Specific binding of T lymphocytes to macrophages. V. The role of Ia antigens on Mphi in the binding.

The effect of anti-Ia alloantiserum on the capacity of selected peritoneal exudate lymphocytes (selected PEL) to bind to antigen-pulsed F1 (responder x nonresponder) macrophages was investigated. With the use of selected PEL for antigens under Ir gene control, it was shown that anti-Ia serum to the responder haplotype blocked adherence of selected PEL to antigen-pulsed macrophages whereas anti-Ia serum to the nonresponder haplotype did not. The target cell of the anti-Ia alloantiserum appeared to be the macrophage because anti-13 Ia in contrast to anti-2 Ia did not inhibit binding of F1 (2 x 13) DNP-GL selected PEL to DNP-GL pulsed strain-2 Mphi (responder strain). Taken together with previous experiments that indicate that an antibody to the native protein antigen employed is unable to block specific binding, the present results suggest that T cells may recognize fragments of exogenous antigen in association with Ia molecules.     

Specific binding of T lymphocytes to macrophages. III. Spontaneous dissociation of T cells from antigen-pulsed macrophages.

Peritoneal exudate lymphocytes (PEL) from immune guinea pigs that adhere to antigen-pulsed macrophages (MO) were cultured for 1 week to yield a population enriched in antigen-specific (selected) T cells. These cells bind specifically within hours to fresh autologous antigen-pulsed MO. Thd dissociation of these selected PEL from antigen-pulsed MO was studied. No evidence was obtained that factors in the culture medium play a role in dissociation. Lymphocytes that have dissociated from antigen-pulsed MO are usually fully capable of rebinding to MO freshly pulsed with antigen, suggesting that there is no deficiency in the lymphocytes ability to bind. In contrast, readding antigen to cultures during incubation prevents the predicted dissociation. Moreover, repulsing MO cultured without selected PEL restores their capacity to bind fresh selected PEL. These findings indicate that decay of antigen associated with with MO is the major mechanism underlying the observed dissociation.     

Alveolar macrophages in pulmonary immune responses. I. Role in the initiation of primary immune responses and in the selective recruitment of T lymphocytes to the lung

Antigen inoculated intratracheally (IT) into animals can induce primary immune responses and selectively recruit specific T cells to the lung. In the current study, the role of alveolar macrophages (AM) in these two responses was investigated. Antigen-pulsed bronchoalveolar cells (BAC) inoculated IT into guinea pigs generated a population of immune T cells that proliferated in vitro on reexposure to antigen-pulsed macrophages (M?). The possibility that antigen-pulsed donor BAC shed antigen that was subsequently processed and presented by host M? was ruled out by genetic experiments. Thus, peritoneal exudate lymphocytes (PEL) from (2 X 13)F1 guinea pigs primed with antigen-pulsed BAC from strain 2 animals responded preferentially to antigen-pulsed strain 2 M? rather than to antigen-pulsed strain 13 M?. In a second set of studies, antigen-pulsed BAC inoculated IT into guinea pigs selectively recruited antigen-specific T cells to the lung. Genetic experiments verified that inoculated BAC were the source of the antigen-presenting cells responsible for selective recruitment. Thus, antigen-pulsed strain 2 BAC inoculated IT recruited a greater proportion of (2 X 13)F1 T cells that recognized antigen in the context of strain 2 M? than F1 T cells that recognized antigen on strain 13 M?. Taken together, these studies suggest that AM contribute to the regulation of pulmonary immunity by both inducing T lymphocyte immunity and selectively recruiting specific T cells to the lung.     

In vitro selection and extended culture of antigen-specific T lymphocytes. II. Mechanisms of selection.

