Mechanisms of antibody formation: I. Early in vivo proliferation of mouse spleen T cells as an initial step in antibody formation

Spleen cultures prepared from mice injected 24 hr earlier with 2 × 10⁶?2 × 10⁸ sRBC and challenged in vitro with sRBC produced 10 times more anti-sRBC IgM PFC than cultures prepared from uninjected mice. The effect was specific for the particular species of foreign RBC injected in vivo. In vitro responses to TNP were also increased in spleen cultures prepared from animals injected 24 or 12 hr earlier with carrier RBC alone, directly implicating carrier-specific T cells in this process. Similar enhancements of PFC formation occurred in cultures prepared from mice which had been injected with sRBC 24 and 48 hr earlier, but which were exposed to lethal irradiation at 1 hr after injection of antigen, if their spleens were shielded extracorporeally during irradiation. This finding indicated that in vivo recruitment of antigen-reactive extrasplenic X-ray-sensitive cells from the circulating lymphocyte pool by the spleen could not account for the observed enhancement.Proliferation in the spleen of antigen-reactive T cells, commencing 12–20 hr after the administration of antigen, was demonstrated by the tritiated thymidine pulse technique. An 8-hr hot-pulse given to spleen cell cultures from normal animals at 20 hr after in vitro challenge with antigen did not affect the rate of generation of IgM-producing cells; however, administration of a similar pulse to cultures which were initiated at 12 or at 20 hr after the in vivo injection of sRBC eliminated the enhanced generation of PFC and delayed the in vitro response to sRBC by 24 hr.Spleen cell cultures were prepared from mice which had been injected in vivo with sRBC at 12, 20, and 70 hr earlier, and 8- to 10-hr hot pulses were given immediately after initiation of the cultures. The cultures were then challenged with sRBC-TNP; antibody responses to TNP were greatly reduced in hot-pulsed cultures prepared from mice injected in vivo with carrier RBC at 12 or 20 hr prior to initiation of the cultures. In contrast, antibody responses to TNP observed in hot-pulsed cultures prepared from mice which had been injected with carrier RBC at 70 hr prior to initiation of the cultures were generally similar to those of nonpulsed 70 hr control cultures. This result suggests that the onset of T helper cell proliferation begins within 12–20 hr after injection of antigen, but subsides in vivo within 70 hr. By that time, the antigen-reactive T cells have already differentiated to perform their helper function.In spite of the triggering of T-cell proliferation during the first 24 hr after injection of antigen, spleen cell cultures prepared from mice which had been injected 24 hr earlier in vivo with 2 × 10⁸ sRBC produced only minimal numbers of anti-sRBC PFC if no antigen was added to the cultures. The presence of unprocessed antigen thus appears to be a requirement for B-cell proliferation in vitro, even after T-cell division has been triggered. This finding is consistent with earlier suggestions that the function of “helper” T cells may not be limited to passive transport of antigenic determinants to B cells. Evidence is also presented to support the contention that the antigen-reactive T cell involved in this process may have to undergo cell division in order to develop “helper” capacity.     

Subpopulations of splenic T and B lymphocytes producing and regulating leukocyte adherence inhibition factor

Picryl chloride induces contact hypersensitivity in mice, accompanied by spleen cell sensitization that is demonstrable in vitro by specific antigen-induced formation of leukocyte adherence inhibition factor (LAIF). This cellular activity was detected only up to 7 days after sensitization; thereafter the spleen cells appeared to be unreactive with the antigen. The cells were still normally reactive with the mitogen concanavalin A. Antigen reactivity of such “late” cells was restored by passage through a glass-bead column (provided resulting nonadherent cells were reconstituted with normal macrophages), and the restored reactivity was again suppressed by the eluted glass-bead-adherent cells. Suppression was antigen specific. Separation of T and B lymphocytes by affinity chromatography, after glass-bead treatment of sensitized spleen cells, showed that two subpopulations of B cells—those responsible for producing LAIF as well as those suppressing LAIF production by T cells—were glassbead adherent. This was extended by showing directly with anti-Thy-1.2 serum that B cells producing LAIF and suppressor T cells were glass adherent. Thus two suppressive cell populations, and the B cell producing LAIF, were glass adherent while the T-cell LAIF producer was not. Tests for adoptive transfer of cutaneous hypersensitivity in vivo demonstrated the relevance of many of the above observations to conditions in the whole animal. “Late” spleen cells from sensitized mice could not transfer hypersensitivity but this property was restored by glass-bead passage. The eluted adherent cells suppressed transfer. Both adoptive transfer and its suppression were antigen specific.     

