Alloantigen-specific T suppressor-inducer and T suppressor-effector cells can be activated despite blocking the IL-2 receptor

To determine IL-2 requirement for activation of suppressor cells, PBMC were primed in one-way MLR in the presence of 10 micrograms/ml anti-IL-2R beta-chain antibody 2A3 (CD25) or control antibody, then irradiated and added as regulators in a fresh MLR. Cells primed in the presence of antibody 2A3 suppressed the proliferative response to fresh autologous lymphocytes to specific alloantigen but had no effect on the response to cells from third party donors. Priming in the presence of an antibody of irrelevant specificity induced only limited suppressor activity. Activated suppressor cells did not show cytolytic activity specific for the stimulators when tested at the time of the suppressor cell assay. To identify the subset(s) responsible for suppression, cells primed in the presence of antibody 2A3 were separated into CD4+/CD45RA+, CD4+/CD45RA-, and CD8+ subsets, which were irradiated and then tested. The suppressive activity was found predominantly in the CD4+/CD45RA+ subset, whereas CD8+ cells had some activity and CD4+/CD45RA- cells had none. No subset suppressed the response of autologous cells to third-party cells. When primed CD4+/CD45RA+ cells were cocultured with fresh autologous lymphocytes depleted of CD8+ cells, no suppression was observed, indicating that, although the CD4+/CD45RA+ cells can function as inducers of suppressors, they cannot function as suppressor-effectors. Conversely, CD8+ cells activated in MLR in the presence of 2A3 caused suppression, regardless of whether the fresh autologous responder population contained CD8+ cells. CD4+/CD45RA+ and CD8+ subsets isolated after priming in the presence of 2A3 also demonstrated Ag-specific suppression in the generation of cytotoxic T lymphocytes whereas CD4+/CD45RA- cells had no activity. Our data are consistent with the model that suppression of alloreactivity requires the cooperation of two types of cells, a CD4+/CD45RA+ suppressor-inducer and a CD8+ suppressor-effector population. Activated Tsi and fresh Tse or activated Tse alone can suppress lymphocyte proliferation and generation of CTL in response to specific Ag. Activation of Ag-specific T suppressor-inducer and T suppressor-effector cells appears to be relatively IL-2 independent and presumably require one or more other growth factors.     

Heterogeneous mechanisms of human cytotoxic T lymphocyte generation. I. Differential helper cell requirement for the generation of cytotoxic effector cells from CD8+ precursor subpopulations.

The subpopulations of CD8+ T cells defined by CD45RA Ag expression have been hypothesized to represent cells varying in their relative maturation along a common, activation-dependent differentiation pathway. Previous studies have shown that both the CD8+CD45RA+ and CD8+CD45RA- subsets contain precursor cells capable of developing into alloreactive CTL. In the current study, we have examined the mechanisms involved in the generation of CTL effector cells from these two CD8+ subsets. Purified CD8+CD45RA+ or CD8+CD45RA- cells were stimulated with allogeneic non-T cells, either alone or in the presence of CD4+ Th cells. Although the generation of CTL from CD8+CD45RA- precursor cells consistently required the presence of CD4+ Th cells, cytotoxic effector cells could be generated from CD8+CD45RA+ precursor cells in the absence of CD4+ cells. Several lines of evidence indicated that the helper cell-independent generation of cytotoxic effector cells from CD8+CD45RA+ precursors resulted from the unique ability of this subset to produce and use IL-2 in an autocrine fashion: 1) exogenous IL-2 could replace the effects of CD4+ helper cells for either CD8+ subset; 2) the helper cell-independent functional maturation of CD8+CD45RA+ cells could be blocked by anti-CD25 or anti-IL-2 antibodies; and 3) CD8+CD45RA+ cells produced IL-2 after activation with allogeneic cells. The finding that precursors for helper cell-independent CTL generation are restricted to the CD8+CD45RA+ subset suggests that this capability may vary as a function of the maturation of CD8+ cells.     