Functional selection of antigen-specific T lymphocytes can be achieved by culturing thymus-dependent (T) lymphocytes from immunized guinea pigs on "monolayers" of antigen-pulsed adherent peritoneal exudate cells (PEC) from nonimmune syngeneic donors. Several aspects of the in vitro selection of T lymphocyte-rich peritoneal exudate lymphocytes (PEL) were studied. It was shown that irradiated adherent PEC were equivalent to nonirradiated adherent PEC in supporting selection cultures, indicating that the lymphocytes harvested at the end of the selection culture derive from the immune donors of the PEL and not from the nonimmune donor of the adherent PEC. The relative importance of specific adherence and specific proliferation for achieving selection was determined by comparing the degree of selection obtained when nonadherent cells were discarded at 24 hr with that noted when the discard step was omitted. It was found that omitting the discard step markedly diminished the degree of selection. On the other hand, blocking proliferation with specific alloantisera after the discard step did not diminish the degree of selection, although it did diminish the cell yield. Thus, specific adherence to antigen-pulsed PEC appeared to be critical in the selection culture procedure. An estimate of the degree of enrichment obtained by the selection culture procedure was obtained by culturing selected cells in an excess of nonprimed PEL, so that auxiliary cells would not be limiting. Under these conditions, it appeared that selected cells were enrichied from 4- to 10-fold in antigen-responsive cells with respect to the initial cell population.     

Nature of T lymphocyte recognition of macrophage-associated antigens. IV. Inhibition of peptide antigen presentation by brief treatment of macrophages with anti-Ia serum

To examine the role of macrophage la antigens in T-lymphocyte stimulation, guinea pig macrophages were briefly treated with anti-Ia serum before or after antigen pulsing with the peptide antigen human fibrinopeptide B (hFPB). To assess their antigen-specific stimulatory capacity, the variously treated macrophages were added to culture with hFPB-immune guinea pig T cells and stimulation was determined by the incorporation of [³H]thymidine. Macrophages treated with anti-Ia serum before antigen pulsing stimulated T-cell responses equivalent to those observed with antigen-pulsed macrophages treated with normal serum. By contrast, brief anti-Ia treatment of macrophages immediately following a 2-hr antigen pulse reduced subsequent T-cell responses by 45 to 70%. Similar treatment of macrophages pulsed with antigen for only 1 hr produced only modest inhibition of T-cell responses. However, if macrophages pulsed for 1 hr with antigen were incubated several hours before brief anti-Ia serum treatment, the subsequent T-cell responses were reduced by 40 to 60%. This inhibition was specific for antiserum directed against Ia antigens of the guinea pig MHC, since brief macrophage treatment with antiserum directed against B.1 antigens, the guinea pig equivalent of murine H-2K and H-2D antigens, produced no inhibition of their T-cell stimulatory capacity. These results are discussed with respect to the formation of the immunogen presented by macrophages for T-cell recognition.     

The expression of Ia antigens on immunocompetent cells in the quinea pig. I the differential expression of Ia antigens on T cell subpopulations.

We have examined the effect of negative selection with anti-Ia serum and C on a number of T cell functions and have clearly defined two subpopulations of guinea pig T lymphocytes. One subpopulation is susceptible to the lytic effects on anti-Ia serum and C and includes the majority of the primed T cells which proliferate and which produce migration inhibition factor in response to specific antigen stimulation in vitro. The lytic effects of anti-Ia serum were directed against the antigen-specific T cell and not an accessory cell such as a macrophage or nonantigen-specific T cell. No evidence for allelic exclusion of the Ia antigens of the antigen-responsive cell could be demonstrated. The susceptibility of the mitogen-responsive T cell to lysis by anti-Ia serum and C varied with the mitogen used, anatomic origin of the T cell, and the strain of animals studied. A second subpopulation of T cells is completely resistant to the lytic effects of anti-Ia serum and C and includes the primed T helper cell and the T cell that proliferates in response to alloantigenic stimulation in the MLR.     

Specific binding of T lymphocytes to macrophages. II. Role of macrophage-associated antigen.

Peritoneal exudate lymphocytes from immune guinea pigs that bind in vitro to autologous antigen-pulsed macrophages were allowed to proliferate for 1 week to give a population markedly enriched in antigen-specific T cells. This enriched population was then studied with regard to its binding to fresh autologous antigen-pulsed macrophages. Specific binding was not inhibited by a large excess of antigen in the media (5000-fold greater than the amount of antigen associated with the macrophages) either soluble or bound to Sepharose beads, or by coating the antigen-pulsed macrophags with antibody to the exogenous antigen, by reacting a second layer of antibody to the heterologous antibody, or by haptenating the antigen and treating the hapten-antigen macrophage complex with excess anti-hapten antibody. Results of treating antigen-pulsed macrophages with the proteolytic enzymes trypsin and pronase indicate that exogenous antigen is on the macrophage surface, but the experiments failed to prove that the removable antigen is essential for binding. The simplest interpretation of these results is that the T cell receptor is not specific for native exogenous antigen.     

