CD28 is an inducible T cell surface antigen that transduces a proliferative signal in CD3+ mature thymocytes

The rearrangement of TCR genes during thymic ontogeny creates a repertoire of T cell specificities that is refined to ensure the deletion of autoreactive clones and the MHC restriction of T cell responses. Signals delivered via the accessory molecules CD2, CD4, and CD8 have a crucial role in this phase of T cell differentiation. Recently, CD28 has been identified as a signal transducing molecule on the surface of most mature T cells. Perturbation of the CD28 molecule stimulates a novel pathway of T cell activation regulating the production of a variety of lymphokines including IL-2. We have studied the expression and function of CD28 during thymic ontogeny, and in resting and activated PBL. A variable percentage of resting thymocytes were CD28+ (3 to 25%, n = 8), but it was found in high density only on mature CD3+(bright) CD4/CD8 cells. Both unseparated thymocytes and isolated CD3-CD28-/dull cells proliferated when stimulated with PMA plus IL-2 or PMA plus ionomycin. PMA treatment also rapidly up-regulated CD28 expression in the CD3- subset as these cells became CD3-CD28+(bright). Despite the ability of PMA to induce high density CD28 expression in CD3- cells, CD3- thymocytes did not proliferate in response to PMA plus anti-CD28 mAb, in contrast to unseparated cells. CD3+ thymocytes stimulated with immobilized anti-CD3 mAb also failed to proliferate in culture. However, the addition of either IL-2 or anti-CD28 mAb supported proliferation, suggesting that only CD3+ cells could respond to CD28 signaling. The comitogenic effect of anti-CD3 and anti-CD28 mAb was IL-2 dependent as it was abrogated by an anti-IL-2R mAb. Interestingly, the expression of CD28 on the cell surface of CD3+ cells was also inducible, as flow cytometric analysis demonstrated a 10-fold increase in cell surface CD28 by 24 to 48 h after anti-CD3 stimulation of both CD3+ thymocytes and peripheral blood T cells. This increase was accounted for by a commensurate increase in CD28 mRNA levels. Together, these results suggest that CD28 is an inducible T cell antigen in both CD3- and CD3+ cells. In addition, stimulation of the CD28 pathway can provide a second signal to support the growth of CD3+ thymocytes stimulated through the TCR/CD3 complex, and may therefore represent a mechanism for positive selection during thymic ontogeny.     

"CD3low" human thymocyte populations can readily be triggered via the CD2 and/or CD28 activation pathways whereas the CD3 pathway remains nonfunctional

We have investigated the role of the CD2 and the CD28 Ag-independent pathways of activation on CD3low thymocytes. We previously showed that anti-CD28 mAb synergized with anti-CD2 mAb directed against epitopes T11.1 and T11.2, in the activation of purified resting T cells or unseparated thymocytes. Proliferation induced via CD2 plus CD28 was mediated via an IL-2-dependent pathway and was not affected by prior modulation of the CD3-TCR complex. Here, we show that a subset of CD3low thymocytes, although unresponsive to CD3 activation, can be activated to proliferate through the CD2 or the CD28 pathways, in the presence of exogenous IL-2. The mitogenic combination of mAb to CD2 and CD28 induces a proliferation of thymocytes which, in absence of exogenous lymphokines, is restricted to the more mature intrathymic subpopulation, CD1a-. However, CD3low thymocytes can also be triggered through the CD2 plus CD28 activation pathways but require at least addition of exogenous IL-2 to proliferate. This study demonstrates that a fraction of immature CD3low thymocytes possesses functional CD2 and CD28 surface molecules at a time when CD3 is not yet functional.     

