Cell transfer studies in cyclophosphamide-induced tolerance

Thymectomized, irradiated adult CBA mice were restored with various combinations of bone marrow and thymus cells from nontolerant animals and from animals made tolerant to sheep erythrocytes or to hemocyanin with the drug cyclophosphamide. Mice reconstituted with tolerant marrow and thymus responded as well as those that received nontolerant cells. Thus it is concluded that the tolerant state of the transferred marrow and thymus cells is not a significant factor in the tolerant state of the recipient, and that antigenic diversity is restored in the interaction and proliferation of bone marrow and thymus cells that follow transfer.Thymectomized irradiated mice restored with thymocytes, in contrast to unoperated animals, require multiple antigen injections to demonstrate comparable immune response, but develop tolerance normally when treated with cyclophosphamide and antigen. Reconstitution with tolerant marrow and thymus cells resembles the recovery of immune responsiveness seen after lethal irradiation of tolerant mice; in both instances a complete breakdown of immunological tolerance is observed.     

Studies on the maturation of immune responsiveness in the mouse. II. Role of the spleen.

Experiments were designed to investigate the role of the spleen in the development of the murine immune system. By using mice splenectomized within 24 hr of birth, as well as mice with a hereditary, congenital absence of the spleen, the primary immune response to sheep erythrocytes was examined. The immunocompetence of lymph node cells from spleenless or control mice was assessed in vitro, in organ and in cell suspension cultures, and in vivo, by transfer into lethally irradiated syngeneic recipients followed by antigenic stimulation. The immunologic capacities of thymus and bone marrow cells were similarly tested by injection separately or in combination into irradiated syngeneic mice. Lymph node cells from spleenless animals appeared fully competent both in vitro and in transfer experiments. Neither neonatal splenectomy nor congenital absence of the spleen significantly reduced the capacity of bone marrow or thymus cells to participate in the immune response to sheep erythrocytes.     

The migration of lymphocytes into rat popliteal lymph nodes during antigenic promotion or competition between heterologous erythrocytes

The injection of chicken and sheep red blood cells (CRBC and SRBC) into rat popliteal lymph nodes either together or sequentially 2, 4, 6, or 8 days apart resulted in an enhanced immune response when the second antigen was injected 2 or 4 days after the injection of the first antigen (antigenic promotion) or a suppressed immune response when the second antigen was injected 6 days after the injection of the first antigen (antigenic competition). The immune response to either antigen was dependent upon the time of administration of the second antigen with respect to the first antigen. Lymphocyte migration into antigenically stimulated lymph nodes was greater when the two antigens were injected sequentially rather than together. Further, the migration of lymphocytes into the lymph node was enhanced when the second antigen was injected during the inductive or suppressive phase of the immune response to the first antigen (CRBC) regardless of whether the same (CRBC) or an antigenically unrelated antigen (SRBC) was used as the second antigen. While antigenic promotion may in part be explained by the increased rate at which lymphocytes migrate into lymph nodes, lymphocyte migration is also enhanced during antigenic competition. This suggests that while suppressor cells/factors may regulate the effector phase of an immune response they do not directly modulate the migration of blood-borne lymphocytes into the lymph node.     

Immunocompetent cells in the chicken. II. Synergism between thymus cells and either bursa or bone marrow cells in the humoral immune response to sheep erythrocytes

Newly hatched F₁ hybrid chicks isogenic for the strong B histocompatibility locus were rendered immunologically incompetent by cyclophosphamide treatment and x-irradiation. They were then injected intravenously with thymus, bone marrow, or bursa cells together with sheep erythrocytes (SE) and received another iv injection of SE 3 days later. Splenic plaque-forming cells (PFC) and serum hemagglutinins were assayed 7 days after transfer. At donor ages of 14–26 days, cells from thymus (T) and bone marrow (BM) showed synergism when injected together, as indicated by a significantly higher geometric mean of PFC per recipient spleen in the BM + T group than in the BM group. The response of the T group was extremely low. With thymus and bursa cells from 6- to 28-day-old donors, significant synergism was demonstrated in 3 of 9 individual experiments. However, almost all the other 6 experiments showed marked differences in the same direction, and the combined probability for all experiments was < 0.001. The most striking demonstration of thymus + bursa synergism was made in 2 experiments using 1-week-old donors. Bone marrow cells from 1-week-old donors failed to cooperate with thymus, as did BM cells from older bursectomized agammaglobulinemic donors. This suggests that B cells from bone marrow originate in the bursa. Thymus-bursa cooperation was somewhat difficult to demonstrate in individual experiments using donors over 1 week of age, owing to the occurrence of some responses with bursal cells alone and to variability of response within bursa or bursa + thymus recipient groups. Synergism between thymus and bursa cells was more consistently demonstrable when irradiated normal spleen or low doses of bone marrow cells were added. These additions led to an increased response and a lowered coefficient of variation in the thymus + bursa recipient groups. The ‘third’ cell type needed for optimal response by the thymus and bursa cells together was tentatively identified as a macrophage.     

