Alloantigen presentation by B cells: two types of alloreactive T cell hybridomas, B cell-reactive and B cell-nonreactive

T cell-depleted, Sephadex G-10-passed unstimulated splenic B cells from C57BL/6 mice stimulated splenic T cells from CKB mice to produce IL 2 and to proliferate. The stimulatory ability of the unstimulated B cells was eliminated by 4000 rad irradiation of the unstimulated stimulator B cells. LPS-activated B cells could stimulate responder T cells more efficiently than unstimulated B cells. For further analysis of allostimulation by B cells, we established a series of alloreactive T cell hybridomas. Forty-five percent of these alloreactive T cell hybridomas could be stimulated to produce IL 2 by either macrophage-dendritic cells or unstimulated B cells. Fifty-five percent of these alloreactive T cell hybridomas could be stimulated by macrophage-dendritic cells but not by unstimulated B cells. T cell hybridomas that were not reactive with unstimulated B cells were also nonreactive to LPS-activated B cells. Analysis of two representative I-Ab-reactive T cell hybridoma clones, B cell-reactive clone CB-11.4 and B cell-nonreactive clone HTB-9.3, revealed again that the stimulatory ability of unstimulated B cells was sensitive to 4000 rad irradiation in the activation of CB-11.4 clone and that CB-11.4 could be stimulated more efficiently by LPS-activated B cells than by unstimulated B cells, but HTB-9.3 could not be stimulated by LPS-activated B cells. Thus, there may be two distinct types of T cells in the alloreaction: B-cell-reactive and B cell-nonreactive.     

The role of dendritic cells as stimulators of minor lymphocyte-stimulating locus-specific T cell responses in the mouse. I. Differential capacity of dendritic cells to stimulate minor lymphocyte-stimulating locus-reactive T cell hybridomas and the primary anti-minor lymphocyte-stimulating locus mixed lymphocyte reaction

The response of T cells to minor lymphocyte-stimulating locus (Mls) determinants remains poorly understood with respect to the antigenic determinants responsible for T cell stimulation and the types of APC capable of stimulating the response. In this report, we demonstrate that highly purified dendritic cells (DC) as well as B cells have the capacity to stimulate Mls-specific responses. Unseparated spleen cells, purified DC, resting B cells, and activated B cells were compared for their capacity to stimulate several Mls-reactive T cell hybridomas. Whereas the entire panel of Mls-reactive T cell hybridomas was stimulated strongly by unseparated spleen cells and activated B cells, the hybridomas responded only weakly to purified DC or resting B cells. Activation of resting B cells with either B cell stimulatory factor-1 (1 day pre-treatment) or LPS/dextran (2 or 3 day pre-treatment) greatly augmented their Mls-stimulatory capacity. In contrast, the Mls-stimulatory capacity of DC was not augmented by a 1-day pre-treatment with either B cell stimulatory factor-1 or supernatant from the DC-induced primary anti-Mls-MLR. In the primary anti-Mls-MLR, both purified DC and LPS/dextran-stimulated B blasts were found to elicit vigorous T cell proliferative responses. Much weaker responses were elicited by unseparated spleen cells. The stimulation of the primary anti-Mls-MLR by purified DC was further confirmed by producing Mls-specific T cell clones which were preferentially stimulated by DC. Autologous (Mlsb) DC were found to markedly enhance the primary anti-Mls-MLR response to small numbers of Mlsa B blasts. Thus, DC possess other "accessory cell" properties that augment the primary anti-Mls-MLR despite the predicted low level of Mls determinant expression on DC based on the results obtained with Mls-reactive hybridomas. Possible accessory cell properties of DC relevant to this phenomenon are discussed.     

