Status of T- and B-lymphocytes in long living CBA--F1 (CBA X C57BL/6) chimeras]

Semiallogeneic chimeras were produced by injecting 3 X 10(7) spleen cells of mice CBA (H--2k, Mlsd) to lethally irradiated mice (CBA X C57BL/6)F1. Two days later recipients were given cyclophosphamide (CP), 2 mg per mouse, to prevent death of graft versus host reaction (GVHR). For 1.5--2 months after the creation of chimerism in 23 of 26 mice under study all cells producing antibodies to SRBC were represented by donor cells of H-2 phenotype; 3 mice were partial chimeras. Spontaneous blast transformation in the cultures of chimera spleen did not exceed the control level, and in the mixed lymphocyte culture chimera cells failed to proliferate on addition of irradiated lymphocytes (CBA X C57BL/6) F1. At the same time chimera gave intensive blast transformation to the irradiated lymphocytes of the third line of mice DBA/2 (H--2d, Mlsa). Among the chimera spleen cells no killers capable of destroying target cells of donor or recipient origin were revealed. Similar results were obtained in vivo: chimera cells gave no positive local GVHR after administration to mice (CBA X C57BL/6) F1. Prolonged chimerism was accompanied by a reactivity of donor T-lymphocytes to the recipient transplantation antigens. A blocking factor was revealed in the blood serum of chimeras. The substitution of donor lymphocytes for the recipient cells begins after 3 to 5 months. At the same period donor T-cell population reconstitutes partially the responsiveness to the recipient antigens and the blocking factor disappears from chimeras blood.     

The role of the thymus in the establishment of suppressor cells in liver chimeras.

The role of the thymus in the establishment of specific suppression was studied in an experimental model in which lethally irradiated F1 mice were reconstituted with parental C57BL neonatal liver cells and then challenged with immunocompetent spleen cells syngeneic to the donor. In this model, inhibition of a graft-versus-host response by these spleen cells served as an indication of the establishment of a suppressive state towards syngeneic antigens in the liver chimeras. It was demonstrated that since thymectomy of the chimeras could not prevent the elicitation of a graft-versus-host response by spleen cells, the thymus is essential for the establishment of this specific suppression. Reconstitution of such chimeras with intact thymus grafts of either donor (C57BL) or host (F1) origin led to the inhibition of the graft-versus-host response and to the reappearance of the suppressive state. Removal of the thymus in intact liver chimeras after establishment of a suppressive state did not affect suppression. Thus, it was concluded that the thymus is needed in the chimeras during a critical period in the development of suppression. Once suppression is established, the presence of the thymus is no longer required.     

A study of the mechanism of Con A-induced immunosuppression in vivo

The plaque-forming cell (PFC) response to sheep erythrocytes (SRBC) is suppressed in a dose-related manner when concanavalin A (Con A) is administered intravenously to mice prior to or after immunization with antigen. The magnitude of suppression as well as the duration of the Con A effect greatly depends on the concentration of antigen used for immunization. Although profound suppression of the anti-SRBC PFC response is observed in intact mice pretreated with Con A for 4-24 hr, spleen cells from these mice do not exhibit suppressive activity when transferred into normal recipients or when cotransferred with normal spleen cells into irradiated recipients. Moreover, the cells from Con A-treated mice respond as normal spleen cells to SRBC when transferred alone into irradiated hosts. Suppression of the anti-SRBC PFC is only observed when adoptive hosts of cells from Con A-treated mice are also injected with Con A within 48 hr (but not 72 hr) of cell transfer and immunization. This time course of responsiveness to the suppressive effects of Con A is similar to that observed in normal mice and in irradiated recipients of normal spleen cells. The immune response to SRBC is also suppressed in adoptive hosts of normal spleen cells that are pretreated with Con A 4-24 hr prior to irradiation and cell transfer. Although functionally inactive when transferred into adoptive hosts, spleen cells from mice pretreated with Con A for 4-24 hr can suppress a primary antibody response to SRBC in vitro. The suppressive activity, which cannot be detected in the spleens of mice when the interval between pretreatment and assay is longer than 24 hr, is present in a subpopulation that bears the Thy 1.2 and Lyt 2 phenotype. Taken together the results obtained in in vivo and in vitro functional assays suggest that a suppressor cell population is activated following in vivo treatment with Con A, but that the cells rapidly lose their state of activation when removed from a Con A environment. This phenomenon is in all probability responsible for the failure to demonstrate suppressive activity in the spleens of Con A-treated mice using in vivo functional assays.     

