Antibodies to the L3T4 and Lyt-2 molecules interfere with antigen receptor-driven activation of cloned murine T cells

When L3T4+ cloned murine helper T lymphocytes (HTL) are stimulated with antigen or immobilized anti-T cell receptor (TCR) monoclonal antibodies (mAb) at concentrations which are optimal for proliferation, anti-L3T4 mAb inhibits activation as measured by proliferation and lymphokine production. Under similar conditions, IL 2-independent proliferation of Lyt-2+ cloned murine cytolytic T lymphocytes (CTL) stimulated by anti-TCR mAb is inhibited by anti-Lyt-2 antibodies. Proliferation of cloned HTL and CTL cells stimulated by IL 2 is not affected by the anti-L3T4 and anti-Lyt-2 mAb. The inhibition of TCR-induced activation of the T cell clones is not due to interference with the binding of the anti-TCR mAb. Stimulation of the TCR has been proposed to induce lymphokine secretion and proliferation by T cells through a pathway involving the activation of protein kinase C and the stimulation of an increase in the concentration of intracellular free calcium. However, proliferation of T cells stimulated by PMA (which activates protein kinase C) plus the calcium ionophore A23187 (which increases the concentration of intracellular free calcium) is not affected by mAb reactive with the Lyt-2 or L3T4 structures. If TCR stimulation does indeed activate T cells by activating protein kinase and increasing intracellular free calcium, then our data suggest that anti-L3T4 and anti-Lyt-2 mAb inhibit TCR-driven proliferation at some step before the activation of protein kinase C and the stimulation of a rise in intracellular free calcium concentration. Our results suggest that anti-L3T4 and anti-Lyt-2 mAb interfere with early biochemical processes induced by stimulation of the TCR. In HTL, which proliferate via an autocrine pathway, anti-L3T4 mAb appears to inhibit proliferation by interfering with signaling events involved in lymphokine production. Inhibition of IL 2-independent proliferation of Lyt-2+ cells by anti-Lyt-2 mAb appears to occur by a different mechanism. The precise molecular basis for the interference of each cell type has not yet been characterized.     

Regulation of murine T cell proliferation by B cell stimulatory factor-1

The proliferation of mitogen-activated primary T cells, antigen-activated memory T cells from mixed leukocyte culture, and antigen-dependent alloreactive T cell clones in response to purified murine recombinant B cell stimulatory factor-1 (also known as interleukin 4) was examined. We found that B cell stimulatory factor-1 (BSF-1) stimulated optimal proliferation of these T cells only after their recent activation by antigen or mitogen. Analysis of cell surface BSF-1 receptor expression indicated that although T cell activation is accompanied by a small increase in BSF-1 receptor expression, the cells also express BSF-1 receptors prior to activation at a time when they do not proliferate in response to BSF-1. BSF-1 was as effective a stimulus as interleukin 2 for inducing proliferation of the Lyt-2+ subpopulation of concanavalin A-activated murine spleen cells and an alloreactive cytolytic T cell clone. However, the L3T4+ subpopulation of concanavalin A-activated spleen and an alloreactive helper T cell clone were less responsive to BSF-1 than to interleukin 2. Taken together, the data indicate an important role for BSF-1 in the regulation of normal T cell proliferation.     

B cell stimulatory factor-2 is involved in the differentiation of cytotoxic T lymphocytes

The induction of cytotoxic T lymphocytes (CTL) from precursor T cells requires both antigen and lymphokine signals. Previous work from our laboratory has indicated that three lymphokines are required for the induction of CTL from murine thymocytes; interleukin 2, interferon-gamma (IFN-gamma), and a partially characterized factor referred to as cytotoxic differentiation factor (CDF). While attempting to clone CDF from the human T cell line C10-MJ2, we found that a gene encoding CDF-like activity is identical to the gene encoding the factor known variously as B cell stimulatory factor-2 (BSF-2), IFN-beta 2, and 26-kDa protein. We report here that BSF-2 can induce the differentiation of Ly-2+ CTL from murine thymocytes in the presence of interleukin 2 and that the level of cytotoxicity is augmented by the addition of murine IFN-gamma. Serine esterase, a marker for cytotoxic granules in CTL, was induced only in the presence of BSF-2, and the level of serine esterase activity correlated with the level of serine esterase activity correlated with the level of cytotoxicity. These data suggest that BSF-2 is a differentiation factor for CTL and that it functions in part by inducing proteins required for mediating target cell lysis.     

