Antigen Binding Lymphocytes in Congenitally Athymic (Nude) Mice

THE autoradiographic detection of the binding of various radiolabelled antigens to a proportion of lymphocytes from animals not exposed to those antigens (“nonprimed” lymphocytes) is well documented^1–4. Such lymphocytes are thought to have patches of surface immunoglobulin, primarily IgM, which act as specific receptors for antigen^5,6. A proportion at least of these unprimed lymphocytes are immunologically competent as shown in vivo^7,8 and hence are true antigen reactive cells. Most assays have used peripheral lymphocyte suspensions from tissues of man, mouse, rat and chicken, not enriched or fractionated in any way for the two distinct lines of lymphocytes, thymic derived (T) and non-thymic derived (B)⁹. It is not clear whether antigen-binding cells (ABC), detected in routine assays where autoradiographs are exposed for 1–2 weeks, are of both T and B cell type or are predominantly of only one type. Experiments using unlabelled and radiolabelled immunoglobulin antisera with isolated T and B cells have inferred specific antigen binding on both populations although T cells seem to have far fewer antigen binding receptors than B cells¹⁰.     

Intramembraneous Marker in T Lymphocytes

IT is generally accepted that two distinct classes of lymphocytes collaborate in many immune functions. These lymphocytes are thymus-derived T cells and bone marrow-derived B cells. In mice T and B cells can be distinguished serologically; for example, T cells contain a membrane bound antigen (θ)¹ and B cells also have a specific antigenic marker¹. In addition, B cells have numerous surface bound immunoglobulin-like molecules which are readily demonstrable with