Development of a monoclonal antibody, anti-6C2, which is involved in the interaction of CD4 T helper cells and activated B cells.

We have developed a mAb anti-6C2, by immunizing mice with T cell line derived from the Callithrix jacchus (common marmoset). Anti-6C2 is reactive with approximately 50% of unfractionated T cells, 50% of CD4+ cells, and 40% of CD8+ cells. Regarding CD4+ cells, anti-6C2-reactive cells substantially overlap with the CD29+CD45RO+ Th cell population. Moreover, anti-6C2 can divide these T cells into 6C2+ and 6C2- subpopulations. The CD4+CD45RO+6C2+ cells maximally respond to soluble Ag such as tetanus toxoid and provide strong helper function for PWM-driven B cell IgG synthesis. Most interestingly, anti-6C2 was also reactive against activated B cells but not resting B cells; furthermore, this epitope was inducible through activation of resting B cells or B cell line. Biochemical characterization showed that anti-6C2 precipitated two glycoproteins with the relative molecular weights of 180,000 and 95,000 from 125I-surface labeled cell lysate. Sequential immunoprecipitation studies demonstrated that these two glycoproteins were the lymphocyte function-associated antigen (LFA-1) Ag complex (CD11a/18). Significantly, although this antibody did not inhibit cytotoxic killer T cell responses and Ag-induced T cell proliferation as did conventional anti-LFA-1, it did inhibit PWM-driven B cell IgG synthesis. Because 6C2 expression was induced after B cell activation, the above results strongly suggest that the 6C2 molecule may play a role in the interaction of CD4 helper cells and activated B lymphocytes.     

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.     

The functional heterogeneity of CD8+ cells defined by anti-CD45RA (2H4) and anti-CD29 (4B4) antibodies.

The monoclonal antibodies, anti-2H4(CD45RA), and anti-4B4(CD29), along with UCHL1-(CD45RO), identify reciprocal populations of CD4 cells with distinct suppressor inducer (CD45RA+CD29-CD45RO-) and helper inducer (CD45RA-CD29+CD45RO+) functions. Although the CD8+ population is known to contain precytotoxic, cytotoxic, suppressor, and some natural killer cells, the exact phenotypic identities of these functional CD8 subsets has not been established. In this study, we tried to determine whether these monoclonal antibodies could distinguish functionally distinct subsets of cells within the CD8+ population. For this purpose, whole T cells or fractionated T cells were sensitized with irradiated allogeneic non-T cells for 6 days, following which, CD8+ or CD8+CD11b- cells were isolated and cellular functions such as suppressor, killer precursor, and killer effector activity were assessed. The results showed that both class I-restricted alloantigen-specific killer effector and killer precursor cells belonged to the CD8+CD11b-CD45RA-CD29+ population. Moreover, these killer effector cells expressed the CTL-associated S6F1 molecule, an epitope of the LFA-1 antigen. In contrast, suppressor effector cells belonged to the CD8+CD11b-CD45RA+CD29- cell population. Although the UCHL1 antigen has been reported to define the CD4+CD29+ helper inducer cell, over 90% of allo-activated CD8+ cells expressed this antigen, whereas only 40-60% of these cells expressed either CD45RA or CD29 antigens. These results suggest that anti-CD45RA and anti-CD29 antibodies may provide useful tools for distinguishing between suppressor effector versus killer effector and killer precursor cells within the CD8+CD11b- population.     

CD4+CD45RA+ and CD4+CD45RA- T cell subsets in man maintain distinct function and CD45RA expression persists on a subpopulation of CD45RA+ cells after activation with Con A.