Effects of anti-Lyt-2 and anti-L3T4 monoclonal antibodies on the function of cytotoxic T lymphocyte/helper T lymphocyte hybrid T cell clones

CTL/HTL hybrid clones provide a unique system that allows detailed analysis of the role of Lyt-2, L3T4, and other structures involved in T cell functions. We have demonstrated previously that the fusion of cloned murine CTL and helper T lymphocytes with defined specificity generated hybrid cells that expressed both Lyt-2 and L3T4 as well as two TCR. Data obtained with these hybrid clones demonstrated that cytolysis is closely linked to the CTL TCR. We have analyzed the effects of anti-Lyt-2 and anti-L3T4 as well as anti-TCR mAb on cytolysis, proliferation, and lymphokine release by a number of hybrid clones. We found that anti-Lyt-2 and anti-L3T4 mAb were able to inhibit both proliferation and lymphokine release by the hybrid clones in response to stimulation of either the CTL or helper T lymphocyte parent TCR. In contrast, only anti-Lyt-2 and anti-CTL TCR mAb were able to block cytolysis of target cells bearing the Ag recognized by the CTL TCR. These results provide further evidence that cytolysis is closely linked to the CTL TCR and that Lyt-2 and L3T4 have more than a passive role as accessory molecules on the surface of T lymphocytes.     

Requirements for triggering of lysis by cytolytic T lymphocyte clones

Cloned murine cytolytic T lymphocytes (CTL) having defined specificity were triggered by the phorbol ester together with a calcium ionophore (either A23187 or Ionomycin) to lyse syngeneic or third party target cells efficiently. Neither phorbol 12-myristate 13-acetate (PMA) nor calcium ionophore alone induced efficient lysis. The characteristics of the lytic process induced by these signals are similar to those of antigen-specific or lectin-facilitated lysis by CTL. Lysis is calcium and temperature dependent and shows kinetics which are not grossly different from lysis mediated via the antigen receptor. Two helper T lymphocyte clones were not induced to lyse efficiently EL-4 target cells by concanavalin A or PMA + ionophore. Triggering of lysis induced with PMA plus ionophore by the CTL clone L3 differed from antigen-mediated lysis in specificity and in the susceptibility to inhibition by cytochalasin B. Properties of the target cell determine which cell surface associative recognition structures are important in the efficient lysis of these cells. Anti-LFA-1 monoclonal antibodies inhibited efficiently both antigen-mediated and PMA + ionophore-induced lysis of P-815 or EL-4 target cells which are of hematopoietic origin. However, anti-LFA-1 antibodies do not inhibit antigen-mediated, lectin-facilitated, or PMA + Ionomycin-induced CTL cytolysis of target cells derived from the L cell fibroblast line. We conclude that two intracellular signals, which can be provided by the combination of PMA + ionophore, are required for efficient lysis by antigen-specific murine CTL clones. When the T cell receptor for antigen is bypassed using PMA + ionophore to trigger lysis, we show that Lyt-2 and LFA-1 molecules may be required for efficient lysis. These associative recognition structures appear to play an important role in postactivation steps leading to efficient delivery of the lethal hit to the target cell.     

Il-4 is an endogenous T cell growth factor during the immune response to a syngeneic retrovirus-induced tumor

The relative contributions of IL-2 and IL-4 during the immune response to the retrovirus-induced tumor, FBL, were examined. Both proliferative and cytolytic responses to FBL were measured and compared to similar responses to minor histocompatibility Ag. The addition of alpha IL-2 partially inhibited FBL-stimulated proliferation of purified L3T4+ T cells and nearly completely inhibited the response of Lyt-2+ T cells, whereas alpha IL-4 partially inhibited the proliferative response of the L3T4+ subset but had no effect on the response of the Lyt-2+ subset. The addition of exogenous IL-4 augmented the proliferative response of both subsets. Therefore, IL-4 is an endogenous growth factor for FBL-induced specific proliferation of the L3T4+ and not the Lyt-2+ population, but both subpopulations can respond to IL-4. Similar examination of anti-FBL CTL responses revealed that alpha IL-2, but not alpha IL-4, inhibited FBL-specific Lyt-2+ CTL generation. However, exogenous IL-4 partially replaced the L3T4+ Th cell activity necessary for optimal Lyt-2+ FBL-specific CTL generation. Therefore, IL-4 is not required but can participate in the CTL response. The role of IL-4 during the immune response of B6 mice to minor histocompatibility Ag disparate BALB.B cells was analyzed. alpha IL-4 had no detectable effect on the proliferative or cytolytic response to BALB.B cells, suggesting that endogenous IL-4 does not have a significant role in these responses. The extent of involvement of endogenous IL-4 in the T cell responses to retrovirus-induced tumor Ag and minor histocompatibility Ag presumably reflects the nature of the stimulating Ag, and detection of an IL-4 response may correlate with induction of an antibody response. Thus, the immunizing Ag and/or host B cell repetoire may influence which subsets of L3T4+ Th cells are activated during priming in vivo.     

