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.     

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.     

Mitogen-induced IL-2 production and proliferation at defined stages of T helper cell development.

Th cell development inside the thymus can be defined on the basis of qualitative and quantitative CD4 and CD8 marker expression and follows the pathway of CD4-8- cells----CD4+8+ cells----CD4+8low cells----CD4+8- cells, which presumably emigrate to seed the periphery and serve as functionally mature Th cells. The various cell subpopulations at defined developmental stages were isolated by electronic cell sorting and examined for mitogen induced IL-2 production and cell proliferation responses. For TCR-alpha beta-bearing CD4+8+ and CD4+8low thymocytes that are actively engaged in positive and negative selection processes, negligible to low levels of IL-2 production and cell proliferation were observed in response to TCR:CD3 triggering or to the combined activation of protein kinase C and calcium mobilization mediated by PMA and ionomycin, respectively. For CD4-8- TCR-alpha beta early thymocytes that have not yet entered the selection process, PMA + ionomycin induced significant cell proliferation but little IL-2 production, in the absence of added IL-1. However, addition of IL-1 caused a powerful induction of IL-2 production that was accompanied by increased cell proliferation. Triggering of the TCR:CD3 complex had no effect on CD4-8-TCR(-)-alpha beta thymocytes as they do not express detectable levels of TCR-alpha beta. For thymus CD4+8- Th cells, the first cells that have completed TCR repertoire selection, vigorous proliferation was observed in response to TCR:CD3 triggering in the presence of added IL-2. However, the development of IL-2 responsiveness was not accompanied by high level IL-2 inducibility as TCR:CD3 triggering caused only marginal IL-2 production. In contrast, spleen CD4+8- T cells, the most "mature" representatives of Th cells, expressed high levels of IL-2 production as well as IL-2 responsiveness in response to TCR:CD3-mediated stimulation. The lack of anti-TCR-induced IL-2 production by thymus CD4+8- T cells was not due to an intrinsic defect as high levels of IL-2 production was induced by PMA + ionomycin. Possible reasons for the temporal acquisition and differential control of IL-2 inducibility and IL-2 responsiveness are discussed in the context of established Th cell development pathway.     

CD45R as a primary signal transducer stimulating IL-2 and IL-2R mRNA synthesis by CD3-4-8- thymocytes

CD45R is a high molecular weight (p205/220) form of a series of transmembrane glycoproteins, collectively known as CD45 and present in some form on all lymphoid cells. We have proposed that CD45R+ thymocytes, a minority (15 to 30%) of total thymocytes, represent the generative thymic lineage whereas CD45 p180+ thymocytes are destined for intrathymic death. To test this hypothesis, we prepared human thymus fractions enriched for the expression of CD45R by exhaustive depletion of CD45 p180+ cells, as well as progenitor CD3-4-8- "multinegative" thymocytes which are predominantly CD45R+. Northern analysis of RNA extracted from CD45 p180- and multinegative thymus fractions demonstrated that these populations are enriched for cells able to synthesize mRNA encoding IL-2 and IL-2R after mitogenic stimulation, as compared to unfractionated thymus, consistent with the properties expected for generative thymocytes. Postulating that the CD45R glycoprotein might represent an important signal delivery molecule, we analyzed the ability of mAb specific for CD45 epitopes to synergize with suboptimal amounts of PHA and PMA in the stimulation of IL-2 mRNA production by multinegative thymocytes. We found that CD45R-specific mAb synergizes strongly with PHA/PMA to stimulate IL-2 and IL-2R mRNA expression. In contrast, mAb to CD45 common determinants were unable to synergize. Multinegative thymocytes depleted of all CD45 p180+ cells were compared to total multinegative cells and found to synthesize fourfold greater levels of IL-2 mRNA after stimulation with anti-CD45R mAb. This CD45 p180- multinegative subset is enriched for cells expressing a high density of CD45R, and for CD45- thymus cells, suggesting a possible enrichment for nonlymphoid cells which may play a role in the stimulation process. Our results suggest that the extended amino acid insert of CD45R plays a fundamental role in transmembrane signalling, and that CD45R may be a primary signal transducer for developing thymic progenitor cells.     