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.     

Studies on antigenic competition. V. Evidence for the involvement of a thymic-derived cortisone-sensitive cell in the mediation of antigenic competition

Animals depleted of lymphoid subpopulations by neonatal thymectomy, by adult thymectomy, irradiation, and bone marrow reconstitution, or by hydrocortisone treatment did not exhibit antigenic competition. In contrast, injection of anti-lymphocyte serum, while depressing the magnitude of the immune response, did not effect antigenic competition. It is concluded that a thymic-dependent cortisone-sensitive cell population is involved in the initiation of antigenic competition.     

Effect of fibroblasts from monolayer cultures of hematopoietic and lymphoid tissue on the immune response in vitro]

Stromal fibroblasts from the monolayer cultures of human bone marrow, guinea pig bone marrow, spleen, thymus and peripheral blood suppressed the response of the plagueforming cells against sheep erythrocytes in the suspension cultures of mouse spleen cells. Combined cultivation of 20 X 10(6) fibroblasts from all the mentioned sources led to complete suppression of the immune response. This suppression was less in mice immunized three days before the spleen cell explantation into the suspension cultures and was absent entirely in case the pre-immunization of spleen cell donors was accomplished nine days before the explantation.     

A bicellular mechanism in the immune response to chemically defined antigens. 3. Interaction of thymus and bone marrow-derived cells

The role of thymus and bone marrow-derived cells in the in vitro response to the dinitrophenyl (DNP) determinant was studied using the millipore filter well technique for spleen organ cultures. Antibodies to DNP were assayed by the technique of inactivation of DNP-coupled T-4 bacteriophage. It was found that spleens of mice total-body irradiated at 750 R, treated with bone marrow and thymus cells after exposure and immunized against rabbit serum albumin (RSA) were able to produce antibodies to DNP when challenged in vitro with DNP-RSA. Such a response was not produced by spleen explants from x-irradiated mice treated with either thymus or bone marrow cells. Neither were antibodies to DNP produced by spleens of animals repopulated with thymus and bone marrow cells, but not immunized with the carrier. This carrier effect was manifested when the irradiated mice were treated with RSA and thymus cells 6–8 days before administration of the bone marrow cells. Yet, such an effect was not observed when the RSA and bone marrow cells were given 6–8 days before injection of the thymus cells. Thus, the thymus-derived cells appear to play the role of cells sensitive to the carrier (RSA), whereas the bone marrow seems to be involved in the production of antibodies.     

Cell surface antigens expressed by subsets of pre-B cells and B cells

A large number of monoclonal antibodies, produced by immunizing rats with mouse pre-B cell lines, have been analyzed for their ability to define cell surface antigens expressed by B cells at early stages of differentiation. Whereas many antibodies recognized antigens on pre-B cell lines, only two clones detected cell surface antigens that were distinguished by their restricted distribution among a panel of continuous cell lines and cells from various tissues. Monoclonal antibody clone AA4.1 recognized a cell surface antigen found on all pre-B lymphomas and on one of three B lymphomas tested. This antigen was found on cells at highest frequency in the bone marrow. Adult spleen and fetal liver also have detectable numbers of AA4.1+ cells. Cells that did not express this antigen include plasmacytomas, two of three B lymphomas, T lymphomas, a stem cell line, adult liver, brain, thymus, and lymph node cells. Clone GF1.2 detected an antigen on some pre-B cell lines, one of three B lymphomas tested, and a small fraction of cells from adult bone marrow, spleen, lymph node, and fetal liver. Plasmacytomas, some pre-B lymphomas, two B lymphomas, T lymphomas, adult liver, brain, and thymus cells were negative. In adult bone marrow, AA4.1 bound to all cytoplasmic IgM+ pre-B cells, whereas GF1.2 detected one-half of these cells. Both antibodies recognized approximately 50% of surface IgM+ (sIgM+) bone marrow cells. A small population of bone marrow cells lacking any detectable Ig (surface or cytoplasmic) also reacted with these antibodies. Depletion of AA4.1 or GF1.2 antigen-bearing cells from bone marrow reduced the ability of bone marrow B cells to respond to LPS by 50 to 65%. Experiments with a cloned pre-B lymphoma demonstrate that AA4.1+ pre-B cells become sIgM+ GF1.2+ B cells after activation with LPS. These antibodies recognize cell surface determinants with restricted distribution among the B lymphocyte lineage because they detect antigens displayed by normal and transformed immature B lymphocytes.     