Characterization of the murine T cell surface molecule, designated L3T4, identified by monoclonal antibody GK1.5: similarity of L3T4 to the human Leu-3/T4 molecule

Monoclonal antibody GK1.5 recognizes a previously undescribed murine T cell surface molecule, designated L3T4, which migrates on SDS-PAGE under reducing conditions as a single band with an apparent m.w. of 52,000. L3T4 is expressed by approximately 80% of thymocytes and by approximately 20% of spleen cells. There appears to be poor correlation between expression of L3T4 by functional T cell clones and expression of Lyt-2, expression of the cytolytic phenotype, and class I MHC antigen reactivity. On the other hand, both a class II MHC antigen-reactive HTL clone and an Lyt-1- Mls-reactive HTL clone express L3T4. Analysis of the effect of mAb GK1.5 on PFC responses in adoptive transfer suggests that L3T4 is expressed by the helper/inducer subset of murine T cells. Expression of L3T4 by murine T cells, however, may correlate primarily with class II MHC antigen reactivity rather than with functional phenotype; mAb GK1.5 profoundly blocks antigen-specific cytolysis by the cloned class II MHC antigen-reactive CTL line A15-1.17. Antigen-specific cytolysis by A15-1.17 is blocked by mAb GK1.5 at a step before the lethal hit. Collectively, the flow cytometric, functional, and biochemical data indicate that L3T4 is similar to the human Leu-3/T4 molecule.     

A rat anti-mouse T4 monoclonal antibody (H129.19) inhibits the proliferation of Ia-reactive T cell clones and delineates two phenotypically distinct (T4+, Lyt-2,3-, and T4-, Lyt-2,3+) subsets among anti-Ia cytolytic T cell clones

Hybridoma H129 .19 was derived by fusion between spleen cells of a Lou / Ws1 rat immunized with an Lyt-1+,2- anti-I-Ak cytolytic T lymphocyte (CTL) clone and the nonsecreting myeloma X63-Ag8.653. The monoclonal antibody (mAb) H129 .19 (IgG2a, kappa) was selected for its capacity to inhibit the lytic potential of the immunizing clone. H129 .19 identified a monomorphic determinant on a 55 m.w. murine T cell differentiation antigen, which appeared to be homologous to the human T4 molecule in that: 1) H129 .19 reacted with 80% adult thymocytes, with a subset of splenic T cells, and with the interleukin 2 (IL 2)-producing EL4 thymoma; 2) The mAb bound to and inhibited the IL 2 production and the proliferation of various allo- or soluble antigen-reactive T cell clones that recognized restriction or activating determinants on the I-A or I-E molecules, respectively; 3) H129 .19 did not inhibit the proliferation and/or cytolysis of Lyt-2,3+ T cells specific for class I MHC antigen; and 4) Among six anti-Iak CTL clones examined in this study, the mAb H129 .19 reacted with two I-Ak-specific, Lyt-2,3- clones on which it exerted strong cytolysis inhibiting effect at the effector cell level. By contrast, two other anti-I-Ak and two anti-I-Ek CTL clones were found to express the Lyt-2,3+,T4- cell surface phenotype. The cytolytic potential of the latter clones was not inhibited by anti-Lyt-2,3 mAb. These studies strongly suggest that the mouse T4 molecule facilitates the recognition of class II MHC antigen by most but not all T cells.     