We have previously shown that Con A-induced suppressor T cells belong to the CD45RA+ subset. After unseparated T cells are activated with Con A, CD45RA expression increases to a maximum (Day 2), and then decreases significantly, but does not disappear entirely (Day 9), while CD29 expression increases steadily. In the present study, we examined the fate of these cell surface molecules on isolated CD4+CD45RA+ and CD4+CD45RA- cells following activation with Con A, and their relationship to the regulatory functions of these subsets. After activation of CD4+CD45RA+ cells with Con A, CD45RO and CD29 antigen expression rapidly increases (greater than 90%). While CD45RA expression is downregulated, approximately 40% of the cells continue to express low-density CD45RA in a stable fashion through Day 21. Despite these phenotypic changes, cells originally CD45RA+ continue to suppress IgG synthesis and provide only minimal B cell help. Furthermore, when cells originally CD45RA+ were sorted on the basis of continued presence, or loss of CD45RA antigen 14 days after activation, both populations demonstrated potent suppression and minimal help. In contrast, after activation with Con A, CD4+CD45A- cells maintain stable phenotype and provide significant help and minimal suppression. Immunoprecipitation of the CD45RA antigen from Day 14 activated CD4+CD45RA+ cells confirms the continued presence of the 205-kDa isoform, but reveals a significant decrease in the 220-kDa isoform. These results suggest that after activation with Con A, cells originally CD45RA+ remain functionally distinct from cells originally CD45RA-, and that CD45RA antigen persists on a subpopulation of CD45RA+ cells after activation with Con A.     

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.     

In vivo ultraviolet-exposed human epidermal cells activate T suppressor cell pathways that involve CD4+CD45RA+ suppressor-inducer T cells

In vivo UV exposure of human epidermis abrogates the function of CD1+DR+ Langerhans cells and induces the appearance of CD1-DR+ Ag-presenting macrophages. Epidermal cells from UV-exposed skin, in contrast to epidermal cells from normal skin, potently activate autologous CD4+ T cells, and, in particular, the CD45RA+ (2H4+) (suppressor-inducer) subset. We therefore determined whether UV-exposure in humans leads to a T cell response in which suppression dominates. Autologous blood T cells were incubated with epidermal cell suspensions from in vivo UV-irradiated skin. After activation, repurified T cells were transferred in graded numbers to autologous mononuclear cells (MNC) stimulated with PWM and the resultant IgG production analyzed by ELISA. Relative to T cells activated by unirradiated control epidermal cells, T cells activated by UV-exposed epidermal cells demonstrated enhanced capacity to suppress IgG production (n = 6; p less than or equal to 0.03). Within the T cell population, CD8+ cells stimulated by UV-exposed epidermal cells could be directly activated to suppress PWM-stimulated MNC Ig production if IL-2 was provided in the reaction mixture. The suppressive activity was also transferable with purified CD4+ T cells stimulated by UV-exposed epidermal cells (n = 10; p less than or equal to 0.01), and was radiosensitive. Suppression was decreased when PWM-stimulated MNC were depleted of CD8+ T cells before mixing with CD4+ T cells activated by UV-exposed epidermal cells, suggesting indirect induction of CD8+ Ts cells contained within the responding MNC populations. Indeed, physical depletion of CD45RA+ cells resulted in total abrogation of the suppressor function contained in the CD4+ T cells. Activation of suppressor function was critically dependent on DR+ APC contained in UV-exposed epidermis. The data suggest that UV-exposure modulates cutaneous APC activity in humans, as in mice, such that the dominant immune response is tilted toward suppression. These mechanisms in normal individuals may function to dampen responses to UV-induced endogenous Ag that are pathogenic in autoimmune disorders. However, these mechanisms might also facilitate the growth of UV-induced skin cancers.     

CD45 isoforms associated with distinct functions of CD4 cells derived from unusual healthy donors lacking CD45RA- T lymphocytes.