T8 cell regulation of human B cell responsiveness: regulatory influences of CD45RA+ and CD45RA- T8 cell subsets

The immunoregulatory functions of human T8 cell subpopulations defined by mAb to the CD45RA molecule (2H4) were examined. Both CD45RA+ and CD45RA- T8 cells that had been treated with mitomycin C provided help for the production of immunoglobulins by B cells in cultures stimulated with immobilized mAb to CD3 (64.1). In contrast, both CD45RA+ and CD45RA- T8 cells that had not been treated with mitomycin C suppressed B cell responses in anti-CD3-stimulated cultures, although CD45RA+ T8 cells were more effective in this regard. Interleukin 2 (IL2) enhanced suppression by anti-CD3-activated CD45RA- T8 cells, whereas suppression by CD45RA+ T8 cells was almost maximal and not as much increased by IL2. The differentiation into suppressor-effector cells in this system appeared to involve the production of IL2, but not the production of interferon (INF)-gamma. Thus, CD45RA+ T8 cells produced higher amounts of IL2 but lower amounts of IFN-gamma than CD45RA- T8 cells in anti-CD3-stimulated cultures. Moreover, addition of mAb to the p55 component of IL2 receptor (anti-Tac) inhibited the generation of suppressor activity from CD45RA+ and CD45RA- T8 cells. The pattern and magnitude of suppression of B cell responses by CD45RA+ and CD45RA- T4 cells were similar to that by CD45RA+ and CD45RA- T8 cells in this system. Finally, preactivated CD45RA+ T8 cells that had lost CD45RA expression suppressed the B cell responses as effectively as fresh CD45RA+ T8 cells. The results indicate that both CD45RA+ and CD45RA- T8 cells can help or suppress B cell responses. More importantly, the data suggest that the suppressor-effector function of human T cells may rather be related with the stages of the post-thymic differentiation as evidenced by the expression of the CD45RA molecule than represent the fully differentiated T cell subsets, such as T4 and T8 cells. In addition, the CD45RA molecule appeared not to be involved in the suppressor-effector function, but to determine the stage of post-thymic differentiation.     

IL-10 is produced by subsets of human CD4+ T cell clones and peripheral blood T cells.

Murine IL-10 has been reported originally to be produced by the Th2 subset of CD4+ T cell clones. In this study, we demonstrate that human IL-10 is produced by Th0, Th1-, and Th2-like CD4+ T cell clones after both Ag-specific and polyclonal activation. In purified peripheral blood T cells, low, but significant, levels of IL-10 were found to be produced by the CD4+CD45RA+ population, whereas CD4+CD45RA- "memory" cells secreted 5- to 20-fold higher levels of IL-10. In addition, IL-10 was produced by activated CD8+ peripheral blood T cells. Optimal induction of IL-10 was observed after activation by specific Ag and by the combination of anti-CD3 mAb and the phorbol ester tetradecanoyl phorbol acetate, whereas the combination of calcium ionophore A23187 and 12-O-tetradecanoylphorbol-13-acetate acetate was a poor inducer of IL-10 production. Kinetic studies indicated that IL-10 was produced relatively late as compared with other cytokines. Maximal IL-10 mRNA expression in CD4+ T cell clones and purified peripheral blood T cells was obtained after 24 h, whereas maximal IL-10 protein synthesis occurred between 24 h and 48 h after activation. No differences were observed in the kinetics of IL-10 production among Th0, Th1-, and Th2-like subsets of CD4+ T cell clones. The results indicate a regulatory role for IL-10 in later phases of the immune response.     

Monokine production by human T cells; IL-1 alpha production restricted to memory T cells.

The production of cytokines is a key event of inflammation. In this report we demonstrate that normal human T cells are capable to produce IL-1 alpha, IL-6, and TNF-alpha, cytokines formerly considered to be monokines. This production was optimal after stimulation with a combination of anti-CD2, PMA, and anti-CD28. All three cytokines were produced in a bioactive form. Both naive (CD4+CD45RA+) and memory (CD4+CD45RO+) subsets of T cells were shown to produce similar amounts of IL-6 and TNF-alpha. In contrast the production of IL-1 alpha was found to be completely restricted to the CD4+CD45RO+ subset. The finding that T cells are such potent producers of these important mediators of the inflammatory response might be a key observation in the appreciation of the role of T cells in chronic inflammation.     

