Signals involved in T cell activation. II. Distinct roles of intact accessory cells, phorbol esters, and interleukin 1 in activation and cell cycle progression of resting T lymphocytes

The signals involved in the initiation of mitogen-induced activation of resting guinea pig T cells were examined. The combination of phytohemagglutinin (PHA) and 4 beta-phorbol 12-myristate 13-acetate (PMA) stimulated DNA synthesis by accessory cell (AC)-depleted T cells cultured at high density, but the use of low density cultures indicated that intact AC were absolutely necessary for PHA-stimulated T cell DNA synthesis even in the presence of PMA, interleukin 1 (IL 1), or interleukin 2 (IL 2). In contrast, AC-depleted T cells were able to respond to the combination of the calcium ionophore, ionomycin, and PMA regardless of the cell density at which they were cultured. Cell cycle analysis by acridine orange staining indicated that neither PHA nor ionomycin, in the absence of AC, activated resting T cells. PMA in the absence of all AC, supported cell cycle entry and progression to the DNA synthetic phase of the majority of ionomycin-stimulated T cells, but permitted only a small number of PHA-triggered T cells to enter the initial stage of the cell cycle (G1a) characterized by a modest increase in cellular RNA content. Although PMA permitted some PHA-stimulated T cells to enter the cell cycle, most required intact AC to enter G1, and all required intact AC to progress through G1 and synthesize maximal amounts of RNA. No PHA-stimulated cells reached the S phase without intact AC. In PHA-stimulated cultures containing intact AC, PMA increased the number of cells entering the cell cycle and increased the rate of their progress to the DNA synthetic phase. IL 1 also augmented PHA-stimulated AC-dependent T cell DNA synthesis in the presence or absence of PMA, but appeared to be most active during the later stage of the first cell cycle, augmenting the number of activated cells that entered the S phase of the cell cycle. These results support the conclusion that intact AC, IL 1, and a PMA-like signal play distinct roles in the progression of mitogen-stimulated T cells through the first round of the cell cycle.     

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.     

Immunologic function of endothelial cells: guinea pig aortic endothelial cells support mitogen-induced T lymphocyte activation, but do not function as antigen-presenting cells

The possibility that vascular endothelial cells (EC), like macrophages (M phi), can function as accessory cells necessary for mitogen- and antigen-induced T cell activation was examined. EC were enzymatically detached from the luminal surfaces of guinea pig aortas and then propagated in culture. Lymph node T lymphocytes were rigorously depleted of adherent cells, such that they completely lost the capacity to respond to mitogenic stimulation with phytohemagglutinin or concanavalin A. In this system, EC restored mitogen-induced T cell DNA synthesis as effectively as did M phi. This effect could not be explained by a facilitation of residual accessory cell activity within the responding T cell population, because EC restored mitogen responsiveness to T cells that had been treated with anti-Ia antibody and complement. Support of mitogen responsiveness could not be accounted for by secreted products of M phi or EC in the absence of intact accessory cells. In addition to the capacity to serve as fully sufficient accessory cells for the induction of mitogen-stimulated T cell proliferation, EC exerted a number of modulatory influences on T lymphocyte responses in cultures supported by M phi. When such cultures were supplemented with small numbers of EC, responses were dramatically augmented; larger numbers of EC resulted in marked suppression. At least part of these immunomodulatory effects could be accounted for by the activity of secreted products of EC. EC did not express detectable Ia antigens assayed either by indirect immunofluorescence, with the use of the fluorescence-activated cell sorter, or by complement-mediated cytotoxicity. Moreover, treating the EC population with anti-Ia antibody and complement had no effect on its capacity to support mitogen-induced T cell DNA synthesis. As would be expected from the lack of Ia antigen expression, EC were incapable of presenting antigen to primed T cells. They did, however, carry enough antigen into the cultures such that effective antigen presentation could occur when the cultures were supplemented with M phi that were syngeneic but not allogeneic to the responding T cells. Moreover, EC were capable of dramatically augmenting antigen-specific responses stimulated by antigen-pulsed M phi. There was no genetic restriction for this EC-mediated augmentation of antigen responsiveness. These results indicate that EC are capable of functioning as completely sufficient accessory cells for mitogen-induced T cell DNA synthesis and, in addition, are able to modulate ongoing M phi-supported T lymphocyte responses in both a positive and negative manner.(ABSTRACT TRUNCATED AT 400 WORDS)     

