Transfer of cell-mediated hyperacute rejection reaction: The role of active sensitization

The transfer of lymph node cells draining graft sites of allogeneic murine skin results in adoptive immunization of syngeneic recipients, as per hyperacute rejection of allogeneic test skin grafts. The transfer of spleen cells from mice sensitized by i.p. injection of allogeneic cells does not have this result unless the cells undergo a secondary in vitro sensitization. The resultant hyperacute rejection is due in part to adoptive immunization via the spleen cells primed during the in vivo sensitization and rendered transfer effective by the in vitro exposure; in part it is due to active sensitization by carried-over antigen from the in vitro exposure. It follows that the transfer effect of spleen cells sensitized in vivo and in vitro is only in part abrogated by exposure to α-Thy. 1 serum and complement.     

Activation of T cells by glutaraldehyde-fixed erythrocyte antigens: radiosensitivity of cells mediating delayed-type hypersensitivity reactions in the mouse.

Mice immunized with glutaraldehyde-fixed sheep red blood cells (G-SRBC) show delayed-type hypersensitivity (DTH) reactions to G-SRBC or SRBC. The specificity of the DTH reaction of mice sensitized with glutaraldehyde-fixed antigens is similar to that found after sensitization with unfixed antigens. The dose-response curve for sensitization by glutaraldehyde-fixed SRBC was very different from the curve for normal SRBC. At low doses, both antigens were effective in sensitizing to show DTH but neither induced an antibody response. However, at high antigen doses, only the glutaraldehyde-fixed antigen was efficient in sensitizing to show DTH and it failed to raise an antibody titer. Spleen cells of mice sensitized with fixed RBC can transfer DTH locally but if the donor cells are irradiated (500 R), the transfer is abrogated. In contrast, the transfer of DTH by spleen cells of mice immunized with unfixed antigen is not affected by 500 R. The transfer of DTH by spleen cells of mice immunized with fixed antigen can be blocked by “in vitro desensitization” while the transfer of DTH by spleen cells from mice primed with normal antigen is resistant to “in vitro desensitization.” These results suggest that immunization of mice with different physical states of the same antigen can result in the activation of antigen-specific T cells which exhibit markedly different properties.     

A requirement for helper T cells in the induction of delayed-type hypersensitivity

This paper describes a model system for studying the role of helper T cells in the induction of delayed-type hypersensitivity (DTH). Cyclophosphamide- (CP) treated mice sensitized with antigen 3 days later develop high levels of delayed-type immunity; however, DTH cannot be demonstrated in mice that are sensitized with antigen 1 day after drug treatment. The inability to respond to antigen 1 day after CP treatment can be restored if either normal or low-dose primed spleen cells are transferred at the time of sensitization. Although irradiated (1500 rad) normal spleen cells are unable to restore DTH, such treatment has no effect on the primed spleen cell population. The lymphocytes responsible for restoring the DTH response were identified as T cells, in that treatment with anti-Thy-1.2 serum and C abrogated their effect. Furthermore, restoration of the DTH response was dependent on the presence of antigen at the time of lymphocyte transfer; irradiated primed cells could not transfer DTH alone. The DTH effector cells in reconstituted mice were identified as originating from the host and not from the transferred cell population. This was accomplished by using anti-H-2 serum to identify the source of the DTH effector cells after transferring parental (H-2b) irradiated primed spleen cells into CP-treated F1 mice (H-2b,k). Thus, the irradiated transferred cells are behaving as helper T cells and promoting the development of DTH effector cells in the host.     

In vitro and in vivo induction of effector T cells mediating DTH responses to a protein and a synthetic polypeptide antigen.

We have developed an in vitro system for the activation of T cells in order to get a better insight into the genetic and molecular mechanisms involved in the generation of delayed-type hypersensitivity (DTH) effector T cells. Low doses of fowl γ-globulin (FγG) as well as the synthetic polypeptide (T,G)-A-L were bound to splenic adherent cells and served as immunogens for the in vitro sensitization of lymphocytes. In parallel, (T,G)-A-L-specific T cells were activated in vivo in irradiated recipient mice. The ability of the in vitro- and in vivo-activated cells to mediate DTH responses was determined in naive recipient mice by the radioisotopic ear assay. Twenty to thirty × 10⁶ “educated” cells were sufficient to elicit significant DTH responses. Irradiation of the spleen cells prior to their transfer resulted in higher responses. The DTH reactivity was transferable by nylon wool-enriched T cells but not by a Thy 1.2-depleted population indicating the T-cell dependency of the response. The in vitro and in vivo antigen-activated T-cell population exhibited also helper-cell activity as determined by their cooperation with B cells in adoptive transfer experiments.     