A comparison of H-2 restriction of helper function using T cells from radiation chimeras and nude mice bearing thymus grafts

T cells from nude chimeras and radiation chimeras were tested for ability to cooperate with B cells of the thymus epithelium strain and B cells of the T-stem-cell strain in nude mice of appropriate strain backgrounds and also in irradiated F₁'s together with bone marrow cells of the two relevant strains (i.e., A-nu ← B or A → A × B chimera T cells were tested in A-nu and B-nu and in irradiated A × B F₁ with A bone marrow cells or B bone marrow cells). Whether the donor chimeras were antigen primed or not, all cells, when tested in nudes, provided help for the T-stem-cell type only. In contrast, in most cases, chimera T cells, tested in irradiated F₁'S, provided help for bone marrow cells of both thymus and T-stem-cell strains. These data indicate the involvement of two helper cell populations and an hypothesis to explain their interaction is presented.     

Antigen-binding cells in central and peripheral lymphoid tissues of the rabbit

The rosette assay was used to study antigen-binding activity by cells in lymphoid tissues of rabbits immunized with sheep red blood cells and in unimmunized controls. Percentages of rosette-forming cells (RFC) observed were compared with those of cells which secreted antibody (plaque-forming cells, PFC) and cells which both bound antigen and secreted antibody. Rosette-forming cells and PFC were shown to be two distinct reactive cell populations. Thus, in the spleen less than 1% of RFC also formed plaques. Immediately following antigen stimulation, the number of RFC in the bone marrow decreased to below detectable limits. After an initial rise, the number of RFC in the appendix declined similarly. In contrast, RFC levels in the spleen rose steadily from the time of immunization. These patterns suggest that bone marrow and appendix may function as a reservoir of antigen-binding cells which are released to other sites following antigenic stimulation. Rosette-forming cells were rarely observed in the thymus. Rosette-inhibition studies using antisera specific for bone marrow-derived cells (anti-B) and thymus-derived cells (anti-T) revealed a markedly greater proportion of T-RFC in the appendix than in the spleen.     

Antigenic competition among different 'O' antigens of Salmonella enterica subspecies enterica serovars during hyperimmunization in pony mares

The present study on antigenic competition among somatic 'O' antigens of different Salmonella groups (A, B, C1, C2, D and E1) in mares revealed that the immune response to most of the antigens was not (A, B, C2) or little (C1, D) affected by antigenic competition. However, E1 group antigen, which induced high antibody titres (Avg. 12967.3) when given alone, produced almost 3.5 log2 lower antibody titres on giving with other antigens, indicating the antigenic competition among some Salmonella group antigens. The antigenic competition varied for different antigens even of the similar chemical nature. Therefore, antigens belonging to different somatic groups should not be given together for the purpose of raising polyvalent serum or for immunization using multivalent Salmonella vaccines prepared from strains of different 'O' groups revealing antigenic competition.     

Hematopoietic differentiation cell surface antigen switching in the bone marrow of different aged chickens