Constitutive production of a factor supporting B lymphocyte differentiation by a T cell hybridoma

To investigate the role of soluble T cell products during B cell differentiation more fully, we have produced T cell hybridomas by the fusion of normal helper T cells with the T cell lymphoma BW5147. In this report we describe the production of one such hybrid, 14G3, the subclone 14G3.1F2, and the functional activity of the constitutive product. The hybrid supernatant acts exclusively in antigen-nonspecific, but antigen-dependent, promotion of B cell differentiation. It is optimally effective in the presence of small amounts of EL4 supernatant. It does not itself contain any detectable IL 2 or BCGF or interferon activity, however. 14G3.1F2 activity is probably an important component of the conventional TRF preparations produced by mixed lymphocyte populations, and will be useful in further dissection of the contributions of different soluble T cell products to B cell differentiation.     

T cell-induced expression of membrane IgG by 70Z/3 B cells

To study T cell regulation of B cell isotype differentiation, we determined the capacity of clonal T cell populations (hybridomas derived by fusing BW5147 with Con A-activated Peyer's patch (PP) and spleen T cells) to induce "downstream" isotype expression by the pre-B cell lymphoma 70Z/3. In initial studies, we found that 70Z/3 B cells cultured in the presence of LPS (1 microgram/ml) expressed membrane IgM (mIgM) but not membrane IgG (mIgG). In contrast, 70Z/3 B cells cultured with HAJ-3 T cells, a PP-derived T cell hybridoma (as well as other similarly derived PP and spleen hybridomas), or with HAJ-3 T cells plus LPS do express mIgG. Such expression occurred in spite of mitomycin C-induced blockage of cell proliferation, and is observed in 70Z/3 B cell subclones cultured with HAJ-3 T cells. For these reasons, it is not due to selective expansion of a small pre-switched mIgG-bearing 70Z/3 B cell subpopulation. In other studies it was shown that 70Z/3 B cells expressing mIgG after induction by HAJ-3 T cells continue to express mIgM and do not secrete IgG. Finally, exposure of 70Z/3 B cells to the macrophage factor IL 1 and the T cell factors IL 2, BSF-pl, and BCGF-II present in EL-4 cell supernatants did not result in mIgG expression. On the basis of these studies, we conclude that a clonal B cell population expressing mIgM can be induced by T cells to co-express mIgG. Because the B cells do not express mIgG unless exposed to T cells, this represents a T cell-induced isotype switch.     

Production of human suppressor T cell hybridomas

To study human T cell suppression of immunoglobulin (Ig) synthesis with homogeneous populations of immunoregulatory cells, human suppressor T cell hybridomas were prepared by somatic cell fusion of concanavalin A-activated peripheral blood T cells with hypoxanthine-guanine phosphoribosyltransferase-(HGPRT, EC 2.4.2.8) deficient human leukemic CEM T cells. After selection in hypoxanthine-aminopterin-thymidine (HAT) medium and cloning by limiting cell dilution, two human T cell hybridomas were identified that produced 60 to 80% suppression of in vitro polyclonal immunoglobulin production when cocultured with pokeweed mitogen- (PWM) stimulated peripheral blood lymphocytes. Further, one of the suppressor T cell hybridomas constitutively secreted a soluble suppressor factor(s) (TsF) of m.w. 70,000 to 85,000 daltons, which produced reversible noncytotoxic inhibition of lectin-activated B cell Ig production. In contrast, this TsF did not inhibit lectin- or antigen-induced T cell proliferation, nor did it interfere with the generation or effector function of cytotoxic T cells. Additional studies indicated that this Tsf acts directly on B cells or monocytes rather than indirectly modulating the activity of immunoregulatory T cells. In summary, these studies suggest that techniques of somatic cell fusion may provide a valuable approach to further study human immunoregulatory cell-cell interactions as well as provide a source of sufficient quantities of important lymphokines for further purification and characterization.     

Production of T-T hybrids from T cell clones. Direct comparison between cloned T cells and T hybridoma cells derived from them

It has been assumed, without direct evidence, that T cell hybridomas and non-transformed T cell clones are both good models of normal Ag-specific T cells. To compare directly the difference in activation of cloned normal T cells and T hybridoma cells with the same TCR, cloned T hybridoma cells were obtained by fusing pre-established, myoglobin-specific, Iad-restricted T cell clones (14.5 and 9.27) with BW5147 cells. T cell clones were pre-activated with IL-2 as well as specific Ag before fusion. Cloned T hybridoma A3.4C6 was derived from Lys 140-specific and I-Ed-restricted clone 14.5. The other cloned T hybridoma, C7R14, was a fusion product of Glu 109-specific and I-Ad-restricted clone 9.27. Both T hybridomas showed the same Ag specificity and Ia restriction as the parental cloned T cells. However, C7R14 showed higher apparent affinity and broader cross-reactivity than 9.27. Clone 14.5, but not hybridoma A3.4C6, appeared to stimulate splenic cells to secrete cytokines inhibiting HT-2A cell proliferation. The most striking difference between the clones and hybridomas was that both clones, but neither of the matched hybridomas, were induced to synthesize IL-1 on stimulation with Ag. Finally, both cloned T cells and T hybridomas killed Ag-pulsed Iad-bearing B lymphoma target cells. This evidence suggests that killing function can be inherited from clones to hybridomas. However, the clones were much more efficient at killing than the hybridomas, and the hybridomas were more efficient at IL-2 production than the clones. Thus, matched pairs of clones and hybridomas differ in their capacity to mediate the two functions or may tend to be selected differently during cloning. Thus, although our results generally support the validity of T cell hybridomas as faithful models of the corresponding T cell clones, a number of subtle and not-so-subtle differences indicate that caution must be used in such an extrapolation.     

Inhibition of IgE production in B hybridomas by IgE class-specific suppressor factor from T hybridomas

The function of IgE class-specific suppressor factor (IgE-TsF) from T hybridomas was studied by employing IgE-producing B hybridomas. IgE-TsF was obtained from IgE class-specific T hybridomas, which had been established by the fusion of a phosphorylcholine-conjugated Mycobacterium-primed T cell population with the T lymphoma cell line BW5147. The absorption experiments showed that IgE-TsF from T hybridomas was composed of the binding site(s) for IgE and I region gene products as observed in conventional IgE-TsF. Incubation of IgE-producing B hybridomas with IgE-TsF for 1 hr at 37 degrees C resulted in the reduction of the number of IgE-secreting cells when assessed by a reverse plaque assay. The proportions of surface IgE-positive cells were concomitantly reduced. After 24 hr incubation with IgE-TsF, the number of cytoplasmic IgE-positive cells was reduced, showing that IgE synthesis was inhibited by IgE-TsF. Antigen-specific TsF from phosphorylcholine-specific T hybridomas did not show any inhibitory effect, and IgE-TsF did not block the antibody production of IgM-producing B hybridomas. Precapping of IgE receptors by anti-epsilon antibody or the simultaneous addition of soluble IgE with IgE-TsF abrogated the suppressive function, suggesting that IgE-TsF acted directly on B epsilon cells through binding with IgE receptors.     

Modification of the amino terminus of a class II epitope confers resistance to degradation by CD13 on dendritic cells and enhances presentation to T cells

Dendritic cells and human B cell lines were compared for ability to present synthetic peptides corresponding to residues 145-159 and 188-203 of human Ig kappa-chains to peptide-specific mouse T cell hybridomas restricted by HLA-DR4Dw4. B cell lines presented both peptides, but dendritic cells could only efficiently present the latter epitope. In this paper, we show that dendritic cells degrade the 145-159 peptide, removing four residues from the amino terminus. Binding of the peptide to the class II restriction element is not required for this process. The degradation product is resistant to further cleavage, accumulates in the culture supernatant, and does not bind to HLA-DR4Dw4 or stimulate T cell reactivity. Cleavage can be blocked with bestatin, but not with other protease inhibitors tested, or by a mAb directed against aminopeptidase N (CD13). Addition of an acetyl group to the amino terminus of peptide 145-159 also blocks degradation, and allows dendritic cells to present the peptide to specific T cells with greatly increased efficiency. These results demonstrate that CD13 on dendritic cells is able to selectively and efficiently degrade exogenously provided peptide Ags, in a process that can be blocked by addition of an acetyl group to the amino terminus of the peptide. Modification of the amino terminus of peptide epitopes susceptible to degradation may prove to be useful as a general strategy for enhancing their immunogenicity.     

An IL 2-secreting T cell hybridoma that responds to a self class I histocompatibility antigen in the H-2D region

A self-reactive T cell hybridoma that secretes IL-2 in response to H-2d haplotype cells resulted from a fusion of BALB/cBy lymph node cells with the AKR thymoma BW5147. The lymph node cells used had been enriched for cells reactive to (TG)-A--L, but neither this antigen nor fetal calf serum were required for stimulation of the hybridoma designated 3DT52.5. The gene product responsible for stimulation mapped to the H-2D region. Allogeneic cells of the b, f, k, q, and s haplotypes failed to stimulate. Not all H-2d haplotype cells were effective stimulators of 3DT52.5. Peritoneal cells and splenic B cells were much more stimulatory than splenic T cells. Most tumor cell lines of H-2d derivation and of B cell or macrophage/monocyte lineage were stimulatory, whereas H-2d T cell lines were not. The capacity to stimulate 3DT52.5 did not correlate with the ability to stimulate I region-restricted hybridomas, or with the ability to be induced to stimulate such hybridomas. Stimulatory cell lines did not apparently produce a soluble factor required for stimulation, and negative cell lines were not inhibitory. The monoclonal antibody 27-11-13, which reacts with H-2D of the b, d, and q haplotypes, inhibited stimulation of 3DT52.5 but did not inhibit stimulation of the sibling hybridoma 3DT18.11, which responds to (TG)-A--L plus I-Ad. Conversely, the monoclonal anti-I-Ad antibody MK-D6 inhibited stimulation of 3DT18.11 but not 3DT52.5. Although it is clear that 3DT52.5 recognizes a class I antigen coded for in the H-2D region, the precise molecular nature of the antigen is unknown. The structure of the antigen receptor on this hybridoma may prove to be of interest when it can be compared with receptors found on T cell hybridomas restricted by class II histocompatibility antigens.     

Constitutive and mitogen-induced production of T cell growth factor by stable T cell hybridoma lines

Stable T cell growth factor- (TCGF; IL 2) producing cloned T cell hybridoma lines were constructed by fusing murine alloantigen-activated T cells with the 8-azaguanine-resistant lymphoma line, BW5147. Many, but not all, clones of one of these hybridomas, i.e., hybridoma 24, secreted TCGF constitutively, but production was markedly enhanced by stimulation with T cell mitogens. Large numbers of TCGF-secreting hybridoma cells in a stable functional state could be obtained from histocompatible mice inoculated with cloned T cell hybridomas. Moreover, such in vivo-derived hybridoma cells could be stimulated sequentially with mitogen at least twice to secrete their biologically-active product, resulting in larger TCGF yields from the same cells. The secreted product of these T cell hybridoma lines resembled TCGF isolated from other cellular sources in that it: a) supported the growth of a TCGF-dependent T cell line; b) provided help for the induction of alloantigen-reactive cytotoxic T lymphocytes from thymocyte precursors; c) facilitated concanavalin A-induced mitogenic responses of low thymocyte numbers; d) had an apparent m.w. of 30,000 to 40,000 by gel filtration chromatography; and e) was eluted from DEAE-Sephacel ion-exchange chromatography columns by salt concentrations of 30 to 150 mM NaCl. The ability of these T cell hybridomas to grow in vivo and retain their functional characteristics in a stable form should prove useful in terms of providing large numbers of TCGF-secreting cells and studying in vivo aspects of the production of TCGF as well as other immunoregulatory mediators.     

Expression of cell surface antigens by suppressor T cell hybridomas. I. Comparison of phenotype and function

The phenotypic expression of cell surface markers by T cell hybridomas that elaborate suppressor factors specific for the polymers L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) or L-glutamic acid50-L-tyrosine50 (GT) has been analyzed. We found that determinants encoded by the I-J subregion of the H-2 complex were borne on the surface of these hybrid cells and on the factors they secrete, whereas I-J determinants were not expressed by the AKR thymoma fusion parent, BW5147. The level of expression of I-J determinants fluctuated widely depending upon culture conditions, but I-J products and other cell surface markers of normal T cells could be quantitatively increased, or induced to appear, by treatment of the hybridomas with chemical agents, such as dimethyl sulfoxide (DMSO) or phorbol myristate acetate (PMA). In contrast, the surface expression of the viral product gp70 was decreased by the same treatment. Using chemical induction, we typed BW5147, a group of antigen-specific suppressor T cell hybridomas, and two control hybridomas for expression of I-J, Thy-1, Lyt, and H-2K alloantigens. Also, a haplotype-specific hybridoma that produces an antigen-nonspecific factor was analyzed. The results demonstrated that BW5147 failed to express I-J or Lyt alloantigens but expressed Thy-1.1 and H-2Kk gene products. The pattern of expression of these antigens by T cell hybridomas was very complex, but three conclusions could be drawn: 1) Good correlation exists between the expression of certain I-J determinants and the ability of T cell hybridomas to produce suppressor factor. 2) The expression of Thy-1, Lyt, or H-2Kk determinants is variable, and no correlation was found between expression of these antigens and the ability to produce active suppressor factors. 3) I-Jk products contributed by the AKR thymoma fusion partner are expressed by T cell hybridomas.     

Cell receptors for the mammalian reovirus: reovirus-specific T-cell hybridomas can become persistently infected and undergo autoimmune stimulation.

We have previously described the development of virus-specific helper T cell hybridomas which recognize structural determinants shared by type 1 and type 3 reoviruses that have been exposed to UV radiation. We have found that T-cell hybridomas become persistently infected with live type 3 reovirus used for the immunization. Persistently infected T-hybridoma cells were found to spontaneously produce interleukin 2 (IL-2). To analyze the mechanism of induction of IL-2 secretion of persistently infected T-cell hybridomas, we exposed T-cell hybridomas specific for UV-treated virus to replicating type 3 reovirus. The T-cell hybridomas became infected but did not produce IL-2 unless simultaneously exposed to syngeneic I-A+ antigen-presenting cells. In this situation, the persistently infected T-cell hybridomas produced IL-2 without being reexposed to virus. This process was not a consequence of nonspecific IL-2 gene activation, which occurs in cells persistently infected with reovirus, because reovirus infection did not activate IL-2 secretion in T-cell hybridomas with other antigenic specificities. Reovirus exposure also resulted in persistent infection of certain antigen-presenting B-cell tumor lines. The persistently infected B-cell tumor lines could stimulate reovirus-specific helper T cells but not T-cell hybridomas of other specificities. The data support the thesis that persistent infection of reovirus-specific T cells creates a mechanism in which the virus released from these cells is processed and then reexpressed by I-A+ antigen-presenting cells. The IA antigen and reovirus structures on the antigen-presenting cells then restimulate the T cells through their specific receptors, resulting in IL-2 synthesis and release. These observations may be relevant to mechanisms of autoimmunity induced by virus.     

The role of class II MHC molecules in the activation of class I-reactive T cell hybridomas

To examine the role of Ia molecules in T cell responses to allo-class I major histocompatibility antigens, a series of allo-class I-reactive T cell hybridomas was established. Of 134 T cell hybridomas obtained from the fusion of C3H/HeJm or B10.HTT T cells stimulated with C57BL/6 splenocytes, nine T cell hybridomas were reactive to class I antigens and 126 T cell hybridomas were reactive to class II antigens. Six of the nine IL 2-producing T cell hybridomas were further analyzed: five mapped to H-2Kb and the other mapped to H-2Db. Three of these T cell hybridomas, HTB-157.7, HTB-176.10, and HTB-177.2, could react to the EL-4 cell line that expresses H-2Kb and H-2Db class I antigens but lacks class II I-Ab molecules. Furthermore, the activation of these three T cell hybridomas with C57BL/6-derived splenocytes was not blocked by either anti-I-A or anti-L3T4 antibody. In contrast, the other three T cell hybridomas, CB-127.6, CB-221.7, and HTB-102.7, failed to react with EL-4 but reacted with the LB cell line which expresses class I (H-2Kb, H-2Db) and class II (I-Ab) molecules. Although class II molecules were required for activation of the latter clones, there was no apparent I-A allele specificity, suggesting that a relatively nonpolymorphic Ia determinant was involved. The activation of the three latter T cell hybridoma clones with C57BL/6 splenocytes could be blocked completely by either anti-I-A or anti-L3T4 antibody. The data are interpreted in terms of possible T cell receptor models for recognition of class I with nonpolymorphic class II determinants.     

Minor lymphocyte stimulatory antigen-bearing stimulator cells require lipopolysaccharide activation to induce programmed cell death in T cell hybridomas.

T cell hybridomas respond to conventional peptide Ag associated with self major histocompatibility restriction elements, as well as to alloantigens, activating lectins, and stimulatory forms of mAb by producing lymphokines and undergoing programmed cell death (PCD). We show here that the level of PCD and IL-2 production correlate well in responses to CD3 or allostimulation. The response to minor lymphocyte-stimulatory (Mls) Ag, members of the family of endogenous superantigens, however, are marked by divergence in the levels of the PCD and lymphokine responses. Specifically, PCD in response to Mls activation is achieved poorly despite vigorous IL-2 production. B lymphoma cell stimulators induced PCD in alloreactive T cell hybridomas but not in Mls-reactive T cell hybridomas. This suggests that the absence of PCD in the Mls response is a function of superantigen recognition rather than the stimulator cell type. LPS-preactivated Mls+ stimulators, either splenic B or B lymphoma cells, are shown to trigger PCD in the T cell hybridomas. These results imply that T cell interaction with Mls presented by untreated stimulator cells is not sufficient for induction of PCD and thus is distinct from interactions with conventional Ag.     

Thymic selection generates T cells expressing self-reactive TCRs in the absence of CD45

The CD45 protein tyrosine phosphatase regulates Ag receptor signaling in T and B cells. In the absence of CD45, TCR coupling to downstream signaling cascades is profoundly reduced. Moreover, in CD45-null mice, the maturation of CD4+CD8+ thymocytes into CD4+CD8- or CD4-CD8+ thymocytes is severely impaired. These findings suggest that thymic selection may not proceed normally in CD45-null mice, and may be biased in favor of thymocytes expressing TCRs with strong reactivity toward self-MHC-peptide ligands to compensate for debilitated TCR signaling. To test this possibility, we purified peripheral T cells from CD45-null mice and fused them with the BWalpha-beta- thymoma to generate hybridomas expressing normal levels of TCR and CD45. The reactivity of these hybridomas to self or foreign MHC-peptide complexes was assessed by measuring the amount of IL-2 secreted upon stimulation with syngeneic or allogeneic splenocytes. A very high proportion (55%) of the hybridomas tested reacted against syngeneic APCs, indicating that the majority of T cells in CD45-null mice express TCRs with high avidity for self-MHC-peptide ligands, and are thus potentially autoreactive. Furthermore, a large proportion of TCRs selected in CD45-null mice (H-2b) were also shown to display reactivity toward closely related MHC-peptide complexes, such as H-2bm12. These results support the notion that modulating the strength of TCR-mediated signals can alter the outcome of thymic selection, and demonstrate that CD45, by molding the window of affinity/avidity for positive and negative selection, directly participates in the shaping of the T cell repertoire.     

Human severe combined immunodeficiency disease: phenotypic and functional characteristics of peripheral B lymphocytes

Human severe combined immunodeficiency disease (SCID) includes an X-chromosome-linked type characterized by a complete absence of mature T cells, hypogammaglobulinemia but normal or elevated number of B cells, suggesting that the disease results from a block in early T cell differentiation. It has been shown that B cells from obligate carrier women of this disorder exhibit the preferential use of the nonmutant X chromosome as the active X (as shown for T cells), suggesting that the SCID gene product has a direct effect on B cells as well as on T cells. To examine this question, we analyzed the phenotypic and functional characteristics of peripheral B cells from nine infants with SCID. We found a constant absence of spontaneously expressed activation Ag on B cell membrane from all SCID patients tested which contrasts with the phenotypic pattern exhibited by age-matched infants whom all cells bearing surface Ig express the 4F2 Ag and to a lesser extent the transferrin receptor. Concurrently, B cells from SCID patients have a profound impairment in their responses to stimuli that induce in vitro B cell proliferation and differentiation. Although rIL-2 and low-Mr B cell growth factor are potent inducers of proliferation on age-matched infants' B cells, they are poorly efficient in inducing proliferation of anti-mu-activated SCID B cells. This impairment is not related to the resting B cell phenotype of SCID B cells as shown by comparison with normal resting B cells. Furthermore, we observed an apparent block in B cell differentiation inasmuch as neither rIL-2 nor rIL-6 could support SAC-activated SCID B cell differentiation, both lymphokines being very efficient in inducing SAC-activated age-matched infants' B cell or purified resting B cell differentiation. These results suggest that the SCID gene defect has a direct effect on B cells and is required during B cell maturation.     

A "lymphokine-like" soluble product that induces proliferation and maturation of B cells appears in the serum-free supernatant of a T cell hybridoma as a consequence of mycoplasmal contamination

The serum-free supernatant of a cloned murine T cell hybridoma supports the proliferation and maturation to Ig secretion of purified B cells (mu+ cells) from BALB/c nu/nu mice, but has no effect on the proliferation of nylon wool-selected BALB/c nu/+ splenic T cells. Although the supernatant activates B cells without co-stimulation, it synergizes with anti-mu for the proliferative response. The induction of B cell proliferation and maturation to Ig secretion is directly related to contamination of the hybridoma by Mycoplasma hyorhinis. Hybridoma cells freed of mycoplasma by detergent treatment fail to produce active supernatant, and reinfection of the treated cells reconstitutes the activity. Furthermore, deliberate infection of a mycoplasma-free unrelated T cell hybridoma, as well as the monocytic cell line P388D1, results in the production of supernatants with B cell proliferating activity. Mycoplasma organisms isolated from the supernatant induce B cell proliferation without subsequent maturation to Ig secretion. Gel filtration chromatography of the supernatant from mycoplasma-contaminated hybridoma cells yields two peaks of activity. The first peak, found at the exclusion limit of the gel, results in B cell proliferation without maturation and may be attributed to mycoplasma organisms. The second peak (average m.w. 90,000) results in B cell proliferation as well as differentiation to Ig secretion. A "lymphokine-like" soluble product released by Mycoplasma hyorhinis is most likely responsible for this B cell activation, because fractionation of the supernatant from deliberately contaminated P388D1 cells gives essentially the same results, and gel filtration of mycoplasma-free supernatants does not generate any active fractions. The possibility should be considered that mycoplasma-derived soluble products may be among the many factors controlling in vitro B cell growth and maturation.     

Qualitative and quantitative studies of antigen-presenting cell function by using I-A-expressing L cells

I-A-expressing transfected murine L cells were analyzed as model antigen-presenting cells. Four features of accessory cell function were explored: antigen processing, interaction with accessory molecules (LFA-1, L3T4), influence of Ia density, and ability to stimulate resting, unprimed T lymphocytes. I-A+ L cells could present complex protein antigens to a variety of T cell hybridomas and clones. Paraformaldehyde fixation before but not subsequent to antigen exposure rendered I-A+ L cells unable to present intact antigen. These results are consistent with earlier studies that made use of these methods to inhibit "processing" by conventional antigen-presenting cells. The ability of anti-L3T4 antibody to inhibit T cell activation was the same for either B lymphoma or L cell antigen-presenting cells. In striking contrast, anti-LFA-1 antibody, which totally blocked B lymphoma-induced responses, had no effect on L cell antigen presentation, measured as interleukin 2 (IL 2) release by T hybridomas, proliferation, IL 2 release, or IL 2 receptor upregulation by a T cell clone. I-A+ L cell transfectants were found to have a stable level of membrane I-A and I-A mRNA, even after exposure to interferon-gamma-containing T cell supernatants. In agreement with earlier reports, a proportional relationship between the (Ia) X (Ag) product and T cell response was found for medium or bright I-A+ cells. However, dull I-A+ cells had a disproportionately low stimulatory capacity, suggesting that there may be a threshold density of Ia per antigen-presenting cell necessary for effective T cell stimulation. Finally, I-A-bearing L cells were shown to trigger low, but reproducible primary allogeneic mixed lymphocyte responses with the use of purified responder T cells, indicating that they are capable of triggering even resting T cells. These studies confirm the importance of antigen processing and I-A density in antigen-presenting cell function, but raise questions about the postulated role of the LFA-1 accessory molecule in T cell-antigen-presenting cell interaction. They also illustrate the utility of the L cell transfection model for analysis and dissection of antigen-presenting cell function.     

Prostaglandin E2 inhibits the activation of cloned T cell hybridomas

To minimize complicating interactions inherent in heterogeneous cell populations, we used a panel of cloned murine autoreactive (E8.A1) and antigen-specific (HEL.C10, HEL.B14) T cell hybridomas to examine the effect of prostaglandin E2 (PGE2) on T cell activation. These T cells secrete interleukin 2 (IL 2) when co-cultured with a cloned population of I region-matched stimulator cells (TA3), or with mitogenic signals in the absence of TA3 stimulator cells. Physiologic concentrations of PGE2 inhibited the induction of IL 2 secretion by the T cell hybridomas tested, when they were activated either by TA3 cells or by mitogenic signals. IL 2 production was inhibited in a dose-dependent manner by concentrations of PGE2 between 10(-7) and 10(-11) M, with 50% inhibition occurring at 10(-10) M. Pretreatment of the T hybridoma cells with 10(-7) M PGE2 for 1 hr before culture also resulted in marked inhibition of IL 2 secretion. Similar pretreatment of the TA3 cells did not affect their ability to activate the T cell hybridomas. PGE2 at 10(-8) M induced a 30-fold increase in cAMP levels within 25 min of addition to culture of the E8.A1 T cell hybridoma, but caused no significant elevation of cAMP levels in TA3 cells. The direct addition of dibutyryl cAMP (dcAMP) to cultures of E8.A1 cells resulted in marked inhibition of IL 2 secretion when stimulated by TA3 or by mitogenic signals, with an average of 80% inhibition occurring at 10(-4) M dcAMP. PGE2 and dcAMP also inhibited the growth of E8.A1 cells. Initially, cell growth was virtually halted, but began to recover between 24 and 48 hr after the addition of either PGE2 or dcAMP. Neither PGE2 nor dcAMP inhibited the division of TA3 cells. High affinity binding sites for PGE2 were detected in the E8.A1 T cell hybridomas with an apparent Kd of 7.6 X 10(-10) M, which is consistent with the functional data. No specific binding was detected in the TA3 stimulator cells. These findings suggest that the immunosuppressive effects of PGE2 are localized to the T cell, are receptor regulated, and may be mediated by the associated increase of cAMP levels in the T cell hybridomas.     

Immunization with Leishmania-specific T cell not B cell lines or hybridomas can modulate the response of susceptible mice infected with viable parasites

Monoclonal antibodies (mAb), T cell lines, and T or B cell hybridomas were prepared from BALB/c, CBA, or E1 mice infected with Leishmania mexicana. Various mAb were produced which inhibited the growth and motility of parasites in vitro. T cell lines (hybridomas) were screened for their ability to release interleukin 2 on specific antigen exposure. Passive transfer of mAb or T cell lines to infected adult mice caused little perturbation of parasite growth. Recipient naive mice were immunized with purified Ig or irradiated cells from these sources and were subsequently infected with viable parasites. Only preimmunization with T cell lines (hybridomas) led to exacerbation of parasite growth, although enzyme-linked immunosorbent assays could detect the production of anti-idiotype antibodies in mAb (B cell hybridoma)-immunized mice. Either nylon wool-purified T cells or serum Ig from T cell-immunized mice could be used to immunize further naive recipients for protection against parasite growth. These data have implications for the development of anti-idiotype vaccines for Leishmania antigens.