Novel immunoregulatory functions of phenotypically distinct subpopulations of CD4+ cells in the human neonate.

Although normal numbers of CD4+ T cells are present in the human neonate, cord blood CD4+ cells are deficient in their ability to provide help for antibody production. In the present studies, we have examined the cellular basis for this functional deficit by analyzing the phenotypic properties and immunoregulatory functions of the subsets of cord blood CD4+ cells defined by anti-CD45RA mAb. In contrast to CD4+ cells from adults, greater than 90% of cord blood CD4+ cells expressed the CD45RA, CD38, and Leu-8 membrane Ag. When neonatal CD4+ cells were cultured with adult B cells and PWM or anti-CD4+ mAb, no helper function was apparent. However, when the small number of CD4+CD45RA- cells in cord blood were purified and similarly analyzed, helper activity comparable to that of adult CD4+CD45RA- cells was found. This helper function was profoundly suppressed by the presence of even small numbers of cord blood (but not adult) CD4+CD45RA+ cells. Irradiation of mitomycin C treatment of neonatal CD4+CD45RA+ cells abrogated their suppressor activity, but did not induce helper capability. However, after activation with PHA and culture in IL-2, cord blood CD4+CD45RA+ cells lost their suppressor activity and acquired the ability to provide help for B cell differentiation. This functional maturation was accompanied by their conversion to the CD4+CD45RA- phenotype. Thus, whereas cord blood CD4+CD45RA+ and CD4+CD45RA- cells share certain properties with the analogous subsets in adults, our data show that the dominant immunoregulatory function of cord blood CD4+ cells is suppression mediated by CD4+CD45RA+ (and CD38+) cells. In view of these phenotypic and functional differences between neonatal and adult CD4+CD45RA+ cells, we propose that "naive" CD4+CD45RA+ cells undergo age-related maturational changes that are unrelated to their postulated activation-dependent post-thymic differentiation into CD4+CD45RA- "memory" cells capable of helper functions.     

Identification of the anti-CD3-unresponsive subpopulation of CD4+, CD45RA+ peripheral T lymphocytes.

The majority of peripheral CD4+ T lymphocytes proliferate in vitro in response to anti-CD3 in presence of autologous APC. The present study describes a subpopulation of CD4+ T cells that cannot be activated and progress into cell cycle by stimulation with anti-CD3 plus APC or with mitogenic combinations of anti-CD2. The in vitro responses of these anti-CD3-unresponsive CD4+ T cells were investigated with a panel of mAb to CD2, CD3, and CD28, and found to be similar to those previously observed for mature thymocytes: only the combination of anti-CD2 plus anti-CD28 produced cell proliferation. Anti-CD3-unresponsive T cells were CD45RA+, but represented only 14 to 22% of the CD4+, CD45RA+ T cell population. Activation with anti-CD2 plus anti-CD28 mAb resulted in major changes in the cell surface phenotype and functional properties: a loss of CD45RA+ occurred and an increased expression of CD45RO, CD29, and CD58 (LFA3), as well as a gain in responsiveness to anti-CD3 and anti-CD2. This change in CD45 phenotype from CD45RA to CD45RO occurs in both the anti-CD3-responsive and in the anti-CD3-unresponsive subsets of the CD45RA+, CD4+ cells after cell proliferation. The anti-CD3-unresponsive subset may represent a pool of not yet fully differentiated peripheral T cells. The acquisition of anti-CD3 responsiveness could occur as a consequence of Ag priming or by an Ag-independent mechanism. Involvement of the CD28 Ag in this process is suggested from the present study.     