Adoptive transfer of experimental allergic encephalomyelitis: requirement for macrophages in activation of spleen cells in vitro by concanavalin A or myelin basic protein

Adoptive transfer of experimental allergic encephalomyelitis (EAE) in Lewis rats is markedly enhanced when sensitized spleen cells are incubated in vitro with either concanavalin A (Con A) or myelin basic protein (MBP). This phenomenon permits more detailed analysis of the inductive phase of EAE than has heretofore been possible. We have now demonstrated that macrophages are essential for the process to occur, and that they probably act by different means depending on whether activation is carried out with the mitogen or the specific antigen. Depletion of macrophages by passage through G-10 Sephadex columns prevented activation of spleen cells by either Con A or MBP. The effect of Con A could be partially restored with 2-mercaptoethanol, while activation by MBP could not. Reconstitution of macrophage-depleted cultures with peritoneal exudate cells from either immune or normal rats fully restored activation by both Con A and MBP. Supernatants taken from spleen cell cultures were unable to restore the transfer activity of macrophage-depleted cells, indicating that activation probably is not mediated by a soluble factor released by macrophages. Depletion of macrophages after incubation with Con A slightly reduced transfer activity, but depletion after incubation with MBP abolished it. Thus the mechanisms of activation appear to differ in the two systems, and in the case of MBP the macrophage-mediated portion of the process may be incomplete prior to adoptive transfer.     

The cellular mechanism of leukocyte adherence inhibition.

Human blood leukocytes from three subjects who had been contact sensitized to dinitrochlorobenzene were used in direct and indirect leukocyte-adherence-inhibition (LAI) reactions in an attempt to elucidate the cellular mechanism of reactivity. The leukocytes were separated and purified by standard procedures. In direct LAI, only T cells or populations containing T cells gave positive reactions (significantly reduced adherence) with the antigen. Supernatants from suitable leukocyte-antigen mixtures contained a soluble leukocyte-adherence-inhibition-factor (LAIF) that reduced the adherence of normal leukocytes. Only T cells or populations containing T cells were active in LAIF production; B cells, granulocytes, and monocytes were inactive. The cellular requirement for the action of preformed LAIF was not restricted: all major types of blood leukocytes were susceptible to its effect.     

Immunity to herpes simplex virus type 2. Suppression of virus-induced immune responses in ultraviolet B-irradiated mice

Ultraviolet B irradiation (280 to 320 nm) of mice at the site of intradermal infection with herpes simplex virus type 2 increased the severity of the herpes simplex virus type 2 disease and decreased delayed-type hypersensitivity (DTH) responses to viral antigen. Decrease in DTH resulted from the induction of suppressor T cells, as evidenced by the ability of spleen cells from UV-irradiated mice to inhibit DTH and proliferative responses after adoptive transfer. Lymph node cells from UV-irradiated animals did not transfer suppression. DTH was suppressed at the induction but not the expression phase. Suppressor T cells were Lyt-1+, L3T4+, and their activity was antigen-specific. However, after in vitro culture of spleen cells from UV-irradiated mice with herpes simplex virus type 2 antigen, suppressor activity was mediated by Lyt-2+ cells. Culture supernatants contained soluble nonantigen-specific suppressive factors.     

Mechanisms involved in the antibody-mediated suppression of tuberculin-type delayed hypersensitivity: II. The sensitivity of tolerance induction to cyclophosphamide pretreatment and splenectomy,and the demonstration of active suppression

The induction of tuberculin-type delayed hypersensitivity, as measured by skin test, can be specifically inhibited by administration of antibody during sensitization. The cellular mechanisms involved in this tolerance were investigated in CAP₁ mice, using chicken conalbumin as antigen. Tolerance was prevented when mice were treated with Cyclophosphamide 2 days before sensitization and suppression. However, it was not affected by splenectomy 7 or 21 days before sensitization. This tolerance could be transferred to normal CAF₁ mice with spleen cells, but not with thymocytes, when taken from donor mice 21 to 28 days after sensitization and tolerance induction. Production of these cells in the donors required both antibody and antigen. The cells responsible for the transfer were B cells, as shown by their sensitivity to rabbit anti-mouse-immunoglobulin serum and complement. In addition to B cells, serum from tolerant mice also could transfer suppression at 21 to 28 days. We conclude that sensitizing mice, and treating them with specific immunosuppressive antiserum, induces the recipients to make suppressor B cells and suppressive humoral factors, which are involved in arresting the induction of tuberculin-type delayed hypersensitivity.     