Studies on the mitogen responses of germfree allogeneic chimeras. II. Maturation of two cell types and partial restoration of responsiveness of the short-term chimeras.

Germfree allogeneic bone marrow chimeras (ABMC) were produced by the i.v. injection of approximately 10(7) bone marrow cells from germfree DBA/2 mice into lethally irradiated germfree C3H mice. In the germfree state, the short-term ABMC showed no histologic signs of graft-vs-host reactions (GVHR), yet splenic lymphocytes were unable to respond to PHA, Con A, or SRBC. Attempts to remove responsiveness by the implantation of a DBA/2 thymus under the host kidney capsule also resulted in failure. However, when the donor thymus was enclosed in a cell-impermeable chamber to eliminate a GVH reaction, responsiveness to Con A was restored. The PHA and SRBC responses were unaffected by this treatment. Daily injections of thymosin caused both an increased Con A response and increased numbers of PFC, although the PHA response was again unaffected. Thus, soluble substances from thymic tissue can be used to overcome partially the histocompatibility barrier present in the ABMC that affects at least two different functional cell populations.     

Allotype-specific immunoregulation of autoantibody production by host B cells in chronic graft-versus host disease

A chronic graft-vs-host (GVH) reaction induced in nonautoimmune mice by the transfer of Ia-incompatible spleen cells results in a syndrome that closely resembles SLE in the spectrum of autoantibodies and immunopathology. We have utilized Ia- and Igh-congenic strains to study the immunoregulation of autoantibody-producing B cells in this model. We have found that the autoantibodies are produced almost entirely by the host B cells. The transferred donor B cells contributed neither to the autoimmune response nor to the total serum Ig, with rare exceptions. The donor cell population did, however, exert an Igh allotype-specific immunoregulatory effect on the host B cells. For example, in allotype-heterozygous recipients, the autoantibodies were preferentially made by those host cells that expressed the donor allotype, whereas those host B cells that expressed nondonor allotype were relatively suppressed. In allotype-homozygous recipients, the donor cells frequently suppressed the host IgG2a allotype completely. This suppression sometimes prevented the IgG antichromatin response, although in other cases the response occurred with the use of a different isotype. In a final set of experiments, a chronic GVH reaction was induced in which both the donors and the recipients were Igh allotype heterozygous and yet differed at Ia. In this case, no donor influence on allotype should be expected; yet the IgG2a autoantibodies were clearly skewed toward the b allotype. These results show that host B cells play a unique role in the GVH autoimmune syndrome. In addition, they are immunoregulated in allotype-specific manners, some of which presumably involve interaction with donor T cells.     

Graft versus host-induced immunosuppression: mechanism of depressed T-cell helper function in vitro.

The cellular basis of graft versus host (GVH)-induced immunosuppression was investigated. Results showed that thymus, lymph node, and splenic T cells from normal mice and thymus and lymph node T cells from GVH mice, when cultured on one side of a cell impermeable membrane, restored the plaque-forming cell (PFC) response to sheep erythrocytes of GVH-immunosuppressed spleen cells (GVH-SC) cultured on the other side of the membrane. The restoring ability of T cells present in GVH-SC was inhibited by splenic accessory (A) cells. A direct relationship was shown between the proportion of splenic A cells and the degree of suppression of the PFC response during the first 10 days of the GVH reaction. Normal or GVH A cells reconstituted the PFC response of normal cells and GVH-SC depleted of their A-cell fraction. An optimum ratio of A: nonadherent (NA) cells (1: 10) was required for maximum reconstitution. Larger proportions of A cells inhibited the PFC response. The results suggest that GVH-induced immunosuppression is due, at least in its initial phase, to a depressed T-cell helper function caused by a marked increase of A cells in the spleen.     

Immune competence of splenic lymphocytes following graft-vs-host disease in mouse allogeneic radiation chimeras.