Responsiveness of fetal and adult CD4-, CD8- thymocytes to T cell activation

Day-14 fetal CD4-, CD8- thymocytes showed a greater proliferative response to PMA + IL-4 than did adult double-negative thymocytes. In contrast, adult double-negative thymocytes were more responsive to PMA + IL-1 + IL-2 or to IL-1 + IL-2 alone. The adult double-negative thymocytes showed significantly greater proliferation than fetal thymocytes after stimulation via anti-CD3 or anti-Thy-1 in the presence or absence of interleukins (IL-1 + IL-2 or IL-4). Adult CD4-, CD8- thymocytes also exhibited greater calcium mobilization following anti-CD3 stimulation IL-2-dependent activation with anti-Thy-1 or IL-1 + IL-2 in the absence of PMA resulted in marked expansion of CD 3+, F23.1+, CD4-, CD8- thymocytes, a population absent in fetal thymocytes but constituting 4% of pre-cultured CD4-, CD8- adult thymocytes. IL-4 + PMA failed to expand this CD 3+ population. It is hypothesized that before expression of functional TCR, T cell development may be more dependent on activation pathways not using IL-2; after TCR expression, IL-2-dependent pathways, including Thy-1-mediated stimulation, become functional.     

Regulation of CD4 and CD8 surface expression on human thymocyte subpopulations by triggering through CD2 and the CD3-T cell receptor

Human thymocytes bearing the CD4 and/or CD8 antigens can be fractionated into cells with an immature and more mature phenotype based on their quantitative expression of the CD3 Ag (J. Immunol. 138:3108; J. Immunol. 139:1065). We show that the expression of CD4 and CD8 on thymocyte subpopulations with low CD3 (CD3L) and high CD3 (CD3H) is regulated by activation through the CD2 molecule and perturbation of the CD3-T cell receptor complex (CD3-Ti). Similar to its previously reported effects on peripheral T cells, PMA was able to induce the down-regulation of surface CD4, but not CD8, on thymocyte subpopulations. PMA could induce CD4 and CD8 phosphorylation in both CD3L and CD3H fractions. These results suggest that if changes in phosphorylation represent the mechanism by which CD4 and CD8 are able to transmit signals, this mechanism is operative in both CD3L and CD3H subpopulations. Treatment with anti-T11(2) and anti-T11(3) antibodies (CD2 activation pathway) resulted in partial down-regulation of CD4 but not CD8 surface expression on both CD3L and CD3H thymocytes. Similar treatment had no detectable effect on peripheral T cells. The down-regulation of surface CD4 induced by activation via CD2 could be inhibited by treatment of thymocytes with anti-CD3 antibodies. Treatment of thymocytes with anti-CD3 alone or following CD2 activation induced the selective down-regulation of surface CD8 within 15 minutes. These results suggest that CD2 and CD3-Ti triggering may regulate CD4 and CD8 surface expression on thymocytes. Furthermore, these results suggest that "cross-talk" between the CD2 and CD3-Ti pathway of activation may involve CD4 and CD8 molecules.     

Cultured human thymocytes lacking CD2 and CD11a/CD18 antigens are functional and adhere to endothelial cells via CD56 or CDw49d molecules.

The preferential growth of CD3-CD2-CD11a/CD18- thymocytes was obtained by stimulation of CD2-CD3- thymic cells with low doses of PMA (0.5 ng/ml) and subsequent culture in the presence of recombinant interleukin-2 (100 U/ml). After 2-3 weeks, CD3-CD2-CD11a/CD18- thymocytes represented 40-60% of the total proliferating cells. Highly purified CD3-CD2-CD11a/CD18- cell populations were obtained by depletion of the CD11a/CD18+ thymocytes by immunomagnetic beads. Moreover, these populations proliferated for 2-5 weeks and did not change their surface phenotype. It is of note that these cells, despite the lack of CD2 and CD11a/CD18 adhesion molecules, could bind to umbilical vein endothelial cells as efficiently as did CD3+CD2+CD11a/CD18+ thymocytes. Furthermore we demonstrate that (a) CD56 molecule is involved in the adhesion of CD3-CD2-CD11a/CD18- thymic cells, but not of peripheral CD3-CD56+ lymphocytes, to untreated or IFN-gamma- and/or TNF-alpha-treated endothelium, (b) anti-CDw49d mAb could inhibit the adhesion of this thymus-derived population to either IFN-gamma- or TNF-alpha-treated endothelial cells but not to untreated endothelium, and (c) CD56 antigen expressed by these cultured thymocytes has a sialic acid content different from that of peripheral lymphocytes. Indeed, isoelectrofocusing analysis showed that CD56 molecule expressed on CD3-CD2-CD11a/CD18- thymocytes displayed an isoelectric point (pI 5.0) different from that of CD56 antigen expressed by peripheral NK cells (pI 4.7 and 5.4). Further, we noted that CD56 antigen showed the same pI 5.8 after desialylation obtained using neuraminidase treatment. Finally, CD3-CD2-CD11a/CD18- thymocytes mobilized Ca2+ and released TNF-alpha and IFN-gamma after treatment with lectins.     