Abstract. Immune cytolysis and immunofluorescence were used to examine chicken fetal antigen CFA) and chicken adult antigen (CAA) expression on the differentiation/maturation series of definitive erythroid cells obtained from the bone marrow of different aged chickens. We found that erythroid cells undergo changes in CFA/CAA antigenic expression dependent on their differentiation/maturation stage as well as the developmental age of the chicken. All differentiation/maturation stages of erythroid cells in the bone marrow of 12 and 18-day-old embryos express CFA only. Erythroblasts obtained from 7-day post-hatched chickens express either CFA or CAA. All three CFA/CAA phenotypes (i.e., CFA, CAA, and CFA + CAA) are observed in subsequent maturation stages, but only the CFA + CAA phenotype is observed in mature erythroid cells in the bone marrow of 7day post-hatched chickens. Erythroblasts from 62 day post-hatched chickens exhibit all three CFA/CAA phenotypes. Cells in the subsequent maturation stages express various CFA, CAA, or CFA + CAA phenotypes resulting in a majority of the mature erythrocytes expressing both CFA and CAA, and a small population of mature erythrocytes expressing CAA only. Erythroblasts from adult chickens express both CFA and CAA; however, CFA is lost during erythroid maturation resulting in mature erythrocytes which express CAA only. These studies indicate that both the erythroid differentiation/maturation stage and the developmental age of the chicken influence CFA and CAA antigenic expression on erythroid cells undergoing cellular differentiation/maturation in the bone marrow.     

Cellular aspects of tolerance. V. The in vivo cooperative role of accessory and thymus derived cells in responsiveness and unresponsiveness of SJL mice

Adult (8-week-old) SJL mice reach a relatively low degree of tolerance when injected with aggregate free rabbit γ-globulin (RGG). To analyze this phenomenon, we first examined indirect plaque-forming responses (PFC) in terms of participation of accessory and thymus-derived cells. Double transfer experiments were used; accessory cells were removed from donor cells by filtration over glasswool and their capacity reduced in recipients by 3 day preirradiation or by horse erythrocyte-mediated blockage. Using this type of experimental arrangement we found that the antibody response to RGG required the cooperation of accessory and thymus-derived cells. The induction of tolerance was affected by the presence of accessory cells. Preirradiated secondary recipients were reconstituted with spleen cells from accessory cell-deprived donors which had received thymus and bone marrow cells. In some experiments, the thymus and bone marrow cells were passed over glasswool. The primary recipients were left untreated or were given tolerogen. A more profound state of tolerance (reduction in plaque forming response) was the consequence of the incapacitation or removal of accessory cells. The magnitude of the reduction in PFC was directly related to the completeness of accessory cell removal and incapacitation. Responsiveness could be restored by administration of irradiated spleen cells as a source of accessory cells. The need for thymus-derived (T) cells in the antibody response was demonstrated by double transfer experiments in which the primary recipient was restored with thymus cells alone, bone marrow cells alone, or with a mixture of cell types.     

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.     

A membrane antigen of rabbit thymus cells

Rabbit cells, bearing a thymus-specific antigen, which we call rabbit thymus lymphocyte antigen (RTLA), could be detected with a suitably absorbed heterologous antiserum (goat). In the presence of complement, the RTLA antiserum lysed more than 95% of thymus cells, 70 ± 6% of lymph node cells, 46 ± 10% of spleen cells and 12 ± 7% of bone marrow cells. The number of direct or indirect hemolytic spleen plaques was not reduced by treatment with RTLA antiserum and complement, but was greatly diminished by an unabsorbed thymus antiserum which killed more than 90% of bone marrow cells. RTLA-bearing subpopulations of spleen cells were characterized by velocity sedimentation analysis and were distinguished from Ig receptor bearing subpopulations. The antiserum concentration could be so adjusted that the cytotoxicity against bone marrow was not manifested, while the cytotoxicity against other cell populations remained unchanged. The latter were identified by thymidine incorporation induced by treatment with antibody directed against rabbit light chain allotype. A small subpopulation of thymus cells did not have RTLA antigen and sedimented with a velocity distinct from that of the peak of RTLA-bearing cells.     

Interrelation of the dynamics of antigen intake into bone marrow and the proliferation of hematopoietic stem cells

As it is previously shown (Tsyrlova et al., 1986), the level of humoral immune response is not only determined by the reaction of peripheral lymphoid system on antigenic effect, but also is bound up with the observed stem blood cell (SBC) proliferation in bone marrow (Frindel et al., 1976, Kozlov et al., 1982). Dynamics of label accumulation in bone marrow was examined when injecting antigen--sheep red blood cells labeled by radioisotope 51Cr, 125I. The peak of label accumulation in bone marrow, accompanied by the increase in proliferative SBC, was observed on the 3rd day after antigen injection. Furthermore in the course of immunization 51Cr labeled macrophage assortment was changed in time in such a way that a greater number of macrophages was accumulated in bone marrow on the 3rd and 4th days in the immunized animals in comparison with the intact ones. The macrophages in bone marrow are likely to take part in antigen uptake and to mediate its effect on SBC proliferation.     