We now report two healthy individuals whose T lymphocytes were over 95% positive for CD45RA antigen expression. However, these donors normally expressed both the CD29 high (CD29+) and CD45RO high (CD45RO+) antigens on approximately 40 and 50% of their CD4 cells, respectively. Despite the strong CD45RA expression on the surface of almost all CD4 cells, the CD29 marker allowed T cells from these donors to be divided phenotypically into subsets having distinct in vitro function. CD4+CD29+ cells from these donors responded maximally to recall antigens such as TT and provided strong helper function for B cell Ig synthesis. In contrast, CD4+CD29- cells responded poorly to recall antigens and had poor helper function for B cell Ig synthesis, but had strong suppressor activity. Thus, CD29 antigen expression was still predictive of the in vitro functional activity as previously described for normal donors. Furthermore, biochemical analysis of the distribution of individual CD45 isoforms on the surface of these subsets of CD4 cells revealed distinct differences. The CD4+CD29 high (CD4+CD29+) subset of cells primarily expressed the 180-, 190-, and 205-kDa CD45 isoforms, while the CD4+CD29 low (CD4+CD29-) cells primarily expressed the 190-, 205-, and 220-kDa CD45 isoforms. These results suggest that despite the superficial phenotypic similarity of CD4 cells in these donors, distinctions in the distribution of both CD29 and the 180- and 220-kDa CD45 isoforms exist and might play a role in the different functions of freshly isolated CD4 lymphocytes.     

Activation and function of an autoreactive T cell clone with dual immunoregulatory activity

Previously it was demonstrated that the human autoreactive CD4+ T cell clone MTC-4 is bifunctional, having the capacity to augment differentiation of autologous B cells into Ig-secreting cells in the absence of PWM and the capacity to suppress such differentiation in the presence of PWM. In the present study it was shown that these two functions of MTC-4 are mediated by distinctly different mechanisms. In the presence of autologous class II MHC Ag, MTC-4 releases one or more non-MHC-restricted soluble factors which stimulate B cell differentiation. The helper factors are different from IL-2, and act on both resting (small) and activated (large) B cells. The suppressor function of MTC-4 cells is elicited when MTC-4 cells are co-cultured with autologous non-T cells preincubated with PWM for 4 h, but not with non-T cells preincubated with PWM for 24 h; thus, activated autologous non-T cells have a transient capacity to induce MTC-4 suppressor function. Induction of MTC-4 suppressor activity is not associated with increased proliferation of MTC-4 and is mediated by low numbers of these cells. Unlike helper function, MTC-4 suppression of Ig synthesis can occur late in B cell cultures, and MTC-4 suppresses Ig production by autologous B cells, but not by allogeneic B cells. Finally, in co-cultures with activated autologous non-T cells and allogeneic B cells, MTC-4 can simultaneously produce helper factors that augment Ig synthesis by allogeneic B cells and suppress Ig synthesis by autologous B cells. In summary, exposure of MTC-4 to autologous non-T cells causes release of non-MHC-restricted factors which augment Ig production by both resting and activated autologous B cells, whereas exposure of MTC-4 to recently activated B cells causes MTC-4 to express the additional function of directly suppressing Ig production by differentiated autologous B cells. Thus autoreactive T cells may be uniquely suited to regulate Ig production.     

1F7, a novel cell surface molecule, involved in helper function of CD4 cells

We have developed a monoclonal antibody, anti-1F7, that inhibits soluble Ag-driven T cell proliferation as well as PWM-driven IgG synthesis. Anti-1F7 antibody reacts with approximately 57% of unfractionated T cells, 62% of CD4+ cells, and 54% of CD8+ cells. Although the 1F7 Ag is widely distributed among lymphoid cells, this Ag on CD4+ cells is preferentially expressed on the CDw29(4B4+) helper population. Moreover, anti-1F7 antibody further subdivides the CD4+CDw29+ cell subset into CDw29+1F7+ and CDw29+1F7- populations. The CD4+CDw29+1F7+ population of cells maximally proliferates to recall Ag such as tetanus toxoid, whereas helper function for PWM-driven IgG synthesis by B cells belongs to both the CD4+CDw29+1F7+ and CD4+CDw29+1F7- population of cells. The most prominent structure defined by this antibody is a 110-kDa molecule that is different from the 135-kDa, 160-kDa, and 185-kDa glycoproteins identified by anti-CDw29 antibody and the 180-kDa glycoprotein identified by UCHL-1 antibody. It is, however, related to the molecule recognized by anti-Ta1, an activation Ag on T cells. Furthermore, although the Ta1 molecule is recognized by anti-1F7 mAb, the 1F7 family of structures also includes molecules distinct from Ta1.     