Athymic nude CD4+8- T cells produce IL-2 but fail to proliferate in response to mitogenic stimuli

A comparative study of immune functions of CD4+8- T cells isolated from normal and athymic nude mice by electronic cell sorting was performed. Athymic nude CD4+8- T cells expressed the TCR-associated CD3 molecule but the level of expression was significantly lower than that of normal CD4+8- T cells. Proliferative responses were studied upon stimulation by 1) the T cell mitogen Con A; 2) anti-CD3 mediated cross-linking of the CD3:TCR complex, and 3) the combined action of PMA + ionomycin. All three mitogenic stimuli caused readily detectable cell division in normal (euthymic) CD4+8- T cells. In marked contrast, none of the mitogenic stimuli induced significant proliferation in athymic nude CD4+8- T cells. The failure of athymic nude CD4+8- T cells to proliferate occurred over a wide range of mitogen concentrations and over a 4-day observation period. Neither exogenously supplied rIL-2 or mixed lymphocyte culture supernatant had any effect on the impaired proliferative response by athymic nude CD4+8- T cells. Although IL-2 was produced by athymic nude CD4+8- T cells at a reduced level when compared to normal CD4+8- T cells, it was nevertheless readily detected upon stimulation with either Con A or anti-CD3. Furthermore, stimulation of athymic nude CD4+8- T cells by anti-CD3 induced the expression of the p55 chain of IL-2R on the cell surface. Therefore, despite production of IL-2 and induced expression of IL-2R, athymic nude CD4+8- T cells failed to undergo cell division.     

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.     

IL-2 and IL-4 stimulate different subpopulations of double-negative thymocytes

Double-negative (CD4-/CD8-) thymocytes from young adult mice can be separated into two distinct subpopulations on the basis of the binding of mAb 7D4 directed against the receptor for IL-2. The 7D4+ cells have predominantly nonrearranged TCR beta-chain genes and express incomplete 1.0-kb beta-messages, whereas the 7D4- cells have rearranged beta-genes and express complete 1.3-kb as well as incomplete 1.0-kb beta-messages. These two populations of double-negative thymocytes also differ in their responses to IL-2 and IL-4. The 7D4+ cells are nonresponsive to IL-2 alone or IL-2 plus PMA but they are stimulated to proliferate by the combination of IL-4 and PMA. In contrast, the 7D4- cells vigorously proliferate in response to IL-2 alone or IL-2 plus PMA but they respond poorly to IL-4 alone or IL-4 plus PMA. These results suggest that IL-2 and IL-4 may be involved in the stimulation of immature thymocytes at distinct steps of their differentiation. IL-4 together with PMA stimulate immature thymocytes which seem to express the IL-2R but do not respond to IL-2.     

Heterogeneity of immature (Lyt-2-/L3T4-) thymocytes. Identification of four major phenotypically distinct subsets differing in cell cycle status and in vitro activation requirements

Thymocytes that bear neither Lyt-2 nor L3T4 differentiation Ag (2-4- thymocytes) contain the precursors of mature Lyt-2+ and L3T4+ T cells. In the present study, we have identified four major subpopulations of 2-4- cells in adult C57BL/6 mice that differ in surface phenotype and in situ proliferative status. Two-color immunofluorescence analysis with RL-73 (a mAb recognizing an as yet unidentified activation Ag) and PC-61 (an anti-IL-2R mAb) revealed three distinct subsets of 2-4-thymocytes: RL-73+ IL-2R- (30%), RL-73+/-IL-2R+ (45%), and RL-73- IL-2R- (25%). The RL-73+ IL-2R- subset had the highest percentage of large blasts and cycling cells, whereas the RL-73+/- IL-2R+ and RL-73- IL-2R- subsets had intermediate and low percentages, respectively, indicating that in situ proliferation correlated better with RL-73 intensity than with IL-2R expression. An additional marker, heat-stable Ag (HSA), was found to further subdivide the RL-73- population into RL-73- HSA- (10% of total 2-4-) and RL-73- HSA+ (15%) fractions. The two latter (RL-73-) subsets appeared to be more "mature" than the former since they expressed high levels of Lyt-1 and appeared later during fetal thymus ontogeny. In parallel with the phenotypic analysis, we compared the in vitro activation requirements of each of the four purified 2-4- subsets. All four populations proliferated well to the combination of phorbol ester (PMA), ionomycin, and IL-2. In response to PMA and ionomycin (without added IL-2), only RL-73- HSA-cells proliferated and this proliferation was correlated with IL-2 production. However, if IL-1 was included with PMA and ionomycin then all four populations responded. Finally, a proliferative response to Con A or mitogenic anti-Thy-1 mAb was observed only for RL-73- HSA+ and (to a lesser extent) RL-73- HSA-cells. These data indicate that each of the four phenotypically distinct subpopulations of immature thymocytes can also be distinguished on the basis of their in vitro activation requirements.     