Antigen-specific T cell cluster formation on antigen-pulsed macrophage monolayers in mice

We describe the quantitative measurement of antigen-specific clusters formed by antigen-pulsed macrophages and immunized T cells in mice. We have found the peripheral blood T cells show very little non-specific adhesion to macrophages in mice. By using this population of lymphocytes in the peripheral blood as the source of immunized T cells, we could quantitate antigen-specific cluster formation. On OVA-pulsed monolayers of peritoneal exudate macrophages from normal BALB/c mice, syngeneic peripheral blood T cells from donors immunized with the same antigen develop 20-40 clusters per 1,000 macrophages, whereas the same T cells on non-pulsed monolayers develop only 0-5 cluster-like accumulations of cells. On antigen-pulsed monolayers of macrophages from allogeneic (C57BL/6 or A/J) mice, clusters are developed only in the negative range (0-5/1,000 macrophages). Considering the observation by Braendstrup et al, these data seem to suggest that histocompatibility between macrophages and T cells is required to develop antigen-specific T cell clusters on antigen-pulsed macrophage monolayers, and that the genetic restriction of immune responsiveness may be directly expressed in this initial form of cellular interaction between antigen-bearing macrophages and specific T cells.     

The expression of Ia antigenic determinants on macrophages required for the in vitro antibody response.

A subpopulation of antigen-presenting macrophages required for an in vitro antibody response to burro erythrocytes was deleted by pretreating the splenic macrophages with anti-Ia serum and complement (C). The in vitro response of the macrophage depleted T-B cell population could not be restored by the addition of macrophages resistant to anti-Ia antibodies and C (Ia-). The response of Ia- macrophages and the macrophage-depleted T-B cells was only reconstituted by the addition of Ia+ macrophages. Macrophages pretreated with anti-Ia antibodies restricted to react with determinants of one I subregion could not support the in vitro antibody response when added to cultures whose macrophages were pretreated with anti-Ia serum and C specific for the I-J subregion. These results confirmed that Ia determinants of the I-A, the I-E, and the I-C subregions were all expressed on the I-J+ macrophage required for an in vitro antibody response.     

Generation of T helper cells in vitro. IV. F1 T helper cells primed with antigen-pulsed parental macrophages are genetically restricted in their antigen-specific helper activity.

A sequential culture technique for the in vitro induction and subsequent assay of T helper cells is employed to examine the histocompatibility requirements for antigen recognition by murine T helper cells. F1 T cells are primed in vitro with antigen-pulsed parental strain macrophages and tested for antigen-specific helper activity in cultures containing anti-Thy 1.2 serum and C treated spleen cells from hapten-primed parental or F1 mice. A semiallogenieic system is used and appropriate controls are included to avoid possible complicating effects of allogeneic interactions. The results indicate that F1 T helper cells preferentially stimulate carrier-specific anti-hapten plaque-forming cell responses in spleen cells which are H-2 identical with the macrophage used initially to prime the T cells. Parental spleen cell cultures do not respond to F1 T helper cells which were primed with the other parental strain macrophage. Supplementing this culture with macrophages which are histocompatible with those used to prime the F1T cells is sufficient to restore T helper cell activity. Thus, the genetic restriction described here is between the primed T cell and the macrophage used to elicit secondary responses and not between the T cell and B cell. The results in this semiallogeneic system, however, do not rule out the possibility of additional allogeneic genetic restrictions in the subsequent interaction of T cells with B cells.     

Antigen-specific helper factor production by immortalized clone of OVA-specific T cells. I. In vitro activity

Immortalized clones of virally transformed OVA-specific T cells produce antigen-specific helper factor upon stimulation in vitro. The helper factor activate DNP-primed B cells to multiply and synthesize IgG anti-DNP antibodies. The trigger of the helper clone is antigen specific and the B cell-stimulating hapten must be coupled to the specific T cell carrier in order to transfer the help signal from the activated T clone to the B lymphocytes. Activation of the helper clone is performed by antigen-pulsed macrophages and cannot be achieved by the free soluble antigen. However, cell-free supernatant of the antigen-pulsed macrophages can stimulate the helper cells. Thus the antigenic determinant must be presented to the helper cell in the form of macrophage-processed antigen. These requirements for antigenic stimulation and the activity of the secreted helper factor demonstrate that the immortalized helper clone preserved the cellular components which control the antigen-specific immune function of the normal T lymphocyte.     