The abnormal immune response of long-term mouse allogeneic chimeras is reflected by qualitative deficiencies in either T or B lymphocytes. The present study was undertaken to determine if a relationship existed between the severity of graft-vs-host disease (GVHD) that these animals had experienced and a functional defect in either the T or B cell population. The in vitro PFC response of chimera spleen cells to sheep red blood cells (SRBC) was evaluated in the presence of normal T or B lymphocytes 4 to 8 months after marrow transplantation and well beyond the GVHD period. In an analysis of several different allogeneic radiation chimeras, our results showed no relationship between the severity of GVHD experienced and the immunologic capacity of either T or B cells. Thus, different chimera combinations showing similar degrees of GVHD were functionally deficient in one or the other of these two cells types or both with no apparent predilection for abnormality in either population. In examining the quantitative in vitro PFC response to sheep RBC by spleen cells from individual chimeras, we found that the number of PFC formed was related to the severity of GVHD experienced by that animal. A general relationship between severity of GVHD and PFC capacity may also exist between chimeras of different genetic combinations. However, this relationship is not precise since gross exceptions occur. Our results, although documenting further the qualitative abnormalities in T and/or B lymphocytes of radiation chimeras, do not reveal the factor or mechanisms by which these cells are made unresponsive. It is suggested that the tolerance-inducing mechanism of these animals, whether it be humoral blocking factors or suppressor cells, is in some way interfering with the collaboration of T and B cells for antibody production.     

The lpr gene is associated with resistance to engraftment by lymphoid but not erythroid stem cells from normal mice

This study demonstrates cell lineage-specific resistance to engraftment involving lymphocytes but not erythrocytes by the spontaneously autoimmune MRL/lpr mouse strain. In these experiments, MRL/lpr mice were lethally irradiated (1000 R) and reconstituted with normal A-Thy bone marrow stem cells. Periodic analysis from 6 wk to 6 mo posttransplantation demonstrated that the T and B cells of these chimeras were derived from the MRL/lpr host. However, in the same A-Thy----MRL/lpr chimeras, erythrocyte repopulation was completely of A-Thy donor origin. In contrast, control MRL/+ (congenic mice that differ from MRL/lpr at the lpr locus and do not develop accelerated autoimmune disease) recipients were successfully repopulated in both the lymphoid and erythroid compartments by the A-Thy donor cells.     

Influence of the thymus extract on the immunological function of animals with experimental diabetes

After immunization with SRBC, the number of plaque-forming cells (PFC) in the spleen of alloxan-diabetic mice, in nondiabetic TIR mice and in alloxan-diabetic TIR mice was significantly decreased as compared with control non-diabetic donors. The ability of lymphocytes from alloxan-diabetic mice to adoptively restore the suppressed immune response of TIR mice, was reduced in comparison with the effect of lymphocytes from normal, nondiabetic donors. Local GVH reaction in nondiabetic rat recipients provoked by lymphocytes from control healthy mice was 5.6 +/- 0.7 mm. Significantly lower rate of local GVH reaction after injection of lymphocytes from diabetic donors was found in diabetic as in nondiabetic recipients as well. Treatment of alloxan-diabetic mice with thymus extract or with insulin, partly restored depressed function of the humoral and cellular system. Treatment of diabetic mice with both thymus extract and insulin, was even more effective in restoring of their immune reactivity. Diabetic condition strongly influenced the function of the immune system. This could be attributed to depletion of T-lymphocytes, changed relations between the lymphocyte subpopulations in diabetic donors, and disturbance of lymphocyte metabolism.     

Modulation of the IgE immune response to BSA by fragments of the antigen. I. Suppression by free fragments and by fragments conjugated to homologous gamma-globulin

Nonimmunogenic peptic fragments of bovine serum albumin (BSA), Fraction Ia, suppressed immune response to BSA in mice. Splenic T lymphocytes from mice treated with these fragments suppressed the anti-DNP response in irradiated mice reconstituted with DNP-BSA-primed cells, indicating carrier-specific suppression. The conjugate of Fraction Ia with mouse γ-globulin (MGG) was found to be an effective suppressive substance but it did not induce suppressor T cells. B cells from mice given Ia-MGG were unresponsive to BSA when transferred to irradiated recipients along with either normal or BSA-primed T cells. Thus, unresponsiveness to BSA was mediated by either T or B lymphocytes, depending whether the inducing substance was a free fragment of the antigen or fragments conjugated to homologous γ-globulin.     