Plasmodium berghei: Reduction of the mouse's specific lymphoproliferative response in relation to corticosterone and pregnancy

Spleen cells from mice immune to Plasmodium berghei exhibited a significantly increased in vitro proliferative response to parasitized reticulocytes compared to spleen cells from normal mice. The specific response to malaria antigen was decreased in spleen cells from pregnant immune mice in contrast to the nonspecific response to the mitogen phytohemagglutinin. Addition of mouse serum to spleen cell cultures of immune mice depressed both the phytohemagglutinin and the specific proliferative response, whereas serum of pregnant mice exerted an even stronger inhibition than serum of nonpregnant mice. Charcoal adsorption of mouse sera for the elimination of steroid hormones removed the serum dependent immunosuppression from normal as well as pregnant serum. Corticosterone added to the spleen cell cultures depressed also the proliferative response. These findings demonstrate that the response to malaria antigen is decreased in immune mice during pregnancy. The possible effect of serum corticosterone on the depression of the immune response is discussed.     

Immune unresponsiveness of spleen cells from lipopolysaccharide-sensitized mice to particulate thymus-dependent antigens. II. Evidence for an abortive cooperation between T lymphocytes and antigen-presenting cells

LPS-induced immune unresponsiveness has been shown to be related to an impaired production of differentiation signal factor(s). The mechanism underlying this phenomenon was analyzed. The in vitro anti-SRBC response of spleen cells from normal mice was not suppressed by addition of LPS-treated spleen cells, ruling out a possible implication of active suppressor cells. Immune responsiveness concomitant with TRF production was restored in LPS-sensitized cells upon addition of 2-ME. The role of adherent and nonadherent cells was also investigated; both cell populations from LPS-treated mice were able to collaborate with their normal counterparts showing that the defective TRF production results from synergistic effects of LPS-induced alterations concerning both adherent and T-cell populations.     

Comparison of T suppressor factors from tumour-bearing mice and mice immunized with a monoclonal anti-idiotypic antibody

Summary Certain dosage schedules of a monoclonal antiidiotypic antibody (related to a murine bladder carcinoma) were found to induce suppressor factor production by syngeneic mice. This suppressor factor resembled the factor from tumour-bearing mice with respect to idiotype specificity, possession of molecular markers (reactive with anti-IJ and B16G antibodies) and production by Lyt2⁺IJ⁺ T cells in spleen cell cultures. The two factors differed with respect to Igh restriction in an in vitro assay (leucocyte adherence inhibition) and ability to suppress the induction of delayed-type hypersensitivity to tumour antigen.     

Interferon inhibition of the primary in vitro antibody response to a thymus-independent antigen

Partially purified and crude mouse L cell interferon preparations inhibited the in vitro plaque-forming cell (PFC) response of mouse C57B1/6 spleen cells to the T-cell independent lipopolysaccharide antigen of Escherichia coli 0127. PFC responses of 5-day cultures were inhibited approximately 70–90% by 100–200 NIH reference units of interferon/culture. A similar inhibitory effect was obtained with spleen cells from athymic (nude) mice homozygous for the nu/nu allele. Spleen cultures depleted of adherent cells were also inhibited in their anti-0127 PFC response by interferon. Interferon, then, appears capable of inhibiting the PFC response to E. coli 0127 via direct action on B cells. Heating experiments along with the use of interferon preparations of different specific activities suggest that the inhibition was due to the interferon in the preparations.     