Human autoreactive CD4+ T cells from naive CD45RA+ and memory CD45RO+ subsets differ with respect to epitope specificity and functional antigen avidity

T cells with specificity for self-Ags are normally present in the peripheral blood, and, upon activation, may target tissue Ags and become involved in the pathogenesis of autoimmune processes. In multiple sclerosis, a demyelinating disease of the CNS, it is postulated that inflammatory damage is initiated by CD4+ T cells reactive to myelin Ags. To investigate the potential naive vs memory origin of circulating myelin-reactive cells, we have generated myelin basic protein (MBP)- and tetanus toxoid-specific T cell clones from CD45RA+/RO- and CD45RO+/RA- CD4+ T cell subsets from the peripheral blood of multiple sclerosis patients and controls. Our results show that 1) the response to MBP, different from that to TT, predominantly emerges from the CD45RA+ subset; 2) the reactivity to immunodominant MBP epitopes mostly resides in the CD45RA+ subset; 3) in each individual, the recognition of single MBP epitopes is skewed to either subset, with no overlap in the Ag fine specificity; and 4) in spite of a lower expression of costimulatory and adhesion molecules, CD45RA+ subset-derived clones recognize epitopes with higher functional Ag avidity. These findings point to a central role of the naive CD45RA+ T cell subset as the source for immunodominant, potentially pathogenic effector CD4+ T cell responses in humans.     

Differential interleukin secretion by in vitro activated human CD45RA and CD45RO CD4+ T cell subsets.

The CD45RA and CD45RO isoforms have been reported to define complementary subsets among CD4+ T cells: CD45RA CD4+ T cells are considered "virgin T cells" and CD45RO "primed T cells." We investigated the secretion of lymphokines by human CD4+ CD45RO and CD4+ CD45RA T helper cells after mitogen stimulation. CD45RA and CD45RO CD4+ T cells were isolated by negative immunoselection using magnetic beads. CD45RO cells, but not CD45RA cells, proliferate well in response to pokeweed mitogen (PWM) or insoluble anti-CD3. Both subpopulations produced interleukin (IL)-2, IL-6, and interferon (IFN)-gamma when stimulated with PWM for 1-4 days. Only Day 1 supernatants from CD45RO cells contained moderate amounts of IL-4. After 14 days of continuous culture and stimulation with PWM, the CD45RA subset had lost the expression of CD45RA and gained that of CD45RO. When long-term cultured CD45RA or CD45RO cells were treated with insoluble anti-CD3, they incorporated [3H]thymidine at similar levels, but only CD45RO cells secreted IL-4 and significantly increased their secretion of IFN-gamma. These data indicate that despite phenotype conversion, the two subpopulations maintain functional differences in the secretion of lymphokines, thus suggesting that circulating CD45RA and CD45RO cells may represent different lines of differentiation.     

CD27, a member of the nerve growth factor receptor family, is preferentially expressed on CD45RA+ CD4 T cell clones and involved in distinct immunoregulatory functions.

CD27 is a disulfide-linked 120-kDa homodimer expressed on the majority of peripheral T cells at variable density that belongs to the recently defined nerve growth factor receptor family. mAb reactive with CD27 can either enhance or inhibit T cell activation, suggesting a crucial role in the process of T cell activation. We now show that CD27 is preferentially expressed on the CD45RA+CD45RO-CD29low subset of CD4 cells. CD27 expression on this subset is maintained for a prolonged period in culture after PHA activation. In contrast, CD45RA-CD45RO(+)-CD29high subset of CD4 cells express very low level of CD27, and its expression is lost within 2 wk after PHA activation. To further analyze the differential expression of CD27 on these reciprocal subsets of CD4 cells, we developed T cell clones by stimulating isolated CD4+CD45RA+ and CD4+CD45RO+ populations with PHA. T cell clones derived from cells originally CD45RA+ retained both CD45RA and CD27 expression, whereas T cell clones derived from cells originally CD45RO+ were CD45RA- and CD27-. In functional assays, IL-4 production could only be induced in CD45RA-CD27- CD4 clones by stimulation with PMA and ionomycin. Four of six CD45RA+ CD4 clones had suppressor activity in PWM-driven IgG synthesis, whereas five of six CD45RA- CD4 clones had helper activity. Of interest, the suppressor activity of CD45RA+CD27+ clones was partially blocked by pretreatment with anti-CD27 mAb (1A4). Anti-1A4 pretreatment of these T cell clones resulted in elevation of intracellular cAMP levels. Thus, CD27 appears to play a role in the function of CD45RA+CD27+ CD4 cells, and may be involved in suppressor activity of these cells at least in part via its effects on cAMP production.     