The anti-T cell monoclonal antibody 9.3 (anti-CD28) provides a helper signal and bypasses the need for accessory cells in T cell activation with immobilized anti-CD3 and mitogens

CD28 is an antigen of 44 kDa which is expressed on the membrane of the majority of human T cells. The present study examines the functional effects of an anti-CD28 monoclonal antibody (mAb 9.3) on T cell activation induced with immobilized anti-CD3 mAb OKT3 or with mitogens, in the absence of accessory cells. To this end, we used blood resting T cells that were completely depleted of accessory cells (monocytes, B cells, and natural killer cells), and consequently did not respond to recombinant interleukin-2 (rIL-2), to immobilized OKT3, to PHA, or to Con A. Addition of mAb 9.3 to the cultures enhanced IL-2 receptor expression (Tac antigen) on PHA- or immobilized OKT3-stimulated T cells and induced IL-2 receptors on Con A-stimulated T cells. Moreover, addition of mAb 9.3 to cultures of T cells stimulated with PHA, Con A, or immobilized OKT3 resulted in IL-2 production. Soluble mAb 9.3 was a sufficient helper signal for T cell proliferation in response to PHA or immobilized OKT3. Crosslinking of mAb 9.3 by culture on anti-mouse IgG-coated plates enhanced the helper effect and was an essential requirement for the induction of T cell proliferation in response to Con A. No other anti-T cell mAb (anti-CD2, -CD4, -CD5, -CD7, -CD8) was found to provide a complete accessory signal for PHA or Con A stimulation of purified T cells. T cell proliferation induced by the combination of PHA and mAb 9.3 was strongly inhibited by the anti-IL-2 receptor mAb anti-Tac. In conclusion, mAb 9.3 can provide a signal bypassing monocyte requirement in T cell activation with immobilized OKT3, PHA, and Con A, resulting in an autocrine IL-2-dependent pathway of proliferation.     

Differential requirement for accessory cells in polyclonal T-cell activation

Highly purified rat Ia-negative (OX-6-) and Ia-positive (OX-6+) T cells were employed to examine the requirement for accessory cells (AC) and/or soluble factors in the activation of resting T cells with Con A, PHA, sodium periodate, or antigen. A variety of cells were employed as AC, including Ia-positive and Ia-negative macrophages (M phi), gamma-irradiated (2000 rad) or non-irradiated OX-6+ T cells, and several Ia-negative adenovirus-transformed rat embryo fibroblast cell lines. Our results suggested that for the expression of IL-2 receptors (IL-2R) and proliferation of OX-6- T cells in response to Con A, PHA, or antigen, there was an obligatory requirement for the presence of AC which could not be overcome by the addition of IL-1 and/or IL-2. Activation of OX-6- T cells with antigen required the presence of Ia+ AC, while activation with mitogens could be initiated with Ia- AC. M phi were efficient in AC function in all responses tested, while the AC function of OX-6+ T cells (TAPC) proved discriminatory under different conditions. The optimal response to PHA required much higher concentrations of TAPC as AC than for the Con A response. TAPC failed to stimulate sodium periodate-treated T cells under any conditions tested. Furthermore, when TAPC were employed as AC, their antigen-presenting ability was radiosensitive, while their AC function for Con A and PHA was radioresistant. These results suggest that molecules involved in T cell-AC interactions may differ, depending on the source of AC and/or type of the proliferative stimulus provided to T cells. This data has been discussed in the context of T-cell activation.     