Antigen-specific augmentation factor involved in murine delayed-type footpad reaction. IV. Effect of delayed-type hypersensitivity augmentation factor on in vitro induction of DTH

We found an antigen-specific factor capable of augmenting delayed-type hypersensitivity (DTH) in the serum of mice sensitized with heterologous erythrocytes to induce a delayed footpad reaction (DFR), or in the culture supernatant of the mixture of sensitized T cells and specific antigens. This factor (DTH augmentation factor; DAF) was confirmed to augment DTH in transferred recipients. In this paper, such an activity of DAF was further investigated using the system with in vitro induction and local transfer of DTH. DAF also augmented the primary in vitro induction of DTH, when spleen cells from mice transferred with the DAF-containing serum 12 hr previously or spleen cells incubated with the DAF-containing serum on ice for 2 hr were cultured with heterologous erythrocytes. DAF acted on the induction phase of DTH and augmented a typical DTH which was dependent on Thy-1-positive T cells. DAF showed antigen specificity, but was not assigned to conventional immunoglobulin. The activity of DAF was detected when nylon-wool nonadherent cells were incubated with DAF prior to the culture of those cells and antigens, but not detected when only nylon-wool adherent cells were incubated with DAF. Thus, DAF exerted its effect through binding to acceptor cells which were included in nylon-wool nonadherent spleen cells from normal mice.     

Antigenic markers on mouse lymphoid cells: origin of cells mediating immunologic memory

Specific antisera were used for the purification of thymus dependent and thymus independent or bursa equivalent lymphoid cells in the mouse. Spleen cells from mice immune to sheep erythrocytes, a thymus dependent antigen, or to E. coli 055:B5 lipopolysaccharide, a thymus independent antigen, were treated with anti-θ (C3H) serum or anti-MBLA serum and complement prior to their adoptive transfer into lethally irradiated syngeneic recipients. Syngeneic thymocytes, bone marrow cells, or spleen cells from nonimmune donors were appropriately added to antiserum treated cells prior to transfer. The secondary response to these antigens was assayed in recipient spleens six days after cell transfer. The kinetics of the primary response to SRBC was investigated as to its effect on origin of specific hyper-reactive T or B lymphoid cells.The adoptive response to CPS originated in the B lymphoid cell population. Immunologic memory to CPS was demonstrated in recipients of immune cells, compared to recipients of normal cells, by a five fold increase in antibody forming cells.The IgM and IgG adoptive immune response to high doses of SRBC depended upon an increased number of specifically hyper-reactive T-lymphoid cells to facilitate cooperation between T and B lymphocytes. High doses of SRBC initially stimulated T cell memory but at 42 days after priming an increased number of specifically hyper-reactive B lymphoid cells were present.     

Avian antigen-binding cells. II. Enrichment of antigen-binding B and T cells.

Antigen-binding B and T cells from chicken spleens were selected on plates of antigen-derived gelatin. Hapten-specific B cells from DNP-immune normal chicken spleens were selected on DNP-gelatin. As much as 165-fold functional enrichment of precursors of anti-DNP antibody-producing cells, as measured in an adoptive transfer system, was achieved. However, the enrichment of DNP-binding cells assessed by rosette formation and autoradiography was no more than 25-fold. HGG-specific T cells from bursectomized agammaglobulinemic chickens immunized with deaggregated HGG were selected on HGG-gelatin. In the fraction adherent to HGG-gelatin, at least a 20-fold enrichment of suppressors of the antibody response to TNP-HGG, as measured by adoptive transfer, was accomplished. In contrast, no more than 6-fold enrichment of HGG-binding cells was detected by autoradiography. Antigen-specific depletion and enrichment of suppressor T cells and of HGG-binding cells occurred in parallel, suggesting that suppressor cells can bind soluble antigen and can be isolated on antigen coupled to a solid support.     

The induction of hapten-specific immunological tolerance and immunity in B lymphocytes. II. Temporal and dose response relationships of tolerance induction in B lymphocytes of various differentiation states.