CD5 costimulation up-regulates the signaling to extracellular signal-regulated kinase activation in CD4+CD8+ thymocytes and supports their differentiation to the CD4 lineage

CD5 positively costimulates TCR-stimulated mature T cells, whereas this molecule has been suggested to negatively regulate the activation of TCR-triggered thymocytes. We investigated the effect of CD5 costimulation on the differentiation of CD4+CD8+ thymocytes. Coligation of thymocytes with anti-CD3 and anti-CD5 induced enhanced tyrosine phosphorylation of LAT (linker for activation of T cells) and phospholipase C-gamma (PLC-gamma) compared with ligation with anti-CD3 alone. Despite increased phosphorylation of PLC-gamma, this treatment down-regulated Ca2+ influx. In contrast, the phosphorylation of LAT and enhanced association with Grb2 led to activation of extracellular signal-regulated kinase (ERK) mitogen-activated protein kinase. When CD3 and CD5 on CD4+CD8+ thymocytes in culture were coligated, they lost CD8, down-regulated CD4 expression, and induced CD69 expression, yielding a CD4+(dull)CD8-CD69+ population. An ERK inhibitor, PD98059, inhibited the generation of this population. The reduction of generation of CD4+CD8- cells resulted from decreased survival of these differentiating thymocytes. Consistent with this, PD98059 inhibited the anti-CD3/CD5-mediated Bcl-2 induction. These results indicate that CD5 down-regulates a branch of TCR signaling, whereas this molecule functions to support the differentiation of CD4+CD8+ thymocytes by up-regulating another branch of TCR signaling that leads to ERK activation.     

CD1+ thymocytes proliferate and give rise to functional cells after stimulation with monoclonal antibodies recognizing CD3, CD2 or CD28 surface molecules.

The signal requirements for activation and proliferation of CD1+ thymocytes have been studied in order to define whether this immature cell population could function as mature T cells do. We found that CD1+ cells expressed high levels of CD25 antigen upon triggering with specific monoclonal antibodies (mAbs) (anti-CD3, anti-CD2, anti-CD28) in association with low doses of Phorbol-13-myristate-12-acetate (PMA). More interestingly, we described that in the presence of PMA CD1+ thymocytes proliferate upon stimulation with anti-CD28 mAb as well as with a pair of anti-CD2 mAbs, without the need of exogenous interleukin-2 (IL2), whereas they respond to anti-CD3 mAb only if exogenous IL2 was provided. Furthermore, CD1+ cells stimulated under optimal proliferative conditions, gave rise to cell populations capable of lysing natural killer (NK)-sensitive (K562) and NK-resistant (MEL 10, Daudi, EPA1) tumor target cells. These data strongly support the idea that CD1+ thymocytes, under appropriate stimulations, display some of the functional capabilities of mature T cells.     

CD3Ti+ human thymocyte-derived clones displaying a differential response to activation via CD3Ti and CD2

Previous studies indicated that, unlike peripheral T-cells, freshly isolated thymocytes show little or no proliferation to activation signals via either the antigen/MHC receptor complex (CD3Ti) or the CD2 structure, unless exogenous IL-2 or phorbol esters are added. To investigate these differences in more detail, we have studied the response of clonal populations of mature thymocyte subsets as well as peripheral T-cell clones to activation via either CD3Ti or CD2. Here we report the characterization of three clones belonging to different subsets of mature thymocytes: CD3+ CD4+ (Ti alpha/beta), CD3+ CD8+ (Ti alpha/beta), and CD3+ CD4- CD8- (Ti gamma/delta). All three clones could be induced to proliferate to insolubilized anti-CD3 mAb. In contrast, activating anti-CD2 mAbs, which induced proliferation in all peripheral T-cell clones tested, did not induce an appreciable proliferation of the thymocyte clones. The latter required additional signals provided by the phorbol ester PMA. However, anti-CD2 mAbs were able to induce early activation events such as phosphoinositide turnover and [Ca2+]i increase to an extent similar to the ones elicited by anti-CD3 mAb. These results further support previous findings suggesting that mature thymocytes are not functionally identical to peripheral T-cells.     