T helper cells in cytotoxic T lymphocyte development: role of L3T4(+)-dependent and -independent T helper cell pathways in virus-specific and alloreactive cytotoxic T lymphocyte responses

I have compared the requirements for T helper (Th) cell function during the generation of virus-specific and alloreactive cytotoxic thymus (T)-derived lymphocyte (CTL) responses. Restimulation of vesicular stomatitis virus (VSV)-immune T cells (VSV memory CTLs) with VSV-infected stimulators resulted in the generation of class I-restricted, VSV-specific CTLs. Progression of VSV memory CTLs (Lyt-1-2+) into VSV-specific CTLs required inductive signals derived from VSV-induced, Lyt-1+2- Th cells because: (i) cultures depleted by negative selection of Lyt-1+ T cells failed to generate CTLs; (ii) titration of VSV memory CTLs into a limiting dilution (LD) microculture system depleted of Th cells generated curves which were not consistent with a single limiting cell type; (iii) LD analysis of VSV memory CTLs did produce single-hit curves in the presence of Lyt-1+2- T cells sensitized against VSV; and (iv) monoclonal anti-L3T4 antibody completely abrogated CTL generation against VSV. Similar results were also obtained with Sendai virus (SV), a member of the paramyxovirus family. The notion that a class II-restricted, L3T4+ Th cell plays an obligatory role in the generation of CTLs against these viruses is also supported by the observation that purified T cell lymphoblasts (class II antigen negative) failed to function as antigen-presenting cells for CTL responses against VSV and SV. T cell lymphoblasts were efficiently lysed by class I-restricted, anti-VSV and -SV CTLs, indicating that activated T cells expressed the appropriate viral peptides for CTL recognition. Furthermore, heterogeneity in the VSV-induced Th cell population was detected by LD analysis, suggesting that at least two types of Th cells were required for the generation of an anti-VSV CTL response. VSV-induced Th cell function could not simply be replaced by exogenous IL-2 because this lymphokine induced cytotoxic cells that had the characteristics of lymphokine-activated killer (LAK) cells and not anti-viral CTLs. In contrast, CTL responses against allogeneic determinants could not be completely blocked with antibodies against L3T4 and depletion of L3T4+ cells did not prevent the generation of alloreactive CTLs in cultures stimulated with allogeneic spleen cells or activated T cell lymphoblasts. Thus, these studies demonstrate an obligatory requirement for an L3T4-dependent Th cell pathway for CTL responses against viruses such as VSV and SV; whereas, CTL responses against allogeneic determinants can utilize an L3T4-independent pathway.     

Virus-specific memory T cells are Pgp-1+ and can be selectively activated with phorbol ester and calcium ionophore

Memory lymphocytic choriomeningitis virus (LCMV)-immune cytotoxic T-lymphocyte precursors (CTLp) can be stimulated to proliferate and to mediate specific cytotoxic activity following incubation with phorbol myristate acetate (PMA), calcium ionophore (CaI), and interleukin 2 (IL-2). This protocol can be used to selectively induced virus-specific CTL activity under both bulk culture and limiting dilution conditions, in the absence of added antigen. There is no concurrent stimulation of alloreactive CTLp. Proliferation of the effector Lyt-2+ population in medium containing PMA and CaI requires L3T4+ cells, which can be replaced by adding IL-2, and the development of cytotoxicity is totally IL-2 dependent. The LCMV-specific memory T cells are also characterized by the expression of the Pgp-1 (Ly24) glycoprotein. The availability of this marker, together with the capacity to selectively stimulate primed CTLp in the absence of antigen, should greatly facilitate the analysis of T-cell memory in virus infections.     

Relationship among function, phenotype, and specificity in primary allospecific T cell populations: identification of phenotypically identical but functionally distinct primary T cell subsets that differ in their recognition of MHC class I and class II allodeterminants