Allogeneic bone marrow transplantation in conventional mice: I. Effect of antibiotic therapy on long term survival of allogeneic chimeras.

In the present communication the beneficial effect of long term antimicrobial treatment with poorly absorbable antiboitics on the survival of allogeneic bone marrow chimeras was investigated. The combination of C57Bl mice as bone marrow donors and CBA/CA mice as irradiated recipients (800 rad) was used because of their strong histoincompatibility on the H-2 loci. All allografted recipients received 10 X 10(6) bone marrow cells. The majority of the recipients, which were rendered gnotobiotic by an antimicrobial treatment, achieved stable long term chimerism. In contrast, the conventional chimeras died from secondary disease within 9 weeks after transplantation. As early as 14 days after allogeneic bone marrow grafting the gnotobiotic recipients tolerated the reassociation with a conventional microflora without a change in the rate of mortality. Bone marrow cells (8 X 10(6) i.v.) and spleen cells (2 X 10(6) i.v.) collected from allogeneic chimeras failed to induce graft-versus-host-reaction (GVH) in a second lethally irradiated host. The data indicate, that the high rate of mortality in murine allogeneic bone marrow chimeras results from delayed GVH-reaction and systemic infection. The marrow graft, once established seems to exert tolerance against the allogeneic host. The pathogenesis of the systemic infection has not yet been worked out. It is assumed that it originates from bacteremia, induced by radiation dependent lesions of the epithelial integrity and defected lymphatic tissue in the gut.     

Graft-vs-host reactions (GVHR) across minor murine histocompatibility barriers. II. Development of natural suppressor cell activity

We explored the immunoincompetence of mice undergoing a chronic graft-vs-host reaction (GVHR) across minor histocompatibility barriers. BALB/c and B10.D2 mice are H-2d and mls b, and differ only with regard to minor histocompatibility antigens (MiHA). A large number of BALB/c mice were unirradiated or were irradiated with 300, 600, or 900 R. They then were injected with 5 X 10(7) spleen cells from either allogeneic B10.D2 or syngeneic BALB/c mice. The spleen cells from these recipient mice were assayed at various times post-irradiation/injection for their proliferative response to Con A and LPS, their ability to suppress the mitogen responses of normal spleen cells, and for the genetic specificity of this suppression. Spleen cells from BALB/c mice that had received 600 or 900 R (but not 0 or 300 R), and allogeneic B10.D2 lymphocytes, became very hyporesponsive to mitogens and became suppressive in vitro by days 7 to 10 post-irradiation/injection. These phenomena persisted for the entire 49 days of the experiment. After an initial period of splenomegaly, the spleens of these mice gradually became depleted of viable lymphocytes. Initial characterization of suppressor cells found in the spleens of GVH mice showed that they were not removed by treatment with anti-Thy-1.2 plus complement. GVH suppressors also were not adherent to plates coated with antiserum directed towards murine Ig. In addition, these cells did not adhere to plastic plates. Thus, we believe that the suppressor cells found in mice undergoing GVHD across MiHA are not mature T cells, B cells, or macrophages, but belong to a class of suppressor cells termed natural suppressor (NS). Genetic analysis of NS cell activity showed that as early as 10 days post-irradiation/injection, NS cells inhibited mitogen responses of all mouse strains tested, the exception being the relative difficulty in suppressing the LPS response of B10.D2 (syngeneic with donor cells). By day 42, this had developed into an almost complete inability to suppress a B10.D2 LPS response, although at this time NS cells were still capable of inhibiting all the other mitogen responses of all strains tested, including the Con A response of B10.D2 spleen cells. Moderate amounts of mitogen unresponsiveness and suppressor activity were seen in the syngeneic groups (BALB/c----BALB/c) but only if recipients received 600 or 900 R. This was a transient phenomenon that was maximal at day 14, and which we believe to be a similar but less severe degree of immunoincompetence when compared with that seen with allogeneic stimulation in the B10.D2----BALB/c GVH model.(ABSTRACT TRUNCATED AT 400 WORDS)     

Induction and suppression of delayed-type hypersensitivity to non-MHC antigens during lethal graft-versus-host reaction.