The induction of TNP-specific B lymphocyte tolerance by TNBS in sources representing various differentiation states was studied in an adoptive cell transfer system. An adoptive assay was utilized in which the delay of immunization with the T-independent antigen TNP-LPS resulted in an enhanced PFC response. TNBS induced tolerance in spleen cells which was independent of T cell activity, was dose dependent, and could be adoptively transferred. While bone marrow and spleen cells were susceptible to tolerogenesis after cell transfer, TNBS treatment of the donor induced unresponsiveness in splenocytes but not marrow cells. The tolerance dose response relationship and the effect of the temporal relationship between cell transfer and tolerogenesis were studied in B lymphocytes from various sources. Adult spleen cells were resistant to tolerance induction late in the adoptive response, and the tolerance induced by TNBS administration 1 hr after cell transfer was dose dependent. Athymic nude spleen cells and adult bone marrow cells displayed similar characteristics while fetal liver cells were somewhat more susceptible to the induction of unresponsiveness. Neonatal spleen cells were rendered tolerant at much lower doses and at any stage of the adoptive response. The hierarchy obtained in these studies in the order of decreasing resistance to tolerance induction is: adult normal and athymic nude spleen and adult bone marrow, fetal liver, and neonatal spleen. This variation in tolerogenesis appears to be due to the maturity of the cell types which may reflect differences in B lymphocyte sub-populations.     

The accessory cell function of murine Peyer's patches

The cellular composition and certain functional characteristics of murine Peyer's patches (PP) were examined and compared with other lymphoid tissues. The composition of PP resembled most closely that of the spleen with the exception of a significant decrease in the number of adherent and phagocytic cells. Very few cells with dendritic morphology could be identified in Peyer's patches. Whole PP (and the nonadherent population) were capable of presenting antigen ovalbumin, human gammaglobulin, and purified protein derivative in a T proliferative assay to sensitized lymph node cells and to an antigen-specific T-cell clone. The antigen-presenting cell in both the spleen and PP was concentrated in the low-density population which floated on 1.080 bovine plasma albumin. However, equal numbers of whole and PP floaters were deficient in their capacity to present antigen compared with similar populations from spleen. Moreover, in PP the antigen-presenting cell appeared in the nonadherent rather than the adherent population as found with other lymphoid tissues. Similar results were obtained with (B6A)F1, CBA, A.TFR-1 and B10.S (12R) mice, suggesting that the inability of adherent cells from PP to present antigen effectively was not genetically determined. Whole and nonadherent PP contained cells capable of stimulating an allogeneic MLR, although again they were generally inferior to those of the spleen when comparable numbers of cells were employed. The adherent population of PP did not elicit an MLR. However, whole PP contained accessory cells needed for mitogen-induced proliferation since passage over nylon-wool columns resulted in a nonadherent fraction which did not respond to concanavalin A or phytohemagglutinin and the addition of adherent peritoneal exudate cells restored the lectin response. The differences noted in the accessory cell function in PP and other lymphoid tissues suggest the possibility that quantitative or qualitative differences in the function of these cells may explain some of the previously observed characteristics of PP, such as the inability to detect a primary antibody response in this tissue. The possibility that the development of gut-associated suppressor cells and their migration to peripheral tissues may be involved in the systemic tolerance that follows oral immunization and that these may be related to numerical and/or functional differences in macrophages or accessory cells is discussed.     

The B cell is the initiating antigen-presenting cell in peripheral lymph nodes

We have examined the role of B cells in antigen presentation in lymph nodes in several ways. We found that mice depleted of B lymphocytes via chronic injection of anti-mu-chain antibody do not mount peripheral lymph node T cell proliferative responses to normally immunogenic doses of antigen. Depletion of B cells by passage of immune lymph node cells over anti-immunoglobulin columns early after immunization depletes antigen-presenting function from draining lymph nodes, and this function can be restored by using B cells or splenic adherent cells to allow the remaining T cells to proliferate. Lymph node B cells present antigen very effectively to lines of antigen-specific T cells. However, unfractionated lymph node cells from anti-mu-treated mice present very poorly, if at all, whereas unfractionated spleen cells from the same mice do present antigen. This is in keeping with our previous finding that helper T cell function in the spleen is normal in B cell-deprived mice. Finally, when mice homozygous for the lymphoproliferative gene lpr are treated chronically with anti-mu-chain antibody, lymphadenopathy is greatly retarded, suggesting a role for B cells in the massive proliferation of T cells in this syndrome. From this analysis, it would appear that the initiating antigen-presenting cell in the lymph node is a B lymphocyte, and that B lymphocytes in lymph nodes may be distinct from those in the spleen. It is of interest that these results also suggest that the lymph node lacks an antigen-presenting cell that is found in the spleen, perhaps the dendritic cell.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