Dissociation of in vitro lymphocyte transformation from production of a mononuclear leucocyte chemotactic factor in agammaglobulinemic chickens

Cultures of splenic and peripheral lymphocytes from normal chickens immunized intravenously with Brucella abortus organisms were stimulated by this antigen to incorporate significantly greater amounts of ³H-thymidine and ¹⁴C-leucine than lymphocytes from unimmunized animals. Lymphocytes from immunized agammaglobulinemic chickens were unresponsive to Brucella. This defect could not be corrected by the addition of either normal nonimmune or irradiated normal immune spleen cells to cultures of ag chicken lymphocytes which suggests that normally B cells transform in vitro in response to this antigen. In contrast, cultured peripheral blood leucocytes from both immunized normal and agammaglobulinemic chickens produce significantly more monocyte chemotactic factor in response to Brucella than leucocytes from nonimmune chickens. This indicates that the production of this mediator is a B cell independent function and suggests that T cells are the producers of this lymphokine.     

Identification of a novel antigen cross‐presenting cell type in spleen

Antigen-presenting cells (APC), like dendritic cells (DC), are essential for T-cell activation, leading to immunity or tolerance. Multiple DC subsets each play a unique role in the immune response. Here, a novel splenic dendritic-like APC has been characterized in mice that has immune function and cell surface phenotype distinct from other, described DC subsets. These were identified as a cell type continuously produced in spleen long-term cultures (LTC) and have an in vivo equivalent cell type in mice, namely ‘L-DC’. This study characterizes LTC-DC in terms of marker phenotype and function, and compares them with L-DC and other known splenic DC and myeloid subsets. L-DC display a myeloid dendritic-like phenotype equivalent to LTC-DC as CD11c^loCD11b^hiMHC-II⁻CD8α⁻ cells, distinct by high accessibility and endocytic capacity for blood-borne antigen. Both LTC-DC and L-DC have strong antigen cross-presentation ability leading to strong activation of CD8⁺ T cells, particularly after exposure to lipopolysaccharide. However, they have weak ability to stimulate CD4⁺ T cells in antigen-specific responses. Evidence is presented here for a novel DC type produced by in vitro haematopoiesis which has distinct antigen-presenting potential and reflects a DC subset present also in vivo in spleen.     

Augmentation of specifici immune response against syngeneic SV40-induced tumor-associated antigens by splenectomy.

Splenectomy before immunization of mice with syngeneic SV40-transformed cells markedly augmented the specific cell-mediated immune response against the corresponding tumor-associated antigens as measured by an in vitro⁵¹Cr-release assay and an in vivo tumor-cell neutralization assay. This augmentation was not dependent on the time interval between splenectomy and antigen immunization. By performing reconstitution experiments, it was found that thymus-derived cells in spleens of normal syngeneic mice abolished the splenectomy-induced augmentation of immune response. It is inferred that the resident population which normally operates in spleen-intact mice to suppress the specific immune response against SV40-induced tumor-associated antigens is T-cell.     

The immunoregulatory role of bone marrow. I. Suppression of the induction of antibody responses to T-dependent and T-independent antigens by cells in the bone marrow.

Bone marrow cells (BMC) from normal mice suppressed the in vitro IgM, but not the IgG, antibody (Ab) response of spleen cells. BMC were inhibitory only when added during the first 24 hr of culture, and inhibition was not due to an induced shift in the kinetics of the response. Addition of specifically activated T cells or nonspecific T-cell-replacing factors to normal or T-depleted spleen cell cultures did not abrogate suppression while the response to the T-independent antigen DNP-polymerized flagellin or lipopolysaccharide was also suppressed. BMC did not inhibit background Ab synthesis by normal or primed cells in the absence of antigen and did not inhibit, but stimulated, DNA synthesis in normal spleen cell cultures. In addition, high-avidity Ab synthesis was preferentially suppressed. A possible role for the bone marrow suppressor cell in the induction of B cell tolerance is discussed.     