Comitogenic effect of solid-phase immobilized anti-1F7 on human CD4 T cell activation via CD3 and CD2 pathways

We have recently developed a mAb, anti-1F7, which defines a family of structures found to include the molecule recognized by anti-Ta1 (CD26). In this paper, we demonstrated that binding of 1F7 by solid-phase immobilized anti-1F7 mAb but not anti-Ta1 mAb has a comitogenic effect by inducing proliferation of human CD4+ T lymphocytes in conjunction with submitogenic doses of anti-CD3 or anti-CD2. The proliferative response induced via the CD3-1F7 or CD2-1F7 pathways is associated with the IL-2 autocrine pathway, including IL-2 production. IL-2R expression and anti-IL-2R (Tac) inhibition. Furthermore, solid-phase immobilization of anti-1F7 but not anti-Ta1 acts in conjunction with submitogenic doses of PMA to mediate a comitogenic effect in the absence of anti-CD3 or anti-CD2, leading to CD4+ T cell proliferation. PMA treatment, in the meantime, leads to enhanced expression of 1F7 on the T cell surface. Despite its functional association with both pathways of activation, however, the 1F7 structure is not comodulated with the CD3/TCR complex nor the CD2 molecule. These findings thus suggest that the CD26 Ag is involved in CD3 and CD2-induced human CD4+ T cell activation.     

Thymic shared antigen-2: a novel cell surface marker associated with T cell differentiation and activation

Thymic shared Ag-2 (TSA-2) is a 28-kDa, glycophosphatidylinitosol-linked cell surface molecule expressed on various T cell and thymic stromal cell subsets. It is expressed on most CD3-CD4-CD8-, CD4+CD8+, and CD3highCD4-CD8+ thymocytes but is down-regulated on approximately 40% of CD3highCD4+CD8- thymocytes. Expression on peripheral TCR-alphabeta+ T cells is similar to that of CD3+ thymocytes, although a transient down-regulation occurs with cell activation. Consistent with the recent hypothesis that emigration from the thymus is an active process, recent thymic emigrants are primarily TSA-2-/low. TSA-2 expression reveals heterogeneity among subpopulations of CD3highCD4+CD8- thymocytes and TCR-gamma delta+ T cell previously regarded as homogenous. The functional importance of TSA-2 was illustrated by the severe block in T cell differentiation caused by adding purified anti-TSA-2 mAb to reconstituted fetal thymic organ culture. While each CD25/CD44-defined triple-negative subset was present, differentiation beyond the TN stage was essentially absent, and cell numbers of all subsets were significantly below those of control cultures. Cross-linking TSA-2 on thymocytes caused a significant Ca2+ influx but no increase in apoptosis, unless anti-TSA-2 was used in conjunction with suboptimal anti-CD3 mAb. Similar treatment of mature TSA-2+ T cells had no effect on cell survival or proliferation. This study reveals TSA-2 to be a functionally important molecule in T cell development and a novel indicator of heterogeneity among a variety of developing and mature T cell populations.     

Engagement of CD28 modulates CXC chemokine receptor 4 surface expression in both resting and CD3-stimulated CD4+ T cells