IL-2-R beta expression and function within resting CD8+ T cells preferentially segregate with the CD45R0+ subset.

Human peripheral blood CD8+ T cells constitutively express a low level of IL-2-R beta chains which were shown in this study to be preferentially carried by the CD45R0+ subset. Such receptors can transduce signals for in vitro IL-2-induced cytolytic function and for the initiation of soluble anti-CD3 and IL-2-induced cell proliferation. Using these stimulation models, a comparison was made between the responsiveness of resting, small CD45R0+ and CD45RA+ subpopulations of CD8+ T cells, both of them being isolated by negative selection and rigorously depleted of monocytes and of IL-2-inducible non-MHC-restricted CTL. Strong proliferation was induced in CD8+/CD45R0+ cells in response to IL-2 and soluble anti-CD3 (each of these stimuli being by itself ineffective), while in contrast, CD8+/CD45RA+ cells manifested, in this system, little reactivity. Accordingly, no conversion to the CD45R0 phenotype occurred in single stained CD45RA+ T cells following their incubation with the stimuli. A similar restriction of reactivity to CD8+/CD45R0+ T cells was observed with respect to IL-2-induced targetable T cell cytotoxicity. The CTL activity induced by IL-2 alone occurred without cell division. In contrast, the additional increase in CTL activity occurring upon the synergistic actions of anti-CD3 mAb and IL-2 coincided with intense cell proliferation, with no generation of LAK activity. The inhibition exerted by anti-IL-2-R beta mAb in the cytolytic and the proliferative activities induced by these stimuli in resting CD8+/CD45R0+ T cells emphasizes the importance of constitutive IL-2-R beta chains in the biology of these cells.     

Both naive and memory T cells can provide help for human IgE production, but with different cytokine requirements.

Most in vitro systems for the induction of IgE production by human B cells require both IL-4 and the presence of T cells. Little is known about the mechanism of T cell help or the ability of different T cell subsets to provide this helper activity. In the present study we demonstrate that, in the presence of exogenous IL-4, anti-CD3 stimulated naive T cells (CD4+CD45RA+) are potent helper cells for human IgE production. In their presence, as little as 750 autologous B cells can produce up to 100 ng/ml IgE. This response was found over a broad range of anti-CD3 concentrations. IgE helper activity by naive T cells was inhibited by IL-2. Under all conditions tested, naive T cells were unable to provide help for IgM production. This is in contrast to activated memory T cells (CD4+CD45RO+), which are very efficient helper cells for IgM or IgE production, provided that IL-2 or IL-2 plus IL-4 are present respectively.     

T cell regulation of human B cell proliferation and differentiation. Regulatory influences of CD45R+ and CD45R- T4 cell subsets