IL-2, IL-6, and IFN-gamma have distinct effects on the IL-4 plus PMA-induced proliferation of thymocyte subpopulations

We have previously reported complex effects of cytokine-containing T cell supernatants on the interleukin (IL)4 plus phorbol 12-myristate 13-acetate (PMA)-induced proliferative response of murine thymocytes. Here we show that recombinant murine IL-2, IL-6, and IFN-gamma each differentially regulate the IL-4/PMA-driven growth of thymocyte subpopulations. Thymocytes fractionated into four subpopulations on the basis of CD4 and CD8 expression were stimulated to proliferate by IL-4/PMA. Interferon-gamma (IFN-gamma) caused almost complete inhibition of the CD4+/CD8- response but had no measurable effect on the growth of CD4-/CD8+ or CD4-/CD8- populations. This inhibitory effect was also observed on splenic CD4+/CD8- T cells. In contrast, IL-6 strongly enhanced the proliferative response of CD4+/CD8- thymocytes, but showed no effect on peripheral CD4+/CD8- T cells, suggesting that IL-6 may be an important regulator of growth in the thymus. IL-2 also enhanced the proliferation of both CD4-/CD8+ and CD4-/CD8- thymocytes to IL-4 and PMA. To test whether the IL-4/PMA stimulus provided all the signals required to initiate growth in each subpopulation, we titrated cell number and examined the relationship between cell dose and cell response. Growth of CD8+/CD4- cells was cell density independent, indicating that IL-4/PMA is sufficient stimulus to induce growth of these cells. In contrast, growth of CD4-/CD8- and CD4+/CD8- cells is cell density dependent, suggesting a requirement for another signal provided by the cells themselves. These observations suggest that more signals remain to be identified in this thymocyte growth system.     

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.     

Cytokine production by mature and immature thymocytes.

We have studied the ability of subpopulations of activated thymocytes to produce four cytokines (IL-2, IL-4, IFN-gamma and TNF-alpha) which are believed to play roles in T cell development. Supernatants from various thymocyte subsets activated with calcium ionophore and PMA were tested for these cytokines. All CD3hi thymocyte subsets (CD4+8-, CD4-8- and CD4-8+) produced high titers of these four cytokines except CD3+4-8+ thymocytes, which did not produce IL-4. In contrast, CD4+8+ thymocytes did not produce any detectable cytokines. CD3-4-8- thymocytes produced IL-2, IFN-gamma, and TNF-alpha (but not IL-4) when activated by calcium ionophore + PMA and IL-1. We then separated CD3-4-8- thymocytes into IL-2R+ and IL-2R-. CD3-4-8-IL-2R+ thymocytes only produced small amounts of IL-2 when activated with calcium ionophore + PMA + IL-1, whereas CD3-4-8-IL-2R- thymocytes did not require IL-1 to produce IL-2, IFN-gamma, and TNF-alpha. Finally, CD4-8+3- thymocytes (an immature population believed to be an intermediate between CD3-4-8- and CD4+8+ thymocytes) only produced marginally detectable levels of IL-2 upon stimulation with calcium ionophore, PMA, and the addition of IL-1 did not result in increased levels of cytokine production. These observations indicate discrete patterns of cytokine production by the subsets studied and suggest specific controls of cytokine gene expression during T cell development.     

T-deficient transmembrane signaling in CD4+ T cells of retroviral-induced immune-deficient mice.

The defective virus found in the LP-BM5 mixture of murine leukemia viruses induces a severe immune deficiency disease in C57BL/6 mice that is characterized by the activation and expansion of T and B cells that become unresponsive to normal immune stimuli. The nature of the biochemical lesion in these defective lymphocyte populations remains unknown. Flow cytometric analysis of the T cell population in infected animals has demonstrated expansion of both CD4+ and CD8+ subsets. Despite chronic expansion in vivo, CD4+ T cells by wk 4 postinfection failed to up-regulate cell surface IL-2R expression, produced IL-2, or proliferate in vitro in response to either Con A, Staphylococcal enterotoxin super-antigens, or anti-CD3 stimulation. Exogenous IL-2 did not restore the proliferative response and also failed to up-regulate IL-R expression on CD4+ T cells from infected mice, even though basal IL-2R expression was initially elevated compared to normals. In contrast, CD4+ T cells from infected mice could be induced to proliferate by stimulation with PMA and ionomycin resulting in IL-2R up-regulation, IL-2 production, and proliferation. Moreover, proliferation could also be induced by anti-CD3 plus PMA, although anti-CD3 plus ionomycin was without effect. These studies suggest that chronic expansion of CD4+ T cells in infected mice is probably not maintained by normal TCR signaling, which appears defective in these cells. In addition, the lesion in biochemical signaling appears to result in defective activation of protein kinase C, which can be overcome by direct activation with PMA.     