Optimal CD4+ T cell activation requires the cooperation of multiple signaling pathways coupled to the TCR-CD3 complex and to the CD28 costimulatory molecule. In this study, we have investigated the expression of surface CXC chemokine receptor 4 (CXCR4) in enriched populations of CD4+ T PBL, stimulated with anti-CD3 and anti-CD28 mAbs, immobilized on plastic. Anti-CD3 alone induced a progressive down-regulation of surface CXCR4, accompanied by a significant decline in the entry of the HXB2 T cell line-tropic (X4-tropic) HIV-1 clone in CD4+ T cells. Of note, this effect was strictly dependent on the presence in culture of CD14+ monocytes. On the other hand, anti-CD28 alone induced a small but reproducible increase in the expression of surface CXCR4 as well as in the entry of HXB2 HIV-1 clone in resting CD4+ T cells. When the two mAbs were used in combination, anti-CD28 potently synergized with anti-CD3 in inducing the expression of CD69 activation marker and stimulating the proliferation of CD4+ T cells. On the other hand, anti-CD28 counteracted the CXCR4 down-modulation induced by anti-CD3. The latter effect was particularly evident when anti-CD28 was associated to suboptimal concentrations of anti-CD3. Because CXCR4 is the major coreceptor for the highly cytopathic X4-tropic HIV-1 strains, which preferentially replicate in proliferating CD4+ T cells, the ability of anti-CD28 to up-regulate the surface expression of CXCR4 in both resting and activated CD4+ T cells provides one relevant mechanism for the progression of HIV-1 disease.     

Cytokine production by mature and immature CD4-CD8- T cells. Alpha beta-T cell receptor+ CD4-CD8- T cells produce IL-4.

This study follows our previous investigation describing the production of four cytokines (IL-2, IL-4, IFN-gamma, and TNF-alpha) by subsets of thymocytes defined by the expression of CD3, 4, 8, and 25. Here we investigate in greater detail subpopulations of CD4-CD8- double negative (DN) thymocytes. First we divided immature CD25-CD4-CD8-CD3- (CD25- triple negative) (TN) thymocytes into CD44+ and CD44- subsets. The CD44+ population includes very immature precursor T cells and produced high titers of IL-2, TNF-alpha, and IFN-gamma upon activation with calcium ionophore and phorbol ester. In contrast, the CD44- subset of CD25- TN thymocytes did not produce any of the cytokines studied under similar activation conditions. This observation indicates that the latter subset, which differentiates spontaneously in vitro into CD4+CD8+, already resembles CD4+CD8+ thymocytes (which do not produce any of the tested cytokines). We also subdivided the more mature CD3+ DN thymocytes into TCR-alpha beta- and TCR-gamma delta-bearing subsets. These cells produced cytokines upon activation with solid phase anti-CD3 mAb. gamma delta TCR+ DN thymocytes produced IL-2, IFN-gamma and TNF-alpha, whereas alpha beta TCR+ DN thymocytes produced IL-4, IFN-gamma, and TNF-alpha but not IL-2. We then studied alpha beta TCR+ DN T cells isolated from the spleen and found a similar cytokine production profile. Furthermore, splenic alpha beta TCR+ DN cells showed a TCR V beta gene expression profile reminiscent of alpha beta TCR+ DN thymocytes (predominant use of V beta 8.2). These observations suggest that at least some alpha beta TCR+ DN splenocytes are derived from alpha beta TCR+ DN thymocytes and also raises the possibility that these cells may play a role in the development of Th2 responses through their production of IL-4.     

IL-7 maintains the T cell precursor potential of CD3-CD4-CD8- thymocytes.

We and other investigators have reported that IL-4 (in the presence of PMA) or IL-7 (used alone) induce proliferation of both adult and fetal (gestation day 15) CD4-CD8- thymocytes. These results suggested that these cytokines may be growth factors for pre-T cells. However, we recently observed that among adult CD4-CD8- thymocytes, only the CD3+ subset proliferates in response to IL-7, whereas IL-4 + PMA induces proliferative responses in both CD3- and CD3+ subsets. Thus, we concluded that IL-7 used alone is not a potent growth stimulus for adult thymic CD3-CD4-CD8- triple negative (TN) T cell precursors. Interestingly, the viability of adult TN thymocytes in culture was improved by IL-7 for up to 1 wk, in spite of the inability of IL-7 to induce significant [3H]TdR incorporation in these cells. After culture in IL-7 for 4 days, the viable cells remained CD4-CD8-, but 25 to 35% expressed CD3 whereas the rest remained CD3-. In contrast, most of the cells cultured with IL-4 + PMA for 4 days remained TN. To investigate whether adult TN thymocytes that survive in vitro in the presence of IL-4 + PMA or IL-7 retain T cell progenitor potential, we tested whether they could reconstitute lymphoid cell-depleted (2-deoxyguanosine-treated) fetal thymus organ cultures. Our results demonstrate that TN cells cultured in IL-7 retain T cell progenitor potential.     

