Ig secretion. This proliferative response is likewise IL 2 dependent, although purified IL 2 with anti-Ig is not sufficient. These experiments define separable combinations of factors acting on anti-Ig-activated B cell cultures, one of which (SN) results in both proliferation and maturation to high-rate Ig secretion, whereas the other (hybridoma supernatant) results in proliferation only. IL 2 appears to be an essential component of both combinations, although the target cell for IL 2 action in this system remains to be determined.     

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.     

Retrovirus-mediated immunosuppression. I. FeLV-UV and specific FeLV proteins alter T lymphocyte behavior by inducing hyporesponsiveness to lymphokines

Murine splenocytes were used to study the in vitro immunosuppressive effects of UV-inactivated feline leukemia virus (FeLV-UV). FeLV-UV blocks both alloantigen (DBA/2)-induced and Con A-induced proliferation of C57BL/6 splenocytes in a dose-dependent manner. Furthermore, C57BL/6 anti-DBA/2 mixed lymphocyte cultures containing FeLV-UV fail to develop detectable DBA/2-specific cytolytic activity, although FeLV-UV has no effect on the cytolytic activity of preformed C57BL/6 anti-DBA/2 cytolytic T cells (CTL). Disruption of lymphocyte proliferation and CTL generation by FeLV-UV could not be overcome by the addition of exogenous lymphokines. These data suggest that FeLV-UV can interfere with the lymphokine reactivity of alloactivated lymphocytes. In fact, FeLV-UV blocks the lymphokine-induced proliferation of the murine IL 2-dependent cell line CTLL-20. The CTLL-20 cells were subsequently used to study the mechanism(s) by which retroviruses alter T lymphocyte function. Normally, CTLL-20 cells undergo significant proliferation when cultured in EL4 SN, an IL 2-containing culture supernatant from PMA-stimulated EL4 cells. This lymphokine-induced CTLL-20 proliferation is abrogated in a dose-dependent manner by UV-inactivated murine leukemia virus (MuLV-UV), FeLV-UV, and a purified 15,000 dalton viral protein, p15, derived from FeLV. Suppression of CTLL-20 proliferation requires only brief contact (6 hr) with FeLV-UV or with p15, but is most efficient after prolonged (24 hr) contact with these agents. Furthermore, suppression of CTLL-20 proliferation by FeLV-UV and p15 is reversible, because CTLL-20 cells which have been pretreated for 24 hr with FeLV-UV or p15 are equally as efficient at responding to EL4 SN as untreated CTLL-20. Additional studies indicate that CTLL-20 cells continue to remove IL 2 activity from EL4 SN in the presence of suppressive concentrations of FeLV-UV, and that suppressive concentrations of FeLV-UV do not remove IL 2 activity from EL4 SN. This suggests that FeLV does not block CTLL-20 proliferation by absorbing or inactivating IL 2, or by occluding IL 2 receptors, and that T lymphocytes develop an insensitivity to lymphokines after contact with FeLV-UV, which may be caused by a metabolic, rather than an immunologic, defect. Because lymphokines are requisite signals for T cell function, considerable immunosuppression would be associated with acquired lymphokine insensitivity.