A delayed-type hypersensitivity reaction (DTH) to non-MHC Ag was detected during a lethal graft-vs-host reaction (GVH) induced by incompatibility for non-MHC Ag alone. In this model, when appropriate doses of B10.D2 bone marrow and lymphoid cells are grafted to irradiated (DBA/2 x B10.D2)F1 recipients, the ensuing GVH, directed against those DBA/2 non-MHC Ag absent from the B10.D2 background, results in virtually 100% mortality in less than 3 mo; donor alloimmunization against the host histocompatibility Ag considerably reduces mortality, and survival rates of 80 to 100% are common. The experiments reported here show that: 1) the cell responsible for DTH induction expresses the CD4+ CD8- phenotype; 2) CD4+ cells likewise seem to play a predominant role in the pathology of lethal GVH in this genetic combination; 3) the alloimmunization protocol that abrogates mortality also abolishes GVH-associated DTH; and 4) this suppressive effect, as shown elsewhere for the protection against mortality, is mediated by CD4- CD8- "double negative" Thy-1+ CD3+ T suppressor cells. Thus, there is a good parallel between lethal GVH and its associated DTH as concerns both induction and suppression of the two phenomena, suggesting that mortality and DTH may represent different manifestations of a common underlying mechanism. Initiation of the effector phase of DTH in the adoptive transfer model seems to be dependent on the presence of a Thy-1+ double-negative cell in the transfer inoculum; the possible relationship of this double-negative cell to the Th-1-type CD4+ DTH-mediating cell recently shown to induce lethal GVH is discussed.     

Studies of the immunological capacity of germ-free mouse radiation chimeras. IV. Cell-mediated immunity

The cell-mediated immune (CMI) response of germ-free mouse radiation chimeras was compared with that of conventional mice. Spleen or thymus cells from chimeric or normal mice were injected intravenously into lethally irradiated, allogeneic hosts. Spleens of the irradiated hosts were assayed for effector cells using the ⁵¹Cr release assay. Spleen cells from syngeneic and allogeneic chimeras and normal mice were equally active in giving rise to effector cells. However, thymus cells from allogeneic chimeras were completely inactive within 9 months post-bone marrow transplant while thymus cells from syngeneic chimeras and normal mice still remained functional. Although allogeneic chimeras contain cells potentially reactive toward host antigens, cells cytotoxic to host antigens were not detectable. In addition, these studies indicate the helper cell and effector cell, both associated with T-derived lymphocytes, represent two different populations.     

Studies of the immunological capacity of germ-free mouse radiation chimeras: I. Chimerism and humoral immune response

The genetic origin of both the functional lymphoid cell and progenitor cell populations of germ-free mouse radiation chimeras was assessed by indirect immunofluorescence (IIF), anti-H-2 cytotoxicity, and survival of lethally x-irradiated secondary recipients of chimera cell populations. These studies demonstrated that germ free C3H/He mice given 1000 R and 10⁷ DBA/2 bone marrow cells express H-2 antigens on their lymphoid and bone marrow cell populations characteristic of the DBA/2 donor. These cells persist for at least 14 months postirradiation and bone marrow transplantation. However, these allogeneic mouse radiation chimeras have a reduced humoral immune response to sheep erythrocytes (SRBC). This decreased humoral immune capacity as assessed by kinetic studies of the spleen plaque-forming cell (PFC) response is present throughout the life span of the chimera. The γ₁ PFC response shows extreme depression. The reduced humoral immune responsiveness to the thymusdependent SRBC antigen is considered to be due to the absence or malfunctioning of a thymocyte population.     

Immune dysfunction associated with graft-vs-host reaction in mice transplanted across minor histocompatibility barriers. II. Reversible defect in T-dependent antibody responses