A soluble form of the human T cell differentiation antigen CD27 is released after triggering of the TCR/CD3 complex.

The human T cell Ag CD27 belongs to a recently defined family of cell surface receptors, including the nerve growth factor receptor, two distinct tumor necrosis factor receptors, and the B cell specific molecule CD40. On resting T cells, CD27 is a transmembrane homodimer with subunits of 50 to 55 kDa (p55). T cell activation via the TCR/CD3 complex causes a strong enhancement of p55 expression. Concomitantly, an alternative form of the CD27 molecule with a molecular mass of 28 to 32 kDa (p32) appears at the cell surface. With the use of ELISA, we here show that a soluble form of CD27 (sCD27) can be detected in the supernatant of T cells activated with anti-CD3 or combinations of anti-CD2 mAb. Moreover, sCD27 is found in both serum and urine from healthy donors. sCD27, purified from either culture supernatant or urine, has a molecular mass of 28 to 32 kDa and is, according to peptide mapping, structurally homologous to the p55 membrane form of CD27. Quantification of sCD27 levels may be used as a marker for T lymphocyte activation in vivo.     

Expression and function of the UM4D4 antigen in human thymus

UM4D4 is a newly identified T cell surface molecule, distinct from the Ag receptor and CD2, which is expressed on 25% of peripheral blood T cells, resting or activated. Monoclonal anti-UM4D4 is mitogenic for T cells and T cell clones. Since alternative activation pathways independent of Ag/MHC recognition may be important in thymic differentiation, the expression and function of UM4D4 was examined in human thymus. UM4D4 was found on the surface of 6% of thymocytes. All thymocyte subsets contained UM4D4+ cells but expression was greatest on thymocytes that were CD1- (12%), CD3+ (11%) and especially CD4-CD8- (18%). CD3+CD4- CD8- cells, most of which bear the gamma delta-receptor, were greater than or equal to 50% + for UM4D4. Moreover, anti-UM4D4 was comitogenic for thymocytes together with PMA or IL-2. Anti-UM4D4 also reacted strongly with a subset of thymic epithelial cells in both cortex and medulla. Dual color fluorescence microscopy, with anti-UM4D4 and antibodies to other thymic epithelial Ag, showed UM4D4 expression on neuroendocrine thymic epithelium but not on thymic fibrous stroma. Thus, UM4D4 is expressed on, and represents an activation pathway for, a subset of thymic T cells. In addition, this determinant, initially identified as a novel T cell activating molecule, is broadly expressed by neuroendocrine thymic epithelium. Although the function of UM4D4 on the thymic epithelial cells is not yet clear, it is possible that UM4D4 represents a pathway for the functional activation of a subset of the thymic epithelium as well as a subset of thymocytes, thus playing a dual role in T cell differentiation.     

1F7 (CD26): a marker of thymic maturation involved in the differential regulation of the CD3 and CD2 pathways of human thymocyte activation.

We have recently shown that solid-phase immobilization of anti-1F7 recognizing the 110-kDa CD26 Ag is comitogenic for human peripheral blood T cell activation via both the CD3 and CD2 pathways. We have also demonstrated that binding of anti-1F7 leads to the disappearance of CD26 surface expression, and this anti-1F7-induced modulation results in an increase in anti-CD3 or anti-CD2-mediated peripheral blood T cell activation. In this report, we extended these findings by examining the expression and functional relationship of 1F7 on the CD3 and CD2 pathways of activation of human thymocytes. We now demonstrated that most of the anti-1F7 reactivity is found on medullary thymocytes, the population of thymocytes expressing high level of CD3 (CD3H). We have also shown that binding of anti-1F7 can induce a decrease in CD26 surface expression, with no detectable effect on the surface expression of CD3 or CD2. Most importantly, we showed that solid-phase immobilization of anti-1F7 has a comitogenic effect on thymocyte activation induced by anti-CD3 but not anti-CD2. In addition, anti-1F7-induced modulation of CD26 results in an enhancement in CD3-mediated but not CD2-mediated human thymocyte activation. The observed functional effect of CD26 on the CD3/TCR pathway of activation is mainly restricted to mature thymocytes as distinguished by high surface expression of CD5, although CD26 is also functionally associated with the CD3/TCR pathway on cells expressing low level of CD5. Demonstrating that CD26 involvement in the regulation of human thymocyte activation is restricted mainly to the CD3 pathway, unlike its involvement with both the CD3 and CD2 pathways of mature peripheral blood T lymphocyte activation, our data hence suggested that CD26 may play a role in thymic differentiation and maturation via the differential engagement of the CD3 pathway.     