The goal of the present study was to evaluate the relationship among function, Lyt phenotype, and MHC recognition specificity in primary allospecific T cell populations. By using Lyt-2+ and L3T4+ T cells obtained from the same responder populations, we assessed the ability of T cells of each phenotype to generate cytotoxic effector cells (CTL) and IL 2-secreting helper T cells in response to either class I or class II MHC allodeterminants. It was found that a discordance between Lyt phenotype and MHC recognition specificity does exist in primary allospecific T cells, but only in one T cell subpopulation with limited functional potential: namely, Lyt-2+ T cells with cytotoxic, but not helper, function that recognize class II MHC alloantigens. Target cell lysis by these Lyt-2+ class II-allospecific CTL was inhibited by anti-Ia monoclonal antibodies (mAb), but not anti-Lyt-2 mAb, indicating that they recognized class II MHC determinants as their "restriction" specificity and not as their "nominal" specificity even though they were Lyt-2+. A second allospecific T cell subset with limited functional potential was also identified but whose Lyt phenotype and MHC restriction specificity were not discordant: namely, an L3T4+ T cell subset with helper, but not cytotoxic, function specific for class I MHC allodeterminants presented in the context of self-Ia. Thus, the present study demonstrates that primary allospecific T cell populations contain phenotypically identical subpopulations of helper and effector cells that express fundamentally different MHC recognition specificities. Because the recognition specificities expressed by mature T cells reflect the selection pressures they encountered during their differentiation into functional competence, these findings suggest that functionally distinct but phenotypically identical T cell subsets may be selected independently of one another during ontogeny. Thus, the existence of Lyt-2+ CTL specific for class II allodeterminants can be explained by the hypothesis that the association of Lyt phenotype with MHC recognition specificity results from the process of thymic selection that these Lyt-2+ effector cells avoid.     

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.     

L3T4+ T cells regulate Abelson virus-induced lymphomagenesis

To evaluate the role of T cells in regulation of lymphomagenesis, experiments were performed using Abelson murine leukemia virus (AMuLV). In vitro transformation of bone marrow target cells by this B lymphotropic retrovirus was inhibited by peripheral lymph node cells from naive mice. The inhibitory activity depended on Thy-1+ L3T4+ cells but did not require Lyt-2+ cells. In vivo depletion of L3T4+ T cells with a mAb (GK1.5) altered the course of AMuLV-induced lymphoma. L3T4 depletion of naturally resistant C57BL/6 mice resulted in dramatic susceptibility to lymphoma induction. Lymphoma cells from anti-L3T4-treated C57BL/6 mice infected with AMuLV displayed the B lineage transformation marker P1606C3. These studies reveal an important immunologic component of Abelson disease resistance involving L3T4+ T cells.     

Developmental sequence of T200 antigen modifications in murine T cells

The T200 glycoproteins of T cells were analyzed at different stages of T cell development. Immunoprecipitation and analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that Lyt-2-L3T4-, and Lyt-2+L3T4+ thymocytes had similar T200 proteins, whereas Lyt-2+L3T4- and Lyt-2-L3T4+ thymocytes expressed a distinct set of T200 molecules. This result indicated a molecular switch in regulation of T200 protein expression upon differentiation of thymocytes to mature phenotype T cells. Further modifications were evident when the T200 proteins of peripheral T cell subsets were examined. In particular L3T4+ T cells expressed T200 proteins of m.w. 220,000, 200,000, and 175,000, whereas Lyt-2+ lymph node T cells expressed an additional T200 protein of m.w. 235,000. Antigenic differences in the T200 glyco-proteins of peripheral L3T4+ and Lyt-2+ T cells were also detected. The anti-B220 monoclonal antibody, 14.8, reacted with lymph node Lyt-2+ T cells but did not react with lymph node L3T4+T cells or with Lyt-2+L3T4- thymocytes. This finding demonstrated a lineage-specific modification of the T200 protein of Lyt-2+ T cells that occurred after exit of these cells from the thymus into peripheral lymphoid organs. This modification apparently occurred on the m.w. 235,000 and 220,000 proteins since these species were precipitated by 14.8, whereas the others were not. In vitro growth and activation also resulted in further T200 antigen alterations. The monoclonal antibody, RA3, which reacts with the B220 antigen of B cells but, unlike 14.8, does not react with any peripheral T cells, showed significant reactivity with Lyt-2+ cytotoxic T cell (CTL) clones but not with L3T4+ T helper cell clones. CTL clones were also 14.8+ but T helper cell clones were not. Immunoprecipitation by 14.8 and RA3 of T200 proteins from CTL clones yielded a single protein of m.w. 240,000 that co-migrated with the B cell form of T200. Overall, the results indicate the presence of developmentally regulated mechanisms that control T200 glycoprotein expression during T cell differentiation in the thymus and in peripheral lymphoid organs.     