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.     

Distinct patterns of lymphokine requirement for the proliferation of various subpopulations of activated thymocytes in a single cell assay

The frequency and capacity for clonal expansion of several murine thymocyte subpopulations responsive to various IL (fetal day 15, and adult CD4-8-, CD4+8- and CD4-8+) were investigated using a single-cell limiting-dilution cell culture system without filler cells. This assay requires the presence of PMA and ionomycin. The main conclusions of these studies are the following: 1) IL-4 is a better growth factor than IL-2 for immature thymocytes (fetal day 15 or adult CD4-8-). 2) IL-2 is a better growth factor than IL-4 for mature phenotype thymocytes (CD4+8- and CD4-8+). 3) IL-4 is a relatively poor growth factor for adult CD4-CD8- thymocytes and CD4+CD8- thymocytes, while it induced strong responses in fetal day 15 and CD4-8+ thymocytes. 4) IL-6 enhanced the response of CD4+8- thymocytes to either IL-2 or IL-4. 5) Cortisone-resistant thymocytes grown initially with IL-4 and then switched to IL-2 showed a significant decrease in cloning efficiency. No inhibitory effect was observed when cells were cultured first with IL-2 and then switched to IL-4. 6) Finally, supernatant from Con-A stimulated rat spleen cells induced maximal growth of all adult thymocyte populations tested, suggesting that unidentified thymocyte growth factor(s) remain to be characterized. These results indicate that the maturational stage of thymocytes determines their requirements for activation and proliferation.     

Growth-promoting activity of IL-1 alpha, IL-6, and tumor necrosis factor-alpha in combination with IL-2, IL-4, or IL-7 on murine thymocytes. Differential effects on CD4/CD8 subsets and on CD3+/CD3- double-negative thymocytes

Many cytokines (including IL-1, IL-2, IL-4, IL-6, and TNF-alpha) have been shown to induce thymocyte proliferation in the presence of PHA. In this report, we demonstrate that certain cytokine combinations induce thymocyte proliferation in the absence of artificial comitogens. IL-1 alpha, IL-6, and TNF-alpha enhanced the proliferation of whole unseparated thymocytes in the presence of IL-2, whereas none of them induced thymocyte proliferation alone. In contrast, of these three enhancing cytokines, only IL-6 enhanced IL-4-induced proliferation. We also separated thymocytes into four groups based on their expression of CD4 and CD8, and investigated their responses to various cytokines. The results indicate that each cytokine combination affects different thymocyte subsets; thus, IL-1 alpha enhanced the proliferation of CD4-CD8- double negative (DN) thymocytes more efficiently than IL-6 in the presence of IL-2, whereas IL-6 enhanced the responses of CD4+CD8- and CD4-CD8+ single positive (SP) thymocytes to IL-2 or IL-4 better than IL-1 alpha. TNF-alpha enhanced the proliferation of both DN and both SP subsets in the presence of IL-2 and/or IL-7. None of these combinations induced the proliferation of CD4+CD8+ double positive thymocytes. Finally, DN were separated into CD3+ and CD3- populations and their responsiveness was investigated, because recent reports strongly suggest that CD3+ DN thymocytes are a mature subset of different lineage rather than precursors of SP thymocytes. CD3+ DN proliferated in response to IL-7, TNF-alpha + IL-2, and IL-1 + IL-2. CD3- DN did not respond to IL-7 or to IL-1 + IL-2, but did respond to TNF-alpha + IL-2. Finally, we detected TNF-alpha production by a cloned line of thymic macrophages, as well as by DN adult thymocytes. These results suggest that cytokines alone are capable of potent growth stimuli for thymocytes, and indicate that different combinations of these molecules act selectively on thymocytes at different developmental stages.     

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.     

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.     

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.