The isolation and characterization of the human helper inducer T cell subset

Monoclonal antibody anti-4B4 was produced by fusing NS1 myeloma with spleen cells of a mouse immunized with Saguinus oedipus lymphocyte. This anti-4B4 antibody defines a 135-KD cell surface protein that is widely distributed throughout the hematopoietic system. More importantly, anti-4B4 is reactive with functionally unique human T cell subsets. Anti-4B4 antibody was reactive with approximately 41% of unfractionated T cells, 41% of T4+ inducer cells, and approximately 43% of T8+ cytotoxic/suppressor population. This antibody subdivided peripheral blood T4+ cells into two functionally distinct populations. The T4+4B4+ subset proliferates relatively poorly upon stimulation with Con A and autologous cell antigens (AMLR) but well on exposure to soluble antigens, and it provides a good helper signal for PWM-induced Ig synthesis. The T4+4B4- subset, in contrast, proliferates well to Con A stimulation and autologous cell antigen (AMLR) but relatively poorly to soluble antigen stimulation, and provides little help to B cells for PWM-induced Ig synthesis. The T4+4B4- subset is largely 2H4+ and functions as the inducer of the T8+ suppressor cells. Thus, the present results suggest that one can divide the human T4 population into two major subsets that are phenotypically and functionally distinct, the human helper inducer subset (T4+4B4+/H.I.) and its reciprocal population defined by anti-2H4, the suppressor inducer subset (T4+2H4+/S.I.).     

A human CD4- T cell leukemia subclone with contact-dependent helper function.

Helper T lymphocytes provide a contact dependent signal to resting B cells that is required for optimal differentiation into Ig-secreting cells. The surface structure(s) on T cells that mediate helper function have not been identified but are known to be induced by T cell activation. A CD4- subclone of the Jurkat leukemic T cell line (D1.1) was isolated and found to be distinct from CD4+ Jurkat clones and a variety of other T and non-T cell leukemic lines in that coculture of D1.1 with resting B cells induced B cells to specifically express surface CD23 molecules, a marker of B cell activation. Furthermore, Jurkat D1.1 induced B cell proliferation and terminal B cell differentiation into IgG-secreting cells in the presence of T cell-dependent B cell mitogens. Similar to the helper effector function of activated T cells, the effects of Jurkat D1.1 were neither Ag nor MHC restricted. Paraformaldehyde fixed Jurkat D1.1 cells remained competent to activate B cells while D1.1 supernatants and diffusible factors were inactive. The effect of Jurkat D1.1 on B cell activation was distinct from that of rIL-4 and was not inhibited by antibodies to IL-4. Together these observations suggested that surface structures on D1.1 and not secreted factors, mediated contact-dependent helper effector function.     

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.     

A defect in the suppressor circuits among OKT4+ cell populations in patients with systemic lupus erythematosus occurs independently of a defect in the OKT8+ suppressor T cell function

The autologous mixed lymphocyte reaction (MLR) is thought to be part of a regulatory role of T cells on B cell function. OKT4+, but not OKT8+, cells can proliferate in response to autologous non-T cells. Moreover, the OKT4+ cell population activated early in the course of autologous MLR functioned as inducer cells for the differentiation of B cells, whereas later in the response, the activated OKT4+ cells were particularly enriched in suppressor cells. A part of the autologous MLR appears to be an important pathway for the activation of feedback suppression mechanisms among cells contained within the OKT4+ populations. Patients with systemic lupus erythematosus (SLE) were studied with regard to the following OKT4+ cell functions in vitro after activation in the autologous MLR: a) proliferative response, and b) helper and suppressor activities for differentiation of B cells. A marked reduction in the proliferative response of OKT4+ cells was observed in SLE patients. SLE OKT4+ cells activated in the autologous MLR could function as helper cells but could not exert any suppressor activity. This OKT4+ cell abnormality was present regardless of the disease activity, and occurred in the absence of autoantibodies including anti-T cell antibodies. Instead, SLE anti-T cell antibodies could preferentially eliminate cells bearing the OKT8+ phenotype characteristic of suppressor cells in populations of normal T cells. These results suggest that the defect in the suppressor circuits among OKT4+ cell populations is intrinsic to SLE lymphocytes and that the OKT8+ suppressor T cell defect is caused by antibodies produced by the B cells of SLE patients.     