Activation of murine T lymphocytes with monoclonal antibodies: detection on Lyt-2+ cells of an antigen not associated with the T cell receptor complex but involved in T cell activation

A new T cell molecule defined by the mAb 143-4-2 has been identified that is involved in T cell activation. The expression of the 143-4-2-defined epitope is linked to the previously characterized Ly-6 locus and restricted to bone marrow cells and to a subset of peripheral Lyt-2+ cells. In comparison to other anti-Ly-6.2 mAb, the 143-4-2 mAb appears to be directed at an allogeneic determinant of the Ly-6.2C molecule. The anti-Ly-6.2C antibody can promote the lysis of antigen-non-bearing target cells by alloreactive CTL clones, and in the presence of cofactors (PMA or IL 2) induces a subset of Lyt-2+ cells to proliferate, perhaps through an autocrine pathway. Although the antibody described has antigen-like effects as described for anti-TcR complex reagents, studies performed with a recently derived anti-murine T3 mAb suggest that the Ly-6.2C molecule is not associated on the cell surface with components of the TcR complex. Nevertheless, cell surface expression of the TcR complex is required for optimal triggering of T cells via the Ly-6.2C molecule. Because Ly-6.2C determinants are expressed in bone marrow and not in the thymus, the possibility is considered that expression of this molecule identifies a distinct subset of extrathymically derived T cells.     

Depletion of L3T4+ and Lyt-2+ cells by rat monoclonal antibodies alters the development of adoptively transferred experimental autoimmune thyroiditis

To delineate the contribution of L3T4+ and Lyt-2+ cells in the pathogenesis of experimental autoimmune thyroiditis (EAT), synergistic pairs of monoclonal antibodies (mAb) to the T cell subsets were used in conjunction with the adoptive transfer of mouse thyroglobulin (MTg)-activated cells from immunized mice. Initial experiments verified the important role of L3T4+ cells in the transfer of EAT. Subsequent experiments pointed to the relative contribution of both L3T4+ and Lyt-2+ cells, depending on the stage and extent of disease development. Treatment during disease with L3T4, but not Lyt-2, mAb alone significantly reduced thyroiditis. However, in situ analysis of the cellular infiltrate in thyroid sections revealed that, after treatment with mAb, the appropriate subset was eliminated without altering the amount of the other subset in the remaining lesion. In addition, treatment during severe thyroiditis following the transfer of MTg-activated lymph node cells showed that Lyt-2 mAb alone also reduced thyroid infiltration. When the recipients were pretreated with either pair of mAb before transfer, disease development was only moderately affected. We conclude that (i) donor L3T4+ cells are the primary cells responsible for the initial transfer and development of thyroiditis; and (ii) previous in vitro cytotoxicity data, plus current monoclonal antibody treatment of disease and in situ analysis, further implicate a role for Lyt-2+ cells in EAT pathogenesis.     

Cellular basis of immunologic interactions in adoptive T cell therapy of established metastases from a syngeneic murine sarcoma

The adoptive transfer of specifically sensitized T lymphocytes can effectively mediate the regression of established local and metastatic tumors. Previous experiments using the weakly immunogenic MCA 105 sarcoma indicated that cellular interactions between transferred L3T4+ helper and Lyt-2+ cytotoxic immune T cells were necessary for mediating tumor regression. In this study, the kinetics of T-T cell interactions were analyzed by in vivo depletion of T cell subsets with mAb. The anti-tumor efficacy of transferred immune cells was abrogated by in vivo administration of either L3T4 or Lyt-2 mAb on the day of cellular therapy. However, if mAb were given 3 days after the transfer of immune cells, depletion of Lyt-2+ but not L3T4+ cells abrogated anti-tumor efficacy. T cell depletion on day 6 after transfer of immune cells had no adverse effect on tumor regression, indicating the period required for T cell reactivity in vivo. Furthermore, depletion of Ia+ cells by in vivo mAb treatment abrogated the anti-tumor efficacy of immune cells. It is thus hypothesized that there are two distinct but sequential phases of in vivo T cell interactions leading to the regression of established tumors after adoptive immunotherapy. An initial "helper/inducer" phase apparently requires the interaction of L3T4+ immune cells and the tumor Ag involving Ia+ cells. The inducement of L3T4+ cell activation is to provide helper function via the secretion of IL-2. The second phase designated as an "effector phase" involves differentiation of immune Lyt-2+ cells under the influence of IL-2 secreted during the helper/inducer phase for generation of mature Lyt-2+ effector cells. To further support the hypothesis of a two-phase process we have examined the phenotype and kinetics of tumor regression mediated by effector cells generated by secondary in vitro sensitization (IVS). Although the IVS cells were generated from fresh MCA 105 immune spleen cells, their anti-tumor efficacy was mediated solely by Lyt-2+ lymphocytes. Kinetic studies revealed that the in vivo requirement of IVS Lyt-2+ effector cells to mediate tumor regression was less than 3 days, and the anti-tumor reactivity of these cells was not affected by in vivo depletion of Ia+ cells. Thus, the IVS reaction is likely representative of the in vivo counterpart of the helper/inducer phase leading to the generation of mature Lyt-2+ immune effector cells. Tumor regression after transfer of Lyt-2+ cells generated in IVS therefore required a relatively shorter period of time than that required after the transfer of fresh noncultured MCA 105 immune spleen cells.     