Accessory cell-T cell interactions involved in anti-CD3-induced T4 and T8 cell proliferation: analysis with monoclonal antibodies

The effect of monoclonal antibodies (Mab) directed at T cell and accessory cell (AC) surface molecules on OKT3-induced T4 and T8 cell proliferation was examined. Mab directed at nonpolymorphic class I (W6/32, MB40.5) and class II (L243) major histocompatibility complex (MHC)-encoded gene products, an epitope common to LFA-1, CR3, and the p150, 95 molecule (60.3), and a heterodimer present on monocytes (M phi) and activated T cells (4F2) inhibited M phi-supported OKT3-induced proliferation of both T4 and T8 cells. Moreover, an Mab directed at the CD4 molecule (66.1) inhibited OKT3-induced T4 but not T8 cell proliferation, whereas an Mab directed at the CD8 molecule (OKT8) inhibited T8 but not T4 cell responses. With the exception of 66.1, each inhibited OKT3-induced T cell proliferation when added as late as 15 hr after the initiation of culture. Inhibition could not be explained by competition for Fc receptors on the AC. A variety of other Mab including OKT11 and those directed at other HLA-DR and DQ determinants were not inhibitory. The inhibitory Mab were found to diminish T4 cell IL 2 production and IL 2 receptor expression. Consequently, IL 2 reversed some but not all of the Mab-mediated inhibition of T cell proliferation. In contrast to the effects noted with M phi-supported responses, 60.3 and 66.1 but neither L243 nor 4F2 inhibited OKT3-induced T4 cell proliferation supported by Ia- or IFN-gamma-treated Ia+ endothelial cells. None of the Mab tested inhibited T cell proliferation induced by the AC-independent stimuli OKT3 and phorbol myristate acetate (PMA) or calcium ionophore and PMA in the presence or absence of added AC. The data therefore suggest that the Mab inhibit OKT3-induced activation of T4 and T8 cells by preventing necessary interactions between AC and T cell surface proteins. Moreover, the results suggest that different arrays of interaction molecules are involved in OKT3-induced T cell proliferation depending on the nature of the AC and the responding T cell subset.     

Regulation of human T lymphocyte mitogenesis by antibodies to CD3

The inhibitory and mitogenic effects of anti-CD3 antibodies (anti-CD3) were examined in cultures of human peripheral blood T cells. Resting T cells required the presence of accessory cells (AC) or phorbol myristate acetate (PMA) to be stimulated by soluble anti-CD3 (OKT3 and 64.1). Anti-CD3 was unable to induce activation of AC-depleted T cells as determined by IL 2 receptor expression, IL 2 production, cell cycle analysis, or detectable DNA synthesis. Although T cell responses to PHA also required AC, far fewer were necessary to generate responses. Anti-CD3 inhibited PHA-stimulated T cell IL 2 production, IL 2 receptor expression and proliferation in partially AC-depleted cultures. Moreover, anti-CD3 was able to inhibit PHA responses when added to culture as late as 24 to 42 hr after the initiation of a 96-hr incubation. Increasing concentrations of PHA reduced the inhibitory effect of anti-CD3 on PHA-stimulated T cell proliferation, whereas IL 2 production remained suppressed. Anti-CD3 linked to Sepharose beads effectively inhibited PHA-stimulated T cell DNA synthesis, indicating that internalization of the CD3 molecule was not required for inhibition of PHA responses. Although inhibition of IL 2 production was a major effect of anti-CD3 in PHA-stimulated cultures, it was not the only apparent inhibitory effect because the addition of exogenous IL 2 could not prevent inhibition completely. Intact AC but not IL 1 also reduced anti-CD3-mediated inhibition of PHA responsiveness, whereas the addition of both IL 2 and AC largely prevented inhibition. Thus, anti-CD3 in the absence of adequate AC signals exerted a number of distinct inhibitory effects on mitogen-induced T cell activation. These results suggest that the CD3 molecular complex may play a role in regulating T cell responsiveness after engagement of the T cell receptor by a number of mechanisms, some of which involve inhibition of IL 2 production.     