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.     

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.     

Activation of T cells through a T cell-specific epitope of CD45.

The 180- and 190-kDa isoforms of CD45 are preferentially expressed on the helper inducer (memory) subset of CD4 cells. In order to generate monoclonal antibodies against the extracellular domains of these isoforms and determine whether they could regulate the function and activation of these cells, we developed a mAb, anti-4H2D, by immunizing Balb/c mice with an isogenic mouse pre-B cell line expressing the human 190-kDa CD45 isoform. Anti-4H2D reacts with approximately 60% of T cells, 70% of CD4 cells, and 60% of CD8 cells. The CD4 cell population defined by this mAb corresponds functionally and phenotypically to that defined by the CD45RO+CD29+ subset. Western blotting demonstrated that anti-4H2D reacts primarily with the 190-kDa isoform of CD45 and to a minor extent, the 205- and 180-kDa CD45 isoforms. Interestingly, this mAb reacted with only a subpopulation of mature thymocytes and peripheral T cells, despite the fact that the 190-kDa CD45 isoform, as well as CD45RO and CD29, is more widely distributed on cells of hematopoietic origin. The 4H2D epitope was neuraminidase sensitive, indicating that anti-4H2D reacts with a carbohydrate epitope which is present on only a subset of the T cells containing the 190-kDa CD45 isoform epitopes. Functional studies showed that soluble anti-4H2D augmented T cell proliferation induced by the CD2 and CD3 pathways, and treatment of T cells with this mAb up-regulated [Ca2+]i flux induced by both anti-CD2 and anti-CD3 mAbs. These results suggest that the 190-kDa CD45 isoform on human CD4 cells is heterogeneous and that the 190-kDa isoform recognized by anti-4H2D regulates the function and activation of CD4 helper T cells.     

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.     

Development of an antigen-specific CD8 suppressor effector clone in man

A long-term cultured IL-2-dependent keyhole limpet hemocyanin (KLH)-specific CD8 (T8) suppressor clone (5B9) was generated from a healthy donor hyperimmunized with KLH. The 5B9 clonal population suppressed in vitro anti-KLH antibody response but did not suppress anti-TT antibody response or PWM-driven IgG synthesis. Moreover, 5B9 cells could not suppress anti-TT antibody response even in the presence of free KLH. 5B9 cloned cells suppressed the anti-KLH antibody response of B cells cultured with CD4+4B4+ cells without requiring the presence of CD8+ cells. This KLH-specific CD8 suppressor clone is an effector type rather than an inducer type of suppressor T cell. The cloned cells expressed alpha- and beta-TCR proteins (defined by WT-31 antibody) on their cell surface. More importantly, the CD3:TCR complex was functionally important in the suppression induced by this clone, because after CD3 antigen modulation from its cell surface, the suppressor effector function was abolished.     

CTLA-4 and CD28 mRNA are coexpressed in most T cells after activation. Expression of CTLA-4 and CD28 mRNA does not correlate with the pattern of lymphokine production.