Accessory cell requirements for lymphoma growth in vitro and in irradiated mice.

Growth of the transplantable B-cell lymphoma, PU-5, is markedly diminished in γ-irradiated as compared to normal BALB/c mice. Transfer of bone marrow, but not of lymph node or peritoneal exudate cells, partially restored the ability of irradiated mice to support lymphoma growth. In vitro growth of PU-5 cells is promoted by silica-sensitive, adherent cells, bearing surface Ia antigen and present in peritoneal exudates, spleen and lymph node, but not in bone marrow. Their action on PU-5 growth can be shown only in rocking cultures; the cells do not have to be histocompatible, they act synergistically with 2-mercaptoethanol (2-ME) in the medium. The growth-promoting action in vitro is decreased 24 hr after γ-irradiation of the adherent cells in vitro. Growth of transplantable reticulum cell sarcoma in SJL/J mice has previously also been shown to be inhibited by prior irradiation of the host and to be restored by transfer of lymphoid cells including a phagocytic component, but in the present studies no consistent growth-promoting effect of accessory cells on reticulum cell sarcomas has been shown in vitro. Both lymphomas are stimulated by the presence of 2-ME in stationary cultures. The relationship between the in vivo and in vitro lymphoma growth-promoting activities of macrophage-like cells is discussed.     

An in vitro model for induction of immunological unresponsiveness to turkey gamma-globulin in primed mouse spleen cells. I. The secondary in vitro response and induction of unresponsiveness.

Spleen cells from mice previously immunized with turkey γ-globulin (TGG) were shown to give a vigorous secondary response in vitro when challenged in Mishell-Dutton cultures with TGG covalently coupled to pig erthrocytes (TGG-PRBC). However, 90–100% of the response could be abrogated by the incorporation of soluble TGG (sTGG) into the culture medium at concentrations greater than 1 mg/ml. Unresponsiveness, as measured by the absence of plaque-forming cells (PFC) in cultures receiving sTGG, was found to be antigen specific in that these cultures were still able to give normal PFC responses to sheep or burro erythrocytes. Spleen cells incubated with sTGG for short periods of time were shown to remain unresponsive after removal of sTGG from the culture and addition of TGG-PRBC. A 1-hr exposure period resulted in greater than 70% Unresponsiveness and a complete unresponsive state required only 8 hr of exposure. In contrast to the continued Unresponsiveness of sTGG-treated cells in vitro, spleen cells incubated with sTGG for 24 hr were fully responsive to an immunogenic challenge with alum-precipitated TGG when they were transferred into irradiated syngeneic mice. These data suggest that the readily induced unresponsive state in cultures of TGG primed cells may involve either a reversible antigen blockade of antigen-sensitive lymphocytes or a peripheral inhibition of reactive cells by suppressor lymphocytes.     

Macrophage Migration Inhibition by Serum from Desensitized Animals Previously Sensitized with Tubercle Bacilli

MIGRATION of peritoneal exudate cells removed from guinea-pigs or mice exhibiting delayed hypersensitivity is inhibited by specific antigen^1–3. This in vitro macrophage migration inhibition has been regarded as a useful immunological test for delayed skin hypersensitivity^4,5. Studies of the mechanism of this phenomenon revealed that, in contact with specific antigen, lymphocytes from sensitized animals released into the medium a specific substance (migration inhibitory factor; MIF) capable of inhibiting the migration of normal macrophages^6,7. When injected intradermally into normal guinea-pigs, MIF elicits inflammatory reactions characterized by induration, erythema and mononuclear cell infiltration⁸.     