B cell and Th cell functions were assessed in mice undergoing a graft-vs-host reaction (GvHR) in response to minor histocompatibility Ag by using the plaque-forming cell (PFC) response to the T-independent Ag TNP-Brucella abortus and the T-dependent Ag TNP-SRBC. Bone marrow plus spleen cells from B10.D2 mice were transplanted into lethally irradiated B10.D2 (syngeneic recipient) or H-2d-compatible BALB/c (allogeneic recipient) to produce a chronic form of GvHR. BALB/c recipients of an allogeneic transplant demonstrated a marked and proportional lymphoid depletion of the spleen with normal percentages of B cells, T cells, and CD4+ and CD8+ T cell subsets. Mice with GvHR made normal numbers of PFC/10(5) spleen cells in response to the T-independent Ag, but a significantly depressed number of PFC/10(5) spleen cells to the T-dependent Ag compared with normal B10.D2 mice and with irradiated B10.D2 recipients of syngeneic B10.D2 marrow plus spleen cells. Mice undergoing the minor Ag GvHR made significantly larger numbers of PFC/10(5) spleen cells after secondary immunization with TNP-SRBC compared with controls. In vitro assays demonstrated that B cells from mice with GvHR responded to T help from normal B10.D2 mice and that T cells from mice with GvHR provided help to normal B cells after in vivo immunization. These data demonstrate that radiation chimeras with GvHR in response to minor histocompatibility Ag have relatively normal B cell function and an apparent defect in T helper cell function that is reversible by immunization with appropriate Ag.     

Graft-vs-host reactions (GVHR) across minor murine histocompatibility barriers. I. Impairment of mitogen responses and suppressor phenomena

In our laboratory, we have developed a murine model to examine GVHD across minor histocompatibility antigens. In our model, GVHD is induced by injecting B10.D2 spleen cells into irradiated BALB/c recipients. Seven to 10 days after irradiation and injection of cells, there are significant changes in cell function in the recipient spleens. In the B10.D2----BALB/c (600 rad) model, recipient spleen cells are profoundly unresponsive to Con A and LPS stimulation but show increased B cell activity measured by Staphylococcus aureus protein A plaque-forming activity. Spleen cells from such GVH mice profoundly suppress the mitogenic responses of normal BALB/c or B10.D2 spleen cells to Con A and LPS. The degree of impairment of the mitogenic response and the ability to suppress normal cells is proportional to the dose of cells used to induce GVH reactions. Both the inability to respond to mitogens and the capacity to suppress are also related to the dose of irradiation given to the recipients. In addition, immunosuppression across minor histocompatibility antigens shows an unevenhandedness. If we inject parental B10.D2 or BALB/c cells into F1 recipients (P----F1), there is greater inhibition of mitogenic responses when B10.D2 parental cells are given than when BALB/c cells are given to the irradiated F1 recipients. These experiments show that significant immunosuppression occurs during GVH reactions across minor histocompatibility barriers. The degree of suppression varies according to the dose of cells used to induce GVH, the dose of irradiation to the recipient and the "strength" of the GVH recognition system. Such experiments provide models for GVH disease seen in humans who receive treatment for leukemia or other diseases that involves recipient irradiation and infusion of HLA-identical bone marrow.     

Role of cytotoxic T lymphocytes in the prevention of lupus-like disease occurring in a murine model of graft-vs-host disease

The inoculation of B6D2F1 mice with T lymphocytes from the C57BL/6 parental strain induces an "immunosuppressive" graft-vs-host reaction (B6 GVH), whereas inoculation of T cells from the other, DBA/2 parental strain induces an "immunostimulatory" GVH reaction and a lupus-like disease (DBA GVH). The present study compares cytotoxic T lymphocyte (CTL) function in the spleens of these GVH mice as well as differences in the donor inoculum that could account for these different types of GVH. We observed that the B6 GVH induces an immunodeficiency that encompasses CTL precursors (and possibly T helper cells) and results in suppressor cells that abrogate responses to both trinitrophenyl (TNP)-modified self and third party alloantigens. In contrast, the DBA GVH induces only a T helper cell immunodeficiency and results in suppressor cells selective for class II restricted L3T4+ T helper cells. Chimeric T cells were detected in both types of GVH. In the B6 GVH both L3T4+ and Lyt-2+ donor cells were observed, although Lyt-2+ cells predominated. In the DBA GVH, donor T cells were almost exclusively of the L3T4+ phenotype. The lack of appreciable donor Lyt-2+ cells in the DBA GVH can be explained by a defect in the DBA donor inoculum manifested by a naturally occurring two-fold reduction in Lyt-2+ cell numbers as well as a nine-fold reduction in CTL precursors with anti-F1 specificity. T cells in the DBA inoculum, therefore, are predominantly L3T4+. A similar defect induced in B6 donor cells by anti-Lyt2 antibody and complement not only converted the suppressive GVH to a stimulatory GVH, as measured by anti-DNA antibodies, but also resulted in a T cell immune deficiency characteristic of the DBA GVH, i.e., a selective loss of the TNP-self CTL response. Thus the presence or absence of adequate numbers of functioning Lyt-2+ cells in the donor inoculum is correlated with the development of either a suppressive or stimulatory GVH, respectively. That donor Lyt-2+ cells mediate a suppressive GVH through cytolytic mechanisms is evidenced by greater than 70% reduction in B6 GVH spleen cell numbers and readily demonstrable anti-F1 CTL activity by these spleen cells despite an inability to generate anti-allogeneic or anti-TNP self CTL activity even in the presence of added T helper factors.(ABSTRACT TRUNCATED AT 400 WORDS)     