T cell subsets and IFN-gamma production in resistance to systemic candidosis in immunized mice

In addition to previous evidence for the roles of T cell-dependent immunity and delayed-type hypersensitivity in acquired resistance to systemic candidosis in mice, in the present study we have investigated the relative contributions of L3T4+ and Lyt-2+ lymphocytes in the protective immunity induced by vaccination with low virulence Candida albicans cells. We have also addressed the issue of the mode of Candida Ag recognition by specific T cells leading to cytokine release. Spleen cells from immunized mice produced high levels of IFN-gamma in vitro in response to Candida Ag, and this activity was abolished only by the combined treatment of the responder population with anti-L3T4 and anti-Lyt-2.2 mAb plus C. Positively selected L3T4+ and Lyt-2+ cells also produced IFN-gamma in vitro, provided accessory cells (plastic-adherent and Thy-1- Ia- splenocytes, respectively) were added to the lymphocyte-yeast cell cocultures. The production of IFN-gamma by purified L3T4+ and Lyt-2+ cells was inhibited by addition of the respective anti-class II and anti-class I H-2 antibody to the cultures. In vivo, administration of anti-L3T4, anti-Lyt-2.2 mAb or a combination of both significantly impaired the resistance of immunized mice to challenge with virulent C. albicans, as manifested by increased recovery of the yeast from the mouse kidneys. A similar effect was observed upon neutralization of endogenous IFN-gamma by treatment with rat mAb. These results suggest that both L3T4+ and Lyt-2+ T cells play a role in acquired immunity to systemic C. albicans infection, and that their activity may involve IFN-gamma-mediated stimulation of candidacidal mechanisms.     

Thymic stroma-derived T cell growth factor (TSTGF). IV. Capacity of TSTGF to promote the growth of L3T4- Lyt-2- thymocytes by synergy with phorbol myristate acetate or various IL

The present study investigates the role of thymic stroma-derived T cell growth factor (TSTGF) in promoting the growth of L3T4- Lyt2- (double-negative) thymocytes. Partially purified TSTGF samples were prepared from the culture supernatant of a newly established thymic stromal cell line, MRL104.8a. The TSTGF alone induced only marginal proliferation of double-negative thymocytes, whereas this factor exerted a potent growth-promoting effect on these cells in combination with PMA. Because such an enhanced proliferation was not inhibited by anti-IL-4 or anti-IL-2R antibody, this was not due to the stimulation of an autocrine mechanism involving the production and utilization of IL-4 or IL-2. In scrutinizing PMA-equivalent physiologic substance(s), IL-1 was revealed to be capable of replacing the role of PMA in the above co-stimulation cultures and including enhanced proliferation of double-negative thymocytes in combination with TSTGF. Although TSTGF plus IL-2 or IL-4 also exhibited an appreciable or moderate synergistic effect on the growth of double-negative thymocytes, its magnitude was weaker compared with that obtained by TSTGF plus IL-1. More important, the strikingly enhanced proliferation was induced in the combinations of TSTGF, IL-1, and IL-2 or IL-4 under conditions in which the proliferation induced by IL-1 plus IL-4 or IL-1 plus IL-2 was marginal or slight. Furthermore, such strongly enhanced proliferation was also observed in the double-negative thymocyte population which was additionally depleted of T3+ cells (namely, the L3T4- Lyt-2- T3- or dull population). These results indicate the crucial role of TSTGF in the proliferation of immature thymocytes by synergy with various cytokines.