The expression of Ia antigens on immunocompetent cells in the guinea pig. II. Ia antigens on macrophages.

Only 15 to 25% of purified oil-induced guinea pig macrophages could be lysed by treatment with anti-Ia serum and C. Those cells remaining alive after treatment were not damaged and were metabolically active since they readily phagocytized latex beads. However, the "Ia-negative" macrophages were markedly deficient in their ability to present protein antigens to immune T lymphocytes and to function as stimulator cells when mixed with allogeneic T cells in the mixed leukocyte reaction. It thus appears that Ia antigens are expressed on a subpopulation of macrophages and that this subpopulation plays a critical role in the activation of T cell proliferation to soluble protein antigens and to alloantigens.     

Immunologic function of endothelial cells: guinea pig aortic endothelial cells support mitogen-induced T lymphocyte activation, but do not function as antigen-presenting cells

The possibility that vascular endothelial cells (EC), like macrophages (M phi), can function as accessory cells necessary for mitogen- and antigen-induced T cell activation was examined. EC were enzymatically detached from the luminal surfaces of guinea pig aortas and then propagated in culture. Lymph node T lymphocytes were rigorously depleted of adherent cells, such that they completely lost the capacity to respond to mitogenic stimulation with phytohemagglutinin or concanavalin A. In this system, EC restored mitogen-induced T cell DNA synthesis as effectively as did M phi. This effect could not be explained by a facilitation of residual accessory cell activity within the responding T cell population, because EC restored mitogen responsiveness to T cells that had been treated with anti-Ia antibody and complement. Support of mitogen responsiveness could not be accounted for by secreted products of M phi or EC in the absence of intact accessory cells. In addition to the capacity to serve as fully sufficient accessory cells for the induction of mitogen-stimulated T cell proliferation, EC exerted a number of modulatory influences on T lymphocyte responses in cultures supported by M phi. When such cultures were supplemented with small numbers of EC, responses were dramatically augmented; larger numbers of EC resulted in marked suppression. At least part of these immunomodulatory effects could be accounted for by the activity of secreted products of EC. EC did not express detectable Ia antigens assayed either by indirect immunofluorescence, with the use of the fluorescence-activated cell sorter, or by complement-mediated cytotoxicity. Moreover, treating the EC population with anti-Ia antibody and complement had no effect on its capacity to support mitogen-induced T cell DNA synthesis. As would be expected from the lack of Ia antigen expression, EC were incapable of presenting antigen to primed T cells. They did, however, carry enough antigen into the cultures such that effective antigen presentation could occur when the cultures were supplemented with M phi that were syngeneic but not allogeneic to the responding T cells. Moreover, EC were capable of dramatically augmenting antigen-specific responses stimulated by antigen-pulsed M phi. There was no genetic restriction for this EC-mediated augmentation of antigen responsiveness. These results indicate that EC are capable of functioning as completely sufficient accessory cells for mitogen-induced T cell DNA synthesis and, in addition, are able to modulate ongoing M phi-supported T lymphocyte responses in both a positive and negative manner.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization and function of autoreactive T-lymphocyte clones isolated from normal, unprimed mice