The immunoregulatory functions of human T4 cell subpopulations defined by mAb to the CD45R molecule (2H4) were examined. Both CD45R- and CD45R+ T4 cells that had been treated with mitomycin C (CD45R- and CD45R+ T4-mito) provided help for the generation of Ig-secreting cells (ISC) in cultures stimulated by PWM or by immobilized mAb to CD3 (64.1). IL-2 enhanced the generation of ISC in PWM-stimulated cultures and in anti-CD3-stimulated cultures containing CD45R+ T4-mito. The generation of ISC was maximal in cultures containing anti-CD3-activated CD45R- T4-mito and was not increased by IL-2. By contrast, CD45R+ T4 cells that had not been treated with mitomycin C suppressed B cell responses in cultures stimulated with PWM or anti-CD3, whereas CD45R- T4 cells suppressed the generation of ISC only in cultures stimulated with anti-CD3. IL-2 enhanced suppression by anti-CD3, but not PWM, activated CD45R- T4 cells. Suppression by CD45R+ T4 cells was maximal and not increased by IL-2. CD45R+ T4-mito were more effective suppressor-inducers in PWM-stimulated cultures, promoting the differentiation of suppressor-effector cells from CD8+ T cells. However, both CD45R+ and CD45R- T4-mito exerted comparable suppressor-inducer function in anti-CD3-stimulated cultures. Moreover, in anti-CD3-stimulated cultures, T8 cells could function as both suppressor-effector cells and suppressor-inducer cells. One of the functions of suppressor-inducer cells in this system appeared to involve the production of IL-2. Thus, the addition of IL-2 facilitated the induction of suppressor-effector T8 cells by CD45R- T4-mito in PWM-stimulated cultures. Although IL-2 production by the T cell subsets varied widely depending on the nature of the stimulus, these differences could not entirely explain their capacity to function as helper cells, suppressor-effector cells or suppressor-inducer cells. These results indicate that both CD45R+ and CD45R- T4 cells can help or suppress B cell responses, as well as induce suppressor-effector T8 cells. Moreover, suppressor-inducer function of T cells is not limited to the T4 cell population, but rather can also be accomplished by T8 cells. The results indicate that both T4 cell subsets and T8 cells exert multiple regulatory effects on human B cell function, with the nature of the activating stimulus playing a major role in determining the functional capacity of various T cell subsets.     

Stimulation via the CD3 and CD28 molecules induces responsiveness to IL-4 in CD4+CD29+CD45R- memory T lymphocytes

Although both IL-2 and IL-4 can promote the growth of activated T cells, IL-4 appears to selectively promote the growth of those helper/inducer and cytolytic T cells which have been activated via their CD3/TCR complex. The present study examines the participation of CD28 and certain other T cell-surface molecules in inducing T cell responsiveness to IL-4. Purified small high density T cells were cultured in the absence of accessory cells with various soluble anti-human T cell mAb with or without soluble anti-CD3 mAb and their responsiveness to IL-4 was studied. None of the soluble anti-T cell mAb alone was able to induce T cell proliferation in response to IL-4. A combination of soluble anti-CD3 with anti-CD28 mAb but not with mAb directed at the CD2, CD5, CD7, CD11a/CD18, or class I MHC molecules induced T cell proliferation in response to IL-4. Anti-CD2 and anti-CD5 mAb enhanced and anti-CD18 mAb inhibited this anti-CD3 + anti-CD28 mAb-induced T cell response to IL-4. In addition, anti-CD2 in combination with anti-CD3 and anti-CD28 mAb induced modest levels of T cell proliferation even in the absence of exogenous cytokines. IL-1, IL-6, and TNF were each unable to replace either anti-CD3 or anti-CD28 mAb in the induction of T cell responsiveness to IL-4, but both IL-1 and TNF enhanced this response. The anti-CD3 + anti-CD28 mAb-induced response to IL-4 was exhibited only by cells within the CD4+CD29+CD45R- memory T subpopulation, and not by CD8+ or CD4+CD45R+ naive T cells. When individually cross-linked with goat anti-mouse IgG antibody immobilized on plastic surface, only anti-CD3 and anti-CD28 mAb were able to induce T cell proliferation. These results indicate that the CD3 and CD28 molecules play a crucial role in inducing T cell responsiveness to IL-4 and that the CD2, CD5, and CD11a/CD18 molecules influence this process.     