T cells produce TRF in response to Con A and factors in T cell hybridoma supernatants

In recent experiments, a soluble factor (TRF) that mediates the differentiation of anti-immunoglobulin (Ig)-activated B cells to Ig-secreting cells has been identified. TRF works in concert with a growth factor, probably IL 2, in the induction of activated B cells. In previous studies, TRF was identified in culture supernatants of activated T cells and accessory cells, and thus the cellular source (T cell or accessory cell) of the factor was not determined. In the present studies, we succeeded in inducing the production of TRF by T cell populations from which accessory cells had been vigorously depleted. Lymph node cells were depleted of accessory cells by nylon wool adherence and anti-Ia and complement treatment; these cells were activated with Con A and a T cell hybridoma supernatant that contains IL 2. Supernatants from these activated T cell cultures supported the differentiation of anti-Ig-activated B cells to Ig secreting cells. These results show that T cells produce the differentiation factor, and further that they do so in response to ligand (Con A) plus a T cell-derived factor.     

Activated T lymphocytes and macrophages secrete fibronectin which strongly supports cell adhesion.

Matrix-bound fibronectin (FN) appears to be involved in cell adhesion and motility mediated by integrin receptors. Although lymphoid cells and other cell types are capable of producing and secreting FN, the precise role of this secreted FN-like factor in regulating immune reactions is unclear. In the present study we analyzed the adhesive properties of FN secreted by rat CD4+ T cells and clone cells activated by the T cell mitogen concanavalin A (Con A), antigen, or via the CD2 pathways, or by macrophages (M phi) activated by lipopolysaccharide (LPS). Immobilized culture supernatant (CS) from the activated T cells or M phi supports the adhesion of activated rat or human CD4+ T cell or murine tumor cell. These CS contained FN and were more potent at facilitating cell adhesion then plasma FN. The adhesion activity of CS was attributed to FN because (a) gelatin columns depleted the FN present in the CS and (b) pretreating the cells with peptides of the cell-binding domain of FN abrogated their ability to bind CS. CS-mediated adhesion appears to occur primarily via the recognition of the Arg-Gly-Asp (RGD) by the beta 1-integrin-specific receptors of the adhesive cells. Thus, we postulate that FN secreted by various types of leukocytes is involved in promoting essential cell-matrix interactions, possibly affecting cell-adhesive and migratory processes at inflammatory or extravasation sites.     

T4 cell activation by immobilized phytohemagglutinin: differential capacity to induce IL-2 responsiveness and IL-2 production

Soluble mitogens, such as PHA induce accessory cell (AC)-dependent T cell proliferation. One function of the AC is to create a stimulatory matrix. Therefore, experiments were carried out to determine whether PHA immobilized onto microtiter plates could stimulate T cells in the absence of AC. Peripheral blood T4 cells were cultured under limiting dilution conditions with either soluble or immobilized PHA with or without rIL-1 beta, rIL-2, r-TNF-alpha, an anti-CD28 mAb (9.3), or irradiated EBV-transformed B cells as AC. The frequency of proliferating T4 cells was assessed by examining wells microscopically, and the frequency of T4 cells producing IL-2 was assessed by examining the ability of supernatants to support CTLL-2 proliferation. The percentage of T4 cells growing and producing IL-2 was determined by a maximum likelihood procedure. Immobilized, but not soluble, PHA induced a mean of 20.0 +/- 2.6% of T4 cells to grow in the complete absence of AC in medium supplemented with rIL-2. Whereas rIL-1 beta, rTNF-alpha, and 9.3 were unable to support T4 cell growth in the absence of rIL-2, each enhanced the percentage of T4 cells responding to immobilized PHA in the presence of rIL-2. In contrast, both soluble and immobilized PHA were unable to induce T4 cell IL-2 production in the absence of AC, even when cultures were supplemented with rIL-1 beta or 9.3. In the presence of AC, a small percentage of T4 cells (5.4 to 11.7%) was stimulated to produce detectable amounts of IL-2 by either immobilized or soluble PHA. Moreover, in the presence of AC, a very small population (approximately 1%) of PHA-stimulated T4 cells proliferated without supplemental rIL-2. The data indicate that a matrix of immobilized PHA is sufficient for some T4 cells to be activated to respond to IL-2, whereas others require additional signals provided by rIL-1 beta, rTNF alpha, 9.3, or AC. In contrast, neither soluble nor immobilized PHA is sufficient to induce T cell IL-2 production. This response requires signals provided by intact AC.     