Properties of Immature Myeloid Progenitors with Nitric-Oxide-Dependent Immunosuppressive Activity Isolated from Bone Marrow of Tumor-Free Mice

Myeloid derived suppressor cells (MDSCs) from tumor-bearing mice are important negative regulators of anti-cancer immune responses, but the role for immature myeloid cells (IMCs) in non-tumor-bearing mice in the regulation of immune responses are poorly described. We studied the immune-suppressive activity of IMCs from the bone marrow (BM) of C57Bl/6 mice and the mechanism(s) by which they inhibit T–cell activation and proliferation. IMCs, isolated from BM by high-speed FACS, inhibited mitogen-induced proliferation of CD4⁺ and CD8⁺ T-cells in vitro. Cell-to-cell contact of T-cells with viable IMCs was required for suppression. Neither neutralizing antibodies to TGFβ1, nor genetic disruption of indolamine 2,3-dioxygenase, abrogated IMC-mediated suppressive activity. In contrast, suppression of T-cell proliferation was absent in cultures containing IMCs from interferon-γ (IFN-γ) receptor KO mice or T-cells from IFN-γ KO mice (on the C57Bl/6 background). The addition of NO inhibitors to co-cultures of T-cells and IMC significantly reduced the suppressive activity of IMCs. IFN-γ signaling between T-cells and IMCs induced paracrine Nitric Oxide (NO) release in culture, and the degree of inhibition of T-cell proliferation was proportional to NO levels. The suppressive activity of IMCs from the bone marrow of tumor-free mice was comparable with MDSCs from BALB/c bearing mice 4T1 mammary tumors. These results indicate that IMCs have a role in regulating T-cell activation and proliferation in the BM microenvironment.     

In vitro immune blastogenesis during contact sensitivity in tumor-bearing mice: I. Description of progressive impairment and demonstration of splenic suppressor cells

T-cell responsiveness was measured by the DNA response of disassociated spleen and lymph node cells when exposed to antigen in vitro. Sensitized splenic lymphocytes from fibrosarcoma-bearing mice immunized with 2,4-dinitro-1,5-difluorobenzene (DN2FB) demonstrated a progressive decrease in T-cell responsiveness to the haptenprotein conjugate DNP-BSA. Hyporesponsiveness to the dinitrophenylated-protein conjugate appeared in the spleens but not lymph nodes of tumorous animals. Normal host lymph node cells (LNC) responded strongly 24 to 48 h after sensitization and subsequently declined with a corresponding increase in responsiveness in the spleen. Tumor-bearing hosts (TBH) had similar LNC kinetics during immunization, however, spleen cells were significantly suppressed when compared to normal BALB/c mice sensitization kinetics. Spleen cells from TBH were also capable of suppressing the in vitro response of normal primed lymphocytes to DNP-BSA when admixed. Results from these experiments suggest that in vitro measurement of contact sensitivity was affected by suppressor cells/products existing in the spleens but not lymph nodes of fibrosarcoma-bearing mice.     

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.     

In vitro inhibition of the helper activity of GAT-specific T-cell lines by a syngeneic anti-idiotypic serum: preferential effect on the IgG response

We described in this paper the characteristics of a syngeneic anti-idiotypic serum made in BALB/c against BALB/c anti-poly (Glu⁶⁰ Ala³⁰ Tyr¹⁰) (GAT) antibodies. This serum recognizes idiotypic determinants present in all anti-GAT sera whatever the allotypic markers of the mice used to prepare the sera. The functional effect of this serum on two helper cell lines is also described. Cell line BDF₁/52 was obtained from GAT immunized lymph node cells (LNC). Cell line BDF₁/E₃ was selected from splenic T-cells educated in vitro on GAT-pulsed adherent cells. Both lines were propagated in presence of filler cells, antigen, and medium containing T-cell growth factor(s) from splenic cells activated with concanavalin A. Both cell lines exhibit a helper activity as measured by the plaque-forming cell (PFC) response they induce in vitro in the presence of DNP-GAT and DNP sensitized B cells. Their helper activity is specific and they require a hapten-carrier bridge to activate B cells. These lines are able to induce IgG₁, IgG_2a and IgG_2b anti-TNP PFC. Syngeneic anti-idiotypic serum B 658 inhibits specifically the function of these two lines but does not affect the helper activity of an OVA-specific T-cell line. The blocking activity of the serum can be adsorbed on a hybridoma protein with anti-GAT activity. This inhibition affects more dramatically the IgG₁ response than the IgG_2a and IgG_2b responses.     