Fate of H2-activated T lymphocytes in syngeneic hosts. III. Differentiation into long-lived recirculating memory cells.

Memory to H2 determinants was studied with an adoptive transfer system using a population of H2-activated blast T cells (T.TDL) obtained from thoracic duct lymph of irradiated F₁ hybrid mice injected with parental strain T cells. CBA T.TDL activated either to DBA/2 or C57BL determinants were transferred to syngeneic “B” mice. Thoracic duct lymphocytes (TDL) were obtained from the recipients 4–6 weeks later and tested for their capacity to produce (a) a graft-versus-host (GVH) reaction, (b) a mixed lymphocyte reaction (MLR) (measured by an in vivo technique) and (c) allograft rejection (suppression of the growth of allogeneic tumour cells in vivo). Control experiments involved testing the function of TDL obtained from “B” mice preinjected with TDL or no cells.TDL from “B” mice injected with TDL (passaged TDL) gave strong MLR and GVH reactions to both DBA/2 and C57BL determinants. Passaged T.TDL activated to C57BL antigens gave intermediate MLR and GVH reactions to the specific (C57BL) determinants but only very low responses to third-party (DBA/2) determinants; reciprocal results were obtained with passaged T.TDL activated to DBA/2 determinants. TDL from “B” mice given no cells failed to respond to either set of determinants.Since the responses by the passaged T.TDL did not exceed those by passaged TDL there was no evidence that adoptive transfer of T.TDL had conferred to the recipients a state of memory to either MLR or GVH determinants. Adoptive transfer did, however, lead to qualitative changes in the properties of T.TDL since, before transfer, they were unable to evoke GVH reactions or produce an MLR of normal kinetics.Passaged T.TDL were far superior to passaged TDL at suppressing the growth of allogeneic tumour cells. The protection was specific since protection against DBA/2 tumour cells was, cell for cell, 5–10 fold more effective with passaged T.TDL activated to DBA/2 determinants than with cells activated to C57BL determinants. No protection was observed with cells treated with anti-θ serum. The protective cells appeared to be precursors of effector cells rather than effector cells per se since they failed to lyse the tumour cells in vitro. These data suggest therefore that the descendants of T.TDL which survived after transfer to “B” mice were highly enriched in long-lived recirculating T lymphocytes reactive to determinants expressed by specific tumour allografts.     

Graft-versus-host induced immunosuppression: depressed T cell helper function in vitro.

The cause of graft-versus-host (GVH) induced suppression of the plaque forming cell (PFC) response to sheep erythrocytes (SRBC) was investigated by in vitro restoration experiments employing a double compartment culture vessel. The two culture compartments were separated by a cell impermeable membrane. Restoring cells were placed in one chamber and responding GVH spleen cells plus SRBC were placed in the other chamber. It was demonstrated that thymus, lymph node, and spleen cells restored the PFC response whereas bone marrow cells did not. Treatment of the restoring cells with anti-theta serum plus complement abrogated restoration. Supernatants obtained from antigen free cell cultures restored nearly as well as whole cell suspensions. The degree of restoration was not increased by allogeneic or xenogeneic antigenic stimulation of the restoring cells. Thymus and lymphoid cells obtained from animals experiencing a GVH reaction restored as well as normal cells, however spleen cells were unable to restore by day 5 post-GVH induction. The results suggest that GVH induced immunosuppression of the PFC response is due, at least in part, to a depressed T cell factor production by splenic T cells.