Prostaglandin E2 selectively inhibits human CD4+ T cells secreting low amounts of both IL-2 and IL-4

PGE2 is a potent inflammatory mediator with profound immune regulatory actions. The present study examined the effects of PGE2 on the activation/proliferation of CD4+ T cells using 37 cloned CD4+ T cell lines. Ten T cell clones sensitive to PGE2 and 10 T cell clones resistant to PGE2, as measured by proliferation in response to anti-CD3 Ab, were selected for comparison. It was found that the PGE2-sensitive T cells were characterized by low production (<200 pg/ml) of both IL-2 and IL-4, while PGE2-resistant T cells secreted high levels (>1000 pg/ml) of IL-2, IL-4, or both. The roles of IL-2 and IL-4 were confirmed by the finding that addition of exogenous lymphokines could restore PGE2-inhibited proliferation, and PGE2-resistant Th1-, Th2-, and Th0-like clones became PGE2 sensitive when IL-2, IL-4, or both were removed using Abs specific for the respective lymphokines. In addition, we showed that the CD45RA expression in PGE2-sensitive T cells was significantly lower than that in PGE2-resistant cells (mean intensity, 1.2 +/- 0.6 vs 7.8 +/- 5.7; p = 0.001). In contrast, CD45RO expression in PGE2-sensitive T cells was significantly higher that that in PGE2-resistant cells (mean intensity, 55.7 +/- 15.1 vs 33.4 +/- 12.9; p = 0.02). In summary, PGE2 predominantly suppressed CD45RA-RO+ CD4+ T cells with low secretion of both IL-2 and IL-4.     

Differential activation requirements for virgin and memory T cells

Most studies of the activation requirements for T cells have used either T cell lines or populations of normal T cells that consist of a mixture of virgin and Ag-primed T cells. These two subpopulations of T cells can now be distinguished in humans by their reactivity with mAb. The anti-CD45R antibody HB10 identifies virgin T cells (T degrees) that are non-reactive to recall Ag and relatively poor at providing help for B cell differentiation. Conversely, memory T cells (T') that can react to recall Ag and enhance Ig production are non-reactive with anti-CD45R, but can be identified with the UCHL1 antibody. We have used these antibodies to separate the T degrees and T' populations and examine their activation requirements. On activation CD45R+ cells rapidly began to lose the CD45R Ag and express the UCHL1 Ag in increased amounts, whereas the UCHL1+ cells retained this phenotype. Both populations responded to PHA in the presence of monocytes, but when triggered by an antibody to CD3 only the T' cells were induced to express IL-2R, produce IL-2, and to proliferate. The T degrees population of cells remained relatively quiescent by all of these parameters. However, anti-CD3 stimulation conditioned the T degrees cells for IL-2 responsiveness, inasmuch as the addition of rIL-2 resulted in significant IL-2R expression and proliferation. When the CD4+ T degrees and CD4+ T' subpopulations were isolated and examined in the same assays similar results were obtained. The data indicate that fundamental differences exist in the triggering requirements for T degrees and T' cells.     

Generation of CD4(+)CD45RA(+) effector T cells by stimulation in the presence of cyclic adenosine 5'-monophosphate-elevating agents

After TCR cross-linking, naive CD4(+)CD45RA(+) T cells switch to the expression of the CD45RO isoform and acquire effector functions. In this study we have shown that cAMP-elevating agents added to anti-CD3- and anti-CD28-stimulated cultures of T lymphocytes prevent acquisition of the CD45RO(+) phenotype and lead to the generation of a new subpopulation of primed CD4(+)CD45RA(+) effector cells (cAMP-primed CD45RA). These cells displayed a low apoptotic index, as the presence of dibutyryl cAMP (dbcAMP)-rescued cells from CD3/CD28 induced apoptosis. Inhibition of CD45 splicing by dbcAMP was not reverted by addition of exogenous IL-2. cAMP-primed CD45RA cells had a phenotype characteristic of memory/effector T lymphocytes, as they showed an up-regulated expression of CD2, CD44, and CD11a molecules, while the levels of CD62L Ag were down-regulated. These cells also expressed the activation markers CD30, CD71, and HLA class II Ags at an even higher level than CD3/CD28-stimulated cells in the absence of dbcAMP. In agreement with this finding, cAMP-primed CD45RA cells were very efficient in triggering allogenic responses in a MLR. In addition, cAMP-primed CD45RA cells produce considerable amounts of the Th2 cytokines, IL-4, IL-10, and IL-13, whereas the production of IFN-gamma and TNF-alpha was nearly undetectable. The elevated production of IL-13 by neonatal and adult cAMP-primed CD45RA cells was specially noticeable. The cAMP-dependent inhibition of CD45 splicing was not caused by the production of immunosuppressor cytokines. These results suggest that within the pool of CD4(+)CD45RA(+) cells there is a subpopulation of effector lymphocytes generated by activation in the presence of cAMP-elevating agents.     