C57BL/6 and AKR mice were treated with hamster erythrocytes (HRBC) in complete Freund's adjuvant (CFA) or incomplete Freund's adjuvant (IFA) and the development of delayed hypersensitivity and antibody production were examined. 1) Delayed hypersensitivity against HRBC antigen, as determined by the peritoneal macrophage disappearance test, was detected in mice sensitized with HRBC in CFA but not in those sensitized with HRBC in IFA. 2) Antibody production against HRBC or hapten TNP after a booster injection of HRBC or trinitrophenylated HRBC (TNP-HRBC) in saline was enhanced by pretreatment with HRBC in CFA or IFA. 3) Delayed hypersensitivity was not detectable after a booster sensitization with HRBC in CFA in mice which had been pretreated with HRBC in IFA 2 weeks earlier. In the mice treated with both HRBC in IFA (day ?21) and in CFA (day ?7), however, an enhanced antibody production against HRBC or TNP was detected after an intravenous injection with HRBC or TNP-HRBC in saline (day 0). These results suggest that sensitized effector lymphocytes in delayed hypersensitivity and helper cells in antibody production may be derived from the same pool of unprimed T cells. The pool of unprimed T cells with a capacity to differentiate into either type of primed T cells may be exhausted after pretreatment with the antigen in IFA, and the primed helper T cells may not be able to differentiate into sensitized lymphocytes even after sensitization with the antigen in CFA, which favors development of delayed hypersensitivity in normal controls.     

Studies on the mechanism of the enhancement of delayed-type hypersensitivity by pertussigen

The potentiation of delayed-type hypersensitivity (DTH) reactions by pertussigen, a protein toxin from Bordetella pertussis, has been studied in adoptive transfer assays. Lymph node or spleen cells from mice treated with or without pertussigen at the time of immunization with protein antigens were transferred to naive, syngeneic recipients that were challenged with antigen. Cells from donors treated with pertussigen had the capacity to transfer vigorous, antigen-specific DTH reactions. Cells from immunized donors not given pertussigen transferred little or no DTH. These results indicate that pertussigen is able to augment DTH reactions by potentiating the antigen reactivity of cell populations in lymphoid organs. The phenotype of the effector cells induced by pertussigen was Thy-1 positive, L3T4 positive, and Ly-2 negative. Cells from mice given pertussigen and an irrelevant antigen had no influence on specific DTH responses, suggesting that pertussigen enhances the activity of the antigen-specific cell type mediating DTH. The effect of pertussigen and of immunization on the lymphocyte subpopulations present in the lymph nodes was studied by analysis of suspensions of lymph node cells by flow cytometry. In immunized and in nonimmune mice, pertussigen increased the ratio of Ly-2-negative:Ly-2-positive T cells, and reduced the overall proportion of B cells. In immunized mice, pertussigen induced a much higher proportion of large dividing cells from 5 days after sensitization onwards. The relevance of these changes in lymphocyte behavior to the development of enhanced and prolonged DTH in mice given pertussigen is discussed.     

Antigen-initiated B lymphocyte differentiation. XIV. Nonspecific effects of antigen stimulation cause proliferation in the "pre-progenitor" subset of primary B cells.

The effect of specific and nonspecific stimuli on the cycle status of subsets of primary B lymphocytes was assessed by preinjecting donor CBA mice 1 to 2 days previously with various substances, and then incubating the isolated spleen cells with high specific activity 3H-TdR before assay. AFC-progenitor activity was assessed as a response to NIP-POL antigen, either by adoptive transfer to irradiated recipients or by cell culture. Previous studies showed these assays reflected the activity of different subsets of B cells, termed "pre-progenitors" (adoptive assay) and "direct progenitors" (culture assay). Most functional primary B cells, whether assayed in culture or by adoptive transfer, were not initially in rapid cell cycle in normal adult mice. However, nonspecific stimulation for 1 day caused NIP-specific adoptive transfer IgM AFC-progenitors to enter rapid cell cycle. This effect was independent of T cells and not related to the antigenicity of the stimulus: particulate peritoneal irritants were the most effective stimulants. In contrast to adoptive transfer results. AFC-progenitors assayed in cell culture were unaffected by nonspecific stimuli, but were activated into cell cycle by specific antigen.     