Adaptive immune responses during Shigella dysenteriae type 1 infection: an in vitro stimulation with 57 kDa major antigenic OMP in the presence of anti-CD3 antibody

An effort was made to understand the role of the 57 kDa major antigenic fraction of Shigella outer membrane protein (OMP) in the presence of T-cell antigen receptor in activation of adaptive immune responses of the cell mediated immune (CMI) restored patients. The expression of HLA-DR/CD4 out of CD3⁺ T-cells was significantly dominant over the HLA-DR/CD8 and comparable to unstimulated cells of infected or healthy controls. CD4⁺ T-cell activation together with HLA-DR is associated with the expression of CD25⁺ (IL2Rα) for IL-2 growth factors with decreased IL-4 levels, required for maintaining the homeostasis of CD4⁺ T cell. Furthermore, the positive expression of the CD45 antigen is possibly required for acquiring the memory for CD4⁺ cells signals and facilitates the interaction with CD54 antigen. As a result, antigen-specific secondary signal is generated for B-cell activation to produce IgG2a and IgG2b. This suggests that antibody mediated-adaptive immune responses are generated due to anti-CD3 induced helper T-cell activity. The above mentioned findings reflect that the antigen alone might not exacerbate the selective T-cell responses. But these antigens in the presence of anti-CD3 antibody might help to elicit adaptive immune response via T-cell receptor (TCR) activation.     

The nature of immunodeficiency induced by injections of lectins and cyclophosphamide

Consecutive injections of T-cell mitogen (LcA, Con A) and cyclophosphamide (CY) produce an inhibition of T-cell, but not B-cell functions. This phenomenon was not a result of suppressor-cell activity of the action of some suppressor serum factors. Immunoreactivity of mice, treated with Con A CY is restored by thymocytes from intact donors, but not bone marrow cells. Using, monoclonal antibodies to Thy-1.2 antigen or anti-Ig serum it has been shown that pretreatment of mice with lectin and CY resulted in a decrease in T-cell, but not B-cell number in comparison with control mice. The above facts are indicative of CY-mediated elimination of T cells involved in proliferation and differentiation by lectin.     

Immunization with a lentivector that targets tumor antigen expression to dendritic cells induces potent CD8+ and CD4+ T-cell responses

Lentivectors stimulate potent immune responses to antigen transgenes and are being developed as novel genetic vaccines. To improve safety while retaining efficacy, we constructed a lentivector in which transgene expression was restricted to antigen-presenting cells using the mouse dectin-2 gene promoter. This lentivector expressed a green fluorescent protein (GFP) transgene in mouse bone marrow-derived dendritic cell cultures and in human skin-derived Langerhans and dermal dendritic cells. In mice GFP expression was detected in splenic dectin-2⁺ cells after intravenous injection and in CD11c⁺ dendritic cells in the draining lymph node after subcutaneous injection. A dectin-2 lentivector encoding the human melanoma antigen NY-ESO-1 primed an NY-ESO-1-specific CD8⁺ T-cell response in HLA-A2 transgenic mice and stimulated a CD4⁺ T-cell response to a newly identified NY-ESO-1 epitope presented by H2 I-A^b. As immunization with the optimal dose of the dectin-2 lentivector was similar to that stimulated by a lentivector containing a strong constitutive viral promoter, targeting antigen expression to dendritic cells can provide a safe and effective vaccine.