The role of the accessory cell in mitogen-stimulated human T cell gene expression

The role of the accessory cell in optimizing T cell proliferative responses to mitogens is a well known but poorly understood phenomenon. To further dissect the function of the accessory cell in allowing T cell proliferation, we compared mitogen-induced c-myc, interleukin 2 (IL 2), and IL 2 receptor gene expression in peripheral blood mononuclear cells (PBMC) and in T cells rigorously depleted of accessory cells through differential adherence and anti-Dr (anti-class II major histocompatibility antigen) monoclonal antibody complement-directed cytotoxicity. In cultures stimulated with phytohemagglutinin (PHA), a mitogen that requires accessory cells to induce T cell proliferation, expression of all measured genes was accessory cell dependent, since accumulation of their mRNA in PBMC was greater than that in cultures depleted of accessory cells. These genes varied in their accessory cell dependence, with IL 2 expression most dependent, c-myc expression least dependent, and IL 2 receptor expression intermediate in dependency. Use of 12-O-tetradecanoyl-phorbol-13-acetate (TPA) or ionomycin, mitogens that stimulate T cell proliferation independent of accessory cells, induced equal levels of gene expression in PBMC and in T cells depleted of accessory cells. These results suggest that PHA-stimulated T cells are dependent on an accessory cell signal(s) for optimal expression of the genes for c-myc, IL 2, and IL 2 receptor, and for proliferation. In addition, this signal(s) appears to be delivered early in the course of T cell activation events, since it can be bypassed by mitogens that directly activate protein kinase C (TPA) or induce calcium translocation (ionomycin). In addition, these data provide further evidence that expression of the c-myc protooncogene is insufficient for T cell mitogenesis, since PHA-induced accumulation of c-myc mRNA was only partially accessory cell dependent, whereas proliferation was completely accessory-cell dependent.     

CD4+ Leu-8+ T cell supernatant activity that inhibits Ig production.

The subpopulation of CD4+ T cells that expresses the Leu-8 peripheral lymph node homing receptor suppresses PWM-stimulated Ig synthesis. To determine the mechanism of this suppression, the immunoregulatory activity of culture supernatants obtained from peripheral blood CD4+ Leu-8+ T cells cultured with anti-CD3 mAb and PMA (Leu-8+ supernatant) was determined. Leu-8+ supernatant suppressed PWM-stimulated Ig synthesis in cultures containing non-T cells and CD4+ Leu-8- T cells. In contrast, the supernatant from CD4+ Leu-8- T cells did not suppress Ig synthesis. The inhibitory activity of CD4+ Leu-8+ T cell supernatants could not be accounted for by a deficiency or excess of IL-2, IL-4, IFN-gamma, IL-6, or PGE2. In studies examining the effect of CD4+ Leu-8+ supernatant on T cells, the supernatant did not alter either mitogen-induced proliferation or the helper function of CD4+ Leu-8- T cells. In studies examining the effect of CD4+ Leu-8+ supernatant on B cells, the supernatant inhibited Staphylococcus aureus Cowan I strain-induced B cell Ig secretion but not B cell proliferation. The suppressor activity of Leu-8+ supernatant was eliminated by protease treatment and was eluted by HPLC in two main peaks, with molecular sizes of 44 and 12 kDa. In summary, these studies indicate that supernatants from activated CD4+ Leu-8+ T cells directly suppress B cell Ig production.     

Independent analysis of T helper and T killer cell function in young and old NZB mice.

With age, NZB mice lose their ability to develop a cytotoxic response after alloimmunization in vitro. This decline is shown to coincide with a diminution of T-helper cell activity as assessed by proliferation in mixed lymphocyte culture or in response to PHA. When cytotoxic T cell precursors are activated with the polyclonal activator Con A, there is no reduction in the number of cytotoxic effector T cells that develop. No autoreactive cytotoxic cells are seen in Con A-activated cultures. These findings are related to previous work on cell-mediated immunity in NZB and B/W mice.     