The myelopoietic inducing potential of mouse thymic stromal cells

The thymus has generally been considered as being solely involved in T cell maturation. In this study we have demonstrated that mouse thymic stroma can also support myelopoiesis. Bone marrow from mice treated with 5-fluorouracil was depleted of cells expressing Mac-1, CD4, and CD8 and incubated on lymphocyte-free monolayer cultures of adherent thymic stromal cells. After 7 days there was a marked increase in nonadherent cells, the majority of which were Mac-1+, FcR+, and HSA+. These proliferating bone marrow cells also expressed markers (MTS 17 and MTS 37) found on thymic stromal cells. Such cells were not found in thymic cultures alone, in bone marrow cultured alone, or on control adherent cell monolayers. Supernatants from the cultured thymic stroma, however, were able to induce these cell types in the bone marrow precursor population. Incubation of normal thymocytes with a monolayer of these in vitro cultivated Mac-1+, MTS 17+, MTS 37+ myeloid cells leads to selective phagocytosis of CD4+ CD8+ cells. Hence, this study demonstrates that the thymic adherent cells can induce myelopoiesis in bone marrow-derived precursor cells and provide a form of self-renewal for at least one population of thymic stromal cells. Furthermore, these induced cells are capable of selective phagocytosis of CD4+ CD8+ thymocytes and may provide one mechanism for the selective removal of such cells from the thymus.     

Hematopoietic differentiation cell surface antigen switching in the bone marrow of different aged chickens

Immune cytolysis and immunofluorescence were used to examine chicken fetal antigen CFA) and chicken adult antigen (CAA) expression on the differentiation/maturation series of definitive erythroid cells obtained from the bone marrow of different aged chickens. We found that erythroid cells undergo changes in CFA/CAA antigenic expression dependent on their differentiation/maturation stages as well as the developmental age of the chicken. All differentiation/maturation stages of erythroid cells in the bone marrow of 12 and 18-day-old embryos express CFA only. Erythroblasts obtained from 7-day post-hatched chickens express either CFA or CAA. All three CFA/CAA phenotypes (i.e., CFA, CAA, and CFA + CAA) are observed in subsequent maturation stages, but only the CFA + CAA phenotype is observed in mature erythroid cells in the bone marrow of 7-day post-hatched chickens. Erythroblasts from 62 day post-hatched chickens exhibit all three CFA/CAA phenotypes. Cells in the subsequent maturation stages express various CFA, CAA, or CFA + CAA phenotypes resulting in a majority of the mature erythrocytes expressing both CFA and CAA, and a small population of mature erythrocytes expressing CAA only. Erythroblasts from adult chickens express both CFA and CAA; however, CFA is lost during erythroid maturation resulting in mature erythrocytes which express CAA only. These studies indicate that both the erythroid differentiation/ maturation stage and the developmental age of the chicken influence CFA and CAA antigenic expression on erythroid cells undergoing cellular differentiation/maturation in the bone marrow.     

Expression of differentiation and age-related antigens on chicken erythroleukemia cells transformed by avian erythroblastosis virus (AEV)

Immature circulating chicken red cells express on their surface two antigenic molecules referred to as Im 48 kD and Im 140 kD antigens. The Im 140 kD antigen is not present beyond the erythroblast stage while the expression of Im 48 kD antigenic molecule remains detectable on circulating erythrocytes of embryos and young chickens, but not on erythrocytes of adult animals. In addition to Im 48 kD and Im 140 kD antigens, the avian erythroblastosis virus (AEV)-transformed erythroid cells express two novel high molecular weight (MW) immature antigens referred to as Im 150 kD and Im 160 kD. Since the transformed erythroid cells are apparently blocked at a stage close to the colony-forming units erythrocytic (CFU-E), these molecules might be expressed on these progenitor cells. The age-related antigenic molecules referred to as E1 48 kD and A 40 kD/A 85 kD antigens are detected on erythrocytes of embryos (and young chickens) and adult animals respectively. The E1 48 kD antigen as well as an antigen related to the A 40 kD were also detected on AEV-transformed erythroid cells deriving from both young chicken bone marrow and yolk sac. The presence of an adult antigen on the embryonic cells might well be related to the transformation by AEV, since the yolk sac CFU-E progenitor cells do not bear the adult antigenicity.