Human T-cell leukemia virus type I-induced proliferation of human immature CD2+CD3- thymocytes.

The mitogenic activity of human T-cell leukemia virus type I (HTLV-I) is triggering the proliferation of human resting T lymphocytes through the induction of the interleukin-2 (IL-2)/IL-2 receptor autocrine loop. This HTLV-I-induced proliferation was found to be mainly mediated by the CD2 T-cell antigen, which is first expressed on double-negative lymphoid precursors after colonization of the thymus. Thus, immature thymocytes express the CD2 antigen before that of the CD3-TCR complex. We therefore investigated the responsiveness of these CD2+CD3- immature thymocytes and compared it with that of unseparated thymocytes, containing a majority of the CD2+CD3+ mature thymocytes, and that of the CD2-CD3- prothymocytes. Both immature and unseparated thymocytes were incorporating [3H]thymidine in response to the virus, provided that they were cultivated in the presence of submitogenic doses of phytohemagglutinin. In contrast, the prothymocytes did not proliferate. Downmodulation of the CD2 molecule by incubating unseparated and immature thymocytes with a single anti-CD2 monoclonal antibody inhibited the proliferative response to HTLV-I. These results clearly underline that the expression of the CD2 molecule is exclusively required in mediating the proliferative response to the synergistic effect of phytohemagglutinin and HTLV-I. Immature thymocytes treated with a pair of anti-CD2 monoclonal antibodies were shown to proliferate in response to HTLV-I, even in the absence of exogenous IL-2. We further verified that the proliferation of human thymocytes is consecutive to the expression of IL-2 receptors and the synthesis of IL-2. These observations provide evidence that the mitogenic stimulus delivered by HTLV-I is more efficient than that provided by other conventional mitogenic stimuli, which are unable to trigger the synthesis of endogenous IL-2. Collectively, these results show that the mitogenic activity of HTLV-I is able to trigger the proliferation of cells which are at an early stage of T-cell development. They might therefore represent target cells in which HTLV-I infection could favor the initiation of the multistep lymphoproliferative process leading to adult T-cell leukemia.     

A specific inhibitor of the p38 mitogen activated protein kinase affects differentially the production of various cytokines by activated human T cells: dependence on CD28 signaling and preferential inhibition of IL-10 production

Cytokine production upon T cell activation results from the integration of multiple signaling pathways from TCR/CD3 and from costimulatory molecules such as CD28. Among these pathways, the possible role of p38 mitogen activated protein kinase (MAPK) is the least understood. Here, we used a highly specific p38 MAPK inhibitor, the SB203580 compound, to examine the role of this enzyme in the induction of various cytokines in human T cells stimulated with anti-CD3 and anti-CD28 mAb together or in combination with PMA. Cytokine induction was monitored by ELISA and at the mRNA level. While SB203580 had little effect on IL-2 production and proliferation, it significantly reduced the production of several other cytokines. The secretion of IL-4, IL-5, IL-13, and TNF-alpha was inhibited by 20-50% with modes of T cell activation involving the CD28 pathway, whereas their mRNA expression was little affected. In contrast, IFN-gamma induction via CD28/PMA or CD3/CD28, but not CD3/PMA, was markedly diminished both at the protein and at the mRNA levels. Most interestingly, SB203580 also suppressed IL-10 secretion and mRNA induction via CD28-dependent activation by 75-85% (IC50 approximately 0.2 microM). Subset analysis suggested that this inhibition did not reflect a differential effect on T cell subsets. Therefore, p38 MAPK activity appears to contribute to cytokine production, mostly via CD28-dependent signaling. Moreover, IL-10 seems to rely more on this activity than other cytokines for its induction in T cells.