Delineation of the mechanism of inhibition of human T cell activation by PGE2

The capacity of PGE2 to inhibit human T cell responses was examined by investigating its effect on mitogen-induced IL-2 production and proliferation of highly purified CD4+ T cells. PGE2 inhibited both PHA and anti-CD3 induced proliferation and IL-2 production by an action directly on the responding T cell. Inhibition of IL-2 production reflected decreased accumulation of mRNA for IL-2. A variety of other cAMP elevating agents exerted similar inhibitory effects. Inhibition of proliferation could be overcome by supplemental IL-2, PMA, or the anti-CD28 mAb 9.3. Although PMA and 9.3 markedly increased the amount of IL-2 produced by mitogen-stimulated T cells, the percentage inhibition of IL-2 secretion caused by PGE2 and other cAMP elevating agents remained comparable in these costimulated cultures. Rescue of T cell DNA synthesis by these agents appeared to reflect the finding that, although PGE2 markedly inhibited IL-2 production, the absolute amount of IL-2 produced was increased sufficiently to sustain mitogen-induced proliferation. As anticipated, PGE2, forskolin, and cholera toxin increased T cell cAMP levels. The quantity of cellular cAMP generated in response to PGE2, cholera toxin, and forskolin could be inhibited by PMA or 2',5'-dideoxyadenosine. Using these reagents, the inhibitory effects of PGE2 were found to reflect intracellular cAMP levels, but only within a very narrow range. The results indicate that by elevating cAMP levels, PGE2 inhibits human T cell IL-2 production at a point that is common to both the CD3 and CD28 signaling pathways.     

Promotion of human T lymphocyte proliferation by IL-4

The capacity of human rIL-4 to support the proliferation of mitogen-stimulated T cells directly as well as by increasing IL-2 production or enhancing IL-2 responsiveness was investigated. IL-4 augmented proliferation of T cells stimulated with PHA, Con A, immobilized mAb to the CD3 molecular complex (OKT3), or PMA. IL-4 increased the number of mitogen-stimulated cells entering the cell cycle as well as enhancing ongoing proliferation of mitogen-activated lymphoblasts. Facilitation of initial activation by IL-4 was not inhibited by mAb to the p55 component of the IL-2R, anti-Tac, and, therefore, was not dependent on endogenous IL-2 activity. However, IL-4-mediated enhancement of ongoing T cell proliferation stimulated by PHA or OKT3 was partially but not completely blocked by anti-Tac. Analysis of the supernatants from PHA-stimulated T cell cultures indicated that IL-4 increased the production of IL-2 by mitogen-activated cells. Moreover, IL-4 increased the amount of IL-2 mRNA that accumulated in mitogen-stimulated T cells. In addition, IL-4 markedly augmented IL-2R expression by PHA-stimulated T cells. Although IL-4 promoted ongoing DNA synthesis of mitogen-stimulated T cells in an IL-2-dependent manner, it was also able to sustain their proliferation directly. Thus, IL-4 supported proliferation of PMA-activated T cells in a manner that was not inhibited by anti-Tac. Furthermore, IL-4 could augment proliferation and IL-2R expression of T cells stimulated with PHA in the presence of cyclosporin A, which blocks endogenous cytokine production or anti-Tac. Finally, IL-4 was noted to enhance proliferation of both CD4+ and CD8+ T cell subsets. The results indicate that IL-4 enhances proliferation of mitogen-activated human T cells by a number of mechanisms, including the direct promotion of cell cycle entry and subsequent DNA synthesis, enhanced production of IL-2, and increased responsiveness to IL-2 in part by up-regulation of IL-2R expression.     