Self-Ia-reactive cloned T-cell lines, designated PK, were established by long-term culture of T cells from normal DBA/2 mice with irradiated syngeneic splenic adherent cells (SAC), rich in macrophages and dendritic cells. The cell lines were Thy 1+, Lyt 1+, Lyt 2-, produced IL-2 following stimulation with syngeneic spleen cells, and did not exhibit alloreactivity when screened against six different H-2 haplotypes. Of the five cloned PK cell lines tested, four were I-Ed restricted while one was I-Ad restricted as determined by genetic mapping and blocking studies carried out with monoclonal anti-Ia sera. Extensive specificity studies suggested that the PK cells reacted to syngeneic Ia molecules alone and not to foreign antigens such as fetal calf serum (FCS) used in the culture medium, in association with self-Ia. SAC pulsed with FCS or other protein antigens such as turkey gamma-globulin (TGG) were tested for their ability to induce proliferation of autoreactive T cells and other antigen-specific T cells using culture conditions consisting of serumless medium and interleukin 2 (IL-2). The data showed that the autoreactive T cells proliferated better in response to antigen-unpulsed SAC, while FCS-specific and TGG-specific cell lines, developed independently, proliferated only in response to FCS- or TGG-pulsed SAC, respectively, but not to antigen-unpulsed SAC. These results clearly distinguished the autoreactive T-cell clones from the antigen-specific T-cell clones. Preliminary studies carried out to investigate the functions of autoreactive T cells suggested that these cells helped in the in vitro differentiation of alloantigen-specific cytotoxic T lymphocytes (CTL) from CTL precursors obtained from the thymus and augmented syngeneic, allogeneic, and antigen-specific immune responses in vitro. The autoreactive T cells were also capable of inducing both proliferation and differentiation of antigen-specific populations of B cells in the absence of antigen. The present investigation suggests that autoreactive, non-antigen-reactive T cells can be cloned from normal, unimmunized mice and that such cell lines may provide a powerful tool for analyzing the role of the syngeneic mixed lymphocyte reaction in induction and maintenance of both T-and B-cell immune responses.     

The requirement of Ia-positive accessory cells for the induction of tumor-specific cytotoxic T lymphocytes in vitro

The mechanism for the induction of cytotoxic T cells specific for tumor-associated antigens was studied by using fractionated responder T cells, tumor cells, and accessory cells in vitro. The tumor-specific cytotoxic T cells were induced by culturing immunized spleen cells with the tumor cells in vitro for 5 days. Nylon-column-purified T cells alone did not induce cytotoxic T cells upon culture with tumor cells, but the addition of normal spleen cells as accessory cells did successfully induce the cytotoxic T cells, suggesting that the presence of accessory cells is required for the activation of tumor-specific cytotoxic T cells in vitro. The accessory function was associated with spleen cell populations adhering to a plastic dish, a Sephadex G-10 column or a nylon wool column, and was sensitive to anti-Ia serum and C treatment, but was resistant to anti-Ig serum or anti-Thy 1 serum and C treatment, suggesting that the accessory cells are Ia-positive macrophages. Not only syngeneic but also allogeneic macrophages had the accessory function and the allogeneic macrophages were also Ia positive. These results suggest that Ia-positive macrophages play a crucial role in the induction of tumor-specific cytotoxic T cells in vitro. The possible role of Ia-positive accessory cells in the induction of tumor-specific cytotoxic T cells is discussed from the standpoint of cellular interactions.     

Adherent cell function in murine T lymphocyte antigen recognition. I. A. macrophage-dependent T cell proliferation assay in the mouse.

The data in this report describe a T cell proliferation assay with nylon wool column-purified murine lymph node lymphocyte from animals immunized by footpad injection of antigen in CFA. It was found that the in vitro immune response of sensitized T cells to soluble protein antigens was functionally dependent on the presence of adherent cells, more specifically macrophages, at all concentrations of in vitro antigen challenge. The response was due to T cells in that cytotoxic treatment of the immune lymphocyte cells with anti-Thy 1.2 serum and complement effectively eliminated the antigen-specific DNA synthetic responses. The antigen-specific proliferation of murine lymphocytes depleted of adhereent cells could not be reconstituted with either guinea pig macrophages nor murine fibroblasts, indicating the existence of species and cell type specificity. In contrast to previous observations in the guinea pig, soluble products of cultured adherent cells could at least partially replace the function of intact macrophages in the response to antigen.     

Antigen presentation by liver sinusoidal lining cells after antigen exposure in vivo

The ability of liver sinusoidal lining cells (LSLC), a mixture of Kupffer cells and endothelial cells, to function as antigen-presenting cells (APC) was examined. Guinea pig LSLC were found to present antigen in vitro, albeit somewhat less effectively than a reference population of peritoneal exudate macrophages. The difference in APC function could not be explained by a deficiency of interleukin 1 (IL 1), as LSLC secreted IL 1 and expressed membrane-bound thymocyte stimulatory activity. The ability of LSLC to take up antigen from the portal blood in vivo and present it to primed T lymphocytes in vitro was also investigated. Trinitrophenyl-ovalbumin was injected intraportally into either strain 13 or strain 2 guinea pigs. The LSLC were subsequently isolated by collagenase digestion and density separation and assessed for the ability to induce proliferation of antigen-primed accessory cell-depleted syngeneic peritoneal exudate T lymphocytes in vitro. The in vivo antigen-pulsed LSLC were found to present antigen in vitro to primed T cells in an antigen-specific and genetically restricted manner. T cell DNA synthesis induced by antigen-bearing LSLC could be augmented by coculture with additional accessory cells, but not IL 1-containing macrophage supernatants. Enhancement of responsiveness was not genetically restricted. The demonstration that LSLC can take up, process, and retain antigen in vivo and present it to primed T cells in vitro suggests that LSLC are capable of contributing to the immune response to antigens appearing in portal blood.     