Transfer of immunity to Babesia microti of human origin using T lymphocytes in mice

Lymph node and spleen cells from mice infected with Babesia microti of human origin developed the ability to transfer adoptive immunity to naive mice within 25 days after infection. This protective activity was greater in cells obtained at 32 days than in cells obtained at 25 days postinfection and remained stable up to 52 days postinfection. Recipients of lymph node cells and spleen cells displayed similar peak parasitemias although 2 days after peak parasitemia, immune spleen cell recipients had significantly lower parasitemias than immune lymph node cell recipients. Strong protective activity was demonstrated when cells were transferred 1 day postinfection, while equal numbers of cells, transferred 3 days postinfection did not confer significant protection over nonimmune cells. There was also a suggestion that the number of immune spleen cells necessary for significant protection was directly related to the number of parasites inoculated. The subpopulation of lymphocytes responsible for the transfer of adoptive immunity to B. microti of human origin was then studied in BALB/c mice depleted of T lymphocytes by thymectomy and lethal irradiation. One day after infection with B. microti, T-cell-depleted mice were given complement-treated immune spleen cells, anti-θ serum-treated immune spleen cells, nonimmune spleen cells, or no cells. Similar experiments were performed comparing the effects of anti-immunoglobulin serum-treated and unfractionated immune spleen cells on B. microti parasitemia. Treatment with anti-θ serum abrogated the protective activity of immune spleen cells while anti-immunoglobulin serum treatment had no effect. These results suggest that immunologic memory of B. microti in BALB/c mice is modulated by T rather than B lymphocytes.     

Generation in vivo of non-T suppressor cells with the use of anti-allotype antibody

Anti-Igh-1b antiserum induced allotype-specific suppression of adult mouse spleen cells in an adoptive transfer system. Suppression of Igh-1b anti-sheep red blood cell plaque-forming cells was measured as late as 4 wk after the injection of allotype heterozygous (Igha/b) spleen cells, antiserum, and sheep red blood cells. Suppression was maintained on retransfer of the allotype-suppressed spleen cells to further irradiated recipients in the absence of additional exogenous anti-allotype antibody. Mixing experiments were performed to test the putative inhibitory effects of allotype-suppressed spleen cells from the first adoptive transfer (stage I) on the antibody response of normal spleen cells in a second adoptive transfer (stage II). No suppression was observed by using unfractionated stage I spleen cells. In contrast, when these allotype-suppressed spleen cells were depleted of T cells, they strongly inhibited the antibody production of admixed normal spleen cells in stage II. This inhibitory activity of antibody-induced stage I spleen cells was directed primarily toward the target allotype, but some suppression of the Igh-1a plaque-forming cell response and total IgG production also occurred. Although removal of adherent cells did not affect the inhibitory activity of allotype-suppressed spleen cells from stage I, removal of Ig+ cells completely abrogated the inhibitory activity. These results suggest that antibody-induced regulatory B cells may play a role in maintaining long term allotype suppression.     

In vivo and in vitro effects of monoclonal antibody to Ly antigens on immunity to infection

Injection of CBA mice with Brucella abortus strain 19 leads to chronic infection during which both cell-mediated immunity (delayed hypersensitivity and macrophage activation) and antibody production occur. Protection was efficiently transferred to naive mice using spleen cells from mice infected 5 or 12 weeks earlier. Selective lysis in vitro of these cells by antibody to cell surface antigens showed that Thy-1⁺ Ly-1⁺2⁺ T lymphocytes were required for transfer. Treatment with anti-Ia serum neither suppressed nor enhanced adoptive transfer. Thus Ia⁺ B lymphocytes were not required, and Ia⁺ suppressor T cells were not active in the response. Three injections per week of anti-Ly-1 monoclonal antibody beginning 5 days before infection led to a 10-fold increase in bacterial numbers 25 days after infection when acquired immunity was well established in untreated mice. The delayed hypersensitivity response was unaffected. In addition cells from these in vivo treated mice were unable to transfer resistance. Beginning the treatment on the day of infection abolished the IgG antibody response without affecting bacterial numbers. The studies emphasize the unique role of Ly-1⁺2⁺ T cells in immunity to Brucella and indicate the usefulness of these techniques in dissecting out those components of the immune response which contribute to recovery from infection.