Immobilized anti-CD3-induced T cell growth: comparison of the frequency of responding cells within various T cell subsets.

Human T cells can be divided into subsets based on the expression of CD29, CD45RA, CD45RO, LFA-3, or CD11a. It has been suggested that the subset of CD4+ T cells that expresses high densities of CD29, CD11a, CD45RO, and LFA-3 contains "memory" T cells, whereas the subset of cells that expresses CD45RA contains "naive" T cells. In order to obtain a more complete picture of the functional capacities of human naive and memory CD4+ and CD8+ T cell subsets, highly purified T cells were activated with a uniform stimulus and responses were examined in bulk cultures and under limiting dilution conditions. T cell activation was achieved with an immobilized mAb to the CD3 molecular complex, 64.1. In bulk cultures, immobilized 64.1 stimulated a vigorous response. Moreover, the number of cells entering the cell cycle, the magnitude of the [3H]thymidine incorporation, and the growth of the cells over 6 days in culture by naive and memory CD4+ T cells was comparable. To delineate the frequency of responsive cells in each subset more precisely, cells were cultured with immobilized 64.1 at limiting dilution and the precursor frequency of responding cells was assessed by examining wells microscopically for visible growth. Immobilized 64.1 was able to induce some T cells from each subset to grow in the complete absence of AC, when exogenous IL2 was present. The number of responding CD4+ and CD8+ cells was comparable. The percentage of naive cells responding in each population was approximately three times greater than the frequency of memory cells. IL4 could also support the growth of immobilized 64.1-activated CD4+ T cells, but the frequency of responding cells was much lower than that supported by IL2. The vast majority of the IL-4 responsive CD4+ cells resided within the naive cell subset. The data indicate that the response of CD4+ and CD8+ naive and memory T cell subsets to immobilized anti-CD3 depends on the density of responding cells. Naive T cells have an enhanced capacity to grow when cultured in the absence of other T cells or accessory cells. This ability may facilitate their expansion during primary immune responses.     

Functions of rat CD4+ T cell subsets defined by CD45RB: CD45RB- cells have a much stronger response to recall antigens, whereas polyclonally activated cells of both subsets are equally efficient producers of IFN in the presence of exogenous IL-2.

CD4+45RB- rat T cells were shown to respond strongly to recall antigens and produce IFN and TNF after polyclonal activation. Compared to CD4+45RB- cells, CD4+45RB+ cells showed a very weak response to recall antigens but produced higher amounts of IFN and TNF after polyclonal activation. Addition of rIL-2 reduced the difference between the subsets with respect to the level of IFN produced at 48 and 72 hr after activation, but did not influence the level of TNF production. The CD4+45RB- cells clearly showed a faster response to polyclonal activation than that of CD4+45RB+ cells detected as an earlier IFN production and CD25 expression. The earlier IFN production by the CD45RB- population could not only be explained by their faster production of IL-2, since the difference persisted when rIL-2 was added to both populations at the beginning of culture. We conclude that the CD4+45RB- rat T cell population resemble the CD4+45RA-0+ human T cell subset with respect to a good responsiveness to recall antigen and efficient production of IFN. However, the CD4+45RB+ rat T cell subset functionally differs from the CD4+45RA+0- human T cell subset. We suggest that the CD4+45RB+ subset comprises a major CD4+45RA+B+0- and a minor CD4+4+45A-B+0+ T cell subpopulation, the latter possibly mediating a response to recall antigen and the production of IFN.