Ag-presenting cells provide at least two distinct signals for T cell activation. T cell receptor-dependent stimulation is provided by presentation of a specific peptide Ag in association with MHC molecules. In addition, APC also supply costimulatory signals required for T cell activation that are neither Ag- nor MHC restricted. One such costimulatory signal is mediated via the interaction of B7 on APC with the CD28 receptor on T cells. Recently, CTLA-4 has been shown to be a second B7 receptor on T cells. In the present report, we have examined the expression of CD28 and CTLA-4 on a panel of resting and activated normal T cell subsets and T cell clones by RNA blot analysis in an attempt to determine whether their expression defines reciprocal or overlapping subsets. CD28 was detected in resting T cells, whereas CTLA-4 was not. After stimulation with PHA and PMA for 24 h, CTLA-4 mRNA was expressed in both the CD4+ and CD8+ subsets as well as in CD28+ T cells. We examined 37 human and six murine T cell clones that had been previously characterized for their cytokine production. After activation, CTLA-4 and CD28 mRNA were coexpressed in 36 of 37 human T cell clones and all six murine T cell clones. These included T cells of CD4+8-, CD4-8+, and CD4-8- phenotypes as well as clones with Th1 and Th2 cytokine profiles. In contrast, CD28 but not CTLA-4 mRNA was detected in leukemic T cell lines and myelomas. CTLA-4 and B7 mRNA but not CD28 mRNA was detected in two long term HTLV-I-transformed T cell lines. These data demonstrate that CD28 and CTLA-4 mRNA are coexpressed in most activated T cells and T cell clones, providing evidence that they do not define reciprocal subsets. Moreover, they are consistent with the hypothesis that B7 transmits its signal through a single receptor, CD28, on resting T cells, and multiple receptors, CD28 and CTLA-4, on activated T cells.     

IL-2 and a contact-mediated signal provided by TCR alpha beta + or TCR gamma delta + CD4+ T cells induce polyclonal Ig production by committed human B cells. Enhancement by IL-5, specific inhibition of IgA synthesis by IL-4.

To study the role of T cells in T-B cell interactions resulting in isotype production, autologous purified human splenic B and T cells were cocultured in the presence of IL-2 and Con A. Under these conditions high amounts of IgM, IgG, and IgA were secreted. B cell help was provided by autologous CD4+ T cells whereas autologous CD8+ T cells were ineffective. Moreover, CD8+ T cells suppressed Ig production when added to B cells cocultured with CD4+ T cells. Autologous CD4+ T cells could be replaced by allogeneic activated TCR gamma delta,CD4+ or TCR alpha beta,CD4+ T cell clones with nonrelevant specificities, indicating that the TCR is not involved in these T-B cell interactions. In contrast, resting CD4+ T cell clones, activated CD8+, or TCR gamma delta,CD4-,CD8- T cell clones failed to induce IL-2-dependent Ig synthesis. CD4+ T-B cell interaction required cell-cell contact. Separation of the CD4+ T and B cells by semiporous membranes or replacement of the CD4+ T cells by their culture supernatants did not result in Ig synthesis. However, intact activated TCR alpha beta or TCR gamma delta,CD4+ T cell clones could be replaced by plasma membrane preparations of these cells. Ig synthesis was blocked by mAb against class II MHC and CD4. These data indicate that in addition to CD4 and class II MHC Ag a membrane-associated determinant expressed on both TCR alpha beta or TCR gamma delta,CD4+ T cells after activation is required for productive T-B cell interactions resulting in Ig synthesis. Ig production was also blocked by mAb against IL-2 and the IL-2R molecules Tac and p75 but not by anti-IL-4 or anti-IL-5 mAb. The CD4+ T cell clones and IL-2 stimulated surface IgM-IgG+ and IgM-IgA+, but not IgM+IgG- or IgM+IgA- B cells to secrete IgG and IgA, respectively, indicating that they induced a selective expansion of IgG- and IgA-committed B cells rather than isotype switching in Ig noncommitted B cells. Induction of Ig production by CD4+ T cell clones and IL-2 was modulated by other cytokines. IL-5 and transforming growth factor-beta enhanced, or blocked, respectively, the production of all isotypes in a dose-dependent fashion. Interestingly, IL-4 specifically blocked IgA production in this culture system, indicating that IL-4 inhibits only antibody production by IgA-committed B cells.