Hyaluronan synthesis is required for IL-2-mediated T cell proliferation

Hyaluronan (HA) is a glycosaminoglycan composed of N-acetylglucosamine and glucuronic acid subunits. Previous studies have suggested that CD44 expressed by T cells bind exogenous HA for their proliferation. However, HA endogenously synthesized by T cells may participate in their autocrine proliferation. In this study, we examined the role of endogenous HA in T cell proliferation using the highly specific HA synthase inhibitor, 4-methylumbelliferone (4-MU). We found that 4-MU inhibited the mitogen-induced synthesis of HA by T cells. Moreover, 4-MU inhibited T cell proliferation in a dose-dependent manner when cells were cultured with different stimuli, including Con A, PMA/ionomycin, and allogeneic spleen cells. Furthermore, 4-MU inhibited mitogen-stimulated IL-2 secretion, suggesting that HA may play a role in the production of this cytokine. Addition of IL-2 to T cells treated with 4-MU and Con A reversed the block in cell proliferation, showing that impaired IL-2 production is a likely mechanism for the inhibited division of T cells. Surprisingly, an anti-CD44 Ab antagonistic for HA binding did not reduce IL-2 secretion or T cell proliferation. Importantly, 4-MU did not alter the surface expression of CD44 or the ability of CD44 to bind to HA. Thus, HA-mediated IL-2 production and T cell proliferation are CD44 independent. Our results strongly suggest that HA synthesized by T cells themselves is critical for their IL-2-mediated proliferation and have revealed a previously unrecognized role for endogenous HA in T cell biology.     

Alloreactive T cells from individual soft agar colonies specific for guinea pig Ia antigens. II. Cellular and molecular requirements for optimal proliferative responses

We have investigated the cellular and molecular requirement for optimal proliferative responses of several alloreactive T cell lines that were derived from individual soft agar colonies and were specific for guinea pig Ia antigens. Optimal proliferation of several colonies was observed in cultures containing purified allogeneic macrophages and growth factor(s) present in supernatant fluids of Con A-activated T cells (Con A-S). Significant proliferative responses of these alloreactive T cell colonies were also routinely detected in cultures only supplemented with unfractionated irradiated allogeneic peritoneal exudate cell (PEC). The T cell component of the stimulator cell population was crucial for these responses by producing necessary growth factor(s) endogenously in the culture. Thus, 2 signals, allogeneic Ia antigens and growth factor(s), were required for optimal proliferative responses of these alloreactive T cell colonies. Furthermore, macrophage-associated Ia antigen was more efficient than B cell-associated Ia for these responses. The requirement for allogeneic Ia antigen was not absolute, since the colonies could easily be expanded when the cultures were supplemented with irradiated syngeneic PEC and the T cell mitogens, Con A or PHA. The effect of the mitogen was mediated via the T cells in the irradiated PEC, since removal of the T cells from these PEC markedly reduced the responses. Thus, it is likely that a nonspecific signal(s) presumably from T cells can promote proliferation of alloreactive T cell colonies in the absence of allogeneic Ia antigen. These results suggest 2 mechanisms of activation of these alloreactive T cells.     

Dissection of the functions of antigen-presenting cells in the induction of T cell activation

The functions of antigen-presenting cells (APC) in the initiation of T cell activation was examined by culturing antigen-bearing guinea pig macrophages (M phi) with T cells obtained from antigen-primed animals. Although such antigen-bearing M phi stimulated primed syngeneic T cell DNA synthesis, as assessed by tritiated thymidine incorporation, paraformaldehyde fixation (0.15% for 1 min at 37 degrees C) abolished this capacity. Analysis with acridine orange staining indicated that fixed antigen-bearing M phi could not trigger primed syngeneic T cells to progress from the G0 to the G1 phase of the cell cycle. The addition of control non-antigen-bearing syngeneic or allogeneic M phi but not interleukin 1 or 2 to cultures of T cells and fixed APC permitted a proliferative response. Although the interaction between fixed antigen-bearing M phi and responding T cells was genetically restricted, there was no similar restriction for the supplemental control M phi. In fact, completely Ia-negative endothelial cells (EC) and fibroblasts (FB) could restore antigen responsiveness to cultures of fixed antigen-bearing M phi and syngeneic responding T cells, although they could not directly present antigen. Moreover, metabolically intact accessory cells, including Ia-negative EC and FB, could take up and process antigen to an immunogenic moiety, which fixed Ia-positive M phi could present to primed T cells. These data indicate that recognition of the antigen-Ia complex on an APC is necessary but not sufficient to trigger proliferation of freshly obtained primed T cells. The results additionally support the conclusion that APC carry out at least two separate functions necessary for the initiation of antigen-induced T cell activation. Not only must the APC display the antigen-Ia complex, but it must also convey another required effect. This influence, which apparently involved the establishment of cell to cell contact, was neither Ia nor antigen dependent and could only be provided by a metabolically intact cell. By contrast, genetically restricted antigen presentation could be accomplished by a fixed Ia-positive cell. Only when both the antigen-Ia complex and the influence of an intact accessory cell were provided by the same or different accessory cell were T cells triggered to enter the cell cycle.     

Disparate functional properties of two interleukin 1-responsive Ly-1+2- T cell clones: distinction of T cell growth factor and T cell-replacing factor activities

We describe the properties of two Ly-1+2- T cell clones (Ly-1.14 and Ly-1.21), which are maintained in long-term culture in the absence of other cell types. The clones require media containing a source of interleukin 1 as well as interleukin 2. They retain physiologic responses to interleukin 1, which is required for optimal production of T cell lymphokines by these clones in response to concanavalin A (Con A). The two Ly-1+2- T cell clones differ in their production of lymphokines after stimulation by Con A. The supernatant of clone Ly-1.21 promotes the proliferation of T cells maintained in long-term culture, induces antibody synthesis in cultures of B cells and antigen, and induces the differentiation of cytolytic cells in cultures of thymocytes and antigen; these assays define the properties of T cell growth factor (TCGF), T cell-replacing factor for B cells (TRF-B), and T cell-replacing factor for cytolytic cells (TRF-C), respectively. In contrast, the supernatant of clone Ly-1.14 contains only TCGF activity and does not promote antibody synthesis by B cells or differentiation of cytolytic cells from thymocytes. The results indicates that TCGF and TRF activities reside on independent, although perhaps related, molecules.     

Splenic and inguinal lymph node T cells of aged mice respond differently to polyclonal and antigen-specific stimuli.

Numerous changes have been reported to occur in T cell responsiveness of mice with increasing age. However, most of these studies have examined polyclonal stimulation of spleen cells from a limited number of mouse strains. This study investigated the influence of genetic background, source of lymphocytes, and type of stimulus on age-associated changes in T cells response. Con A-induced proliferation and IL-2 and IFN-gamma production by splenic lymphocytes (SL) was significantly greater in CBA/Ca mice compared to C57BL/6 mice, regardless of age. SL of both strains exhibited the predicted age-dependent decline in proliferative response and an increase in IFN-gamma production in response to Con A. In contrast, however, only SL from C57BL/6 mice demonstrated the predicted age-dependent decline in Con A-induced IL-2 production; Con A-induced SL of young and aged CBA/Ca mice produced comparable amounts of IL-2. Differences in age-associated responses to Con A were also observed between SL and inguinal lymph node (ILN) cells of CBA/Ca mice. In contrast to SL, ILN cells demonstrated an increased proliferative response to Con A. However, lymphokine production by Con A-stimulated ILN cells from aged CBA/Ca mice was similar to that of Con A-stimulated SL from aged CBA/Ca mice. To determine if aged ILN T cells respond similarly to polyclonal and antigen-specific stimuli, keyhole limpet hemocyanin (KLH) responses of T cells isolated from ILN of aged and young CBA/Ca mice were examined. KLH-specific T cells from aged mice cultured with KLH-pulsed macrophages (M phi) from aged mice were significantly reduced in their ability to proliferate compared to KLH-specific T cells of young mice cultured with young KLH-pulsed M phi. In contrast to the expected results, the defect was not at the level of the T cells; proliferation of young T cells cultured with aged KLH-pulsed M phi was equivalent to the proliferation of aged T cells cultured with aged M phi. These results suggest that aging has differential effects on polyclonal and antigen-specific T cell proliferation and on polyclonal stimulation of T cells isolated from different lymphoid organs and from different strains of mice.