Immortalization of antigen specific, helper T cell lines by transformation with the radiation leukemia virus (RadLV)

Antigen-specific immune T lymphocytes of male C57BL/6 mice were enriched in vitro on monolayers of antigen-pulsed syngeneic macrophages. The cells were treated in vitro with RadLV and inoculated intrathymically into irradiated female C56BL/6 animals. Thymomas arising in the inoculated recipients were characterized as donor- (male) type according to their karyotype. In vivo and in vitro cell lines were established from the primary lymphomas, two of which (designated ROT/6.1 and ROT/6.2) were capable of providing antigen- (carrier) specific help in normal or preimmunized mice. None of the lymphomas could induce antigen-specific DTH reaction. Five months after their establishment, ROT/6.2 alone retained its carrier specificity. ROT/6.2 consisted mainly of Lyt-1+ cells, whereas the ROT/6.1 population was more heterogeneous and contained Lyt-1+, Lyt-2+, and Lyt-3+ cells. The carrier specificity of the latter may have been lost due to selection against the specific helper cells during prolonged passages.     

Effect of interferon-gamma on myelin basic protein-specific T cell line proliferation in response to antigen-pulsed accessory cells.

We have shown previously that treatment of SJL/J mice with anti-interferon-gamma monoclonal antibody (mAb) exacerbated experimental allergic encephalomyelitis (EAE) only if administered at the time of encephalitogenic challenge. Here we investigate the role of interferon-gamma (IFN-gamma) and anti-IFN-gamma mAb in the early events of T cell activation in vitro. Pretreatment of murine peritoneal exudate cells (PEC) with IFN-gamma led to a significant increase in their ability to activate myelin basic protein (MBP)-specific, short-term T cell lines. When exogenous IFN-gamma was added to cocultures of T cells and MBP-pulsed PEC, the antigen-specific T cell proliferation was considerably reduced. Anti-IFN-gamma mAb added to these cultures neutralized the inhibitory effect of the exogenous IFN-gamma on T cell proliferation but had no visible effect on class II MHC expression by the antigen-pulsed PEC present in the same cultures. A reduction in T cell proliferation was also observed when the T cells were treated with IFN-gamma prior to coculture with the MBP-pulsed PEC. These results demonstrate that, on one hand, IFN-gamma enhances the ability of PEC to induce antigen-specific T cell proliferation but, on the other hand, acts on the T cells themselves by inhibiting their proliferation in response to the antigen-pulsed PEC. This may explain why treatment with anti-IFN-gamma antibody in vivo induces EAE exacerbation.     

Role of macrophages as modulators but not as autonomous accessory cells in the proliferative response of immune T cells to soluble antigen

The role of murine macrophages (M phi) and that of splenic dendritic cells (DC) were investigated in the antigen-specific proliferative response of memory T cells of mice primed with key-hole limpet hemocyanin (KLH) 6 weeks or more before. Peritoneal M phi, whether expressing Ia antigens or not, did not function as autonomous accessory cells (A cells). A-cell activity of the spleen adherent cell population, which comprised M phi in the majority and DC in the minority, was abolished by eliminating DC with a DC-specific monoclonal antibody and complement, and regained by the addition of a small number of DC. Though M phi did not function as autonomous A cells, they augmented the proliferative response in the presence of a small number of DC. This occurred not only in the presence of free antigen, but also when DC and/or M phi were pulsed with antigen. A culture supernatant of M phi having interleukin-1 activity was effective in enhancing the proliferation of T cells which responded to antigen-pulsed DC. On the other hand, interleukin-2 did not replace DC even in the presence of antigen-pulsed Ia+ M phi. We also investigated recently primed T cells, but no evidence was obtained in favor of the competence of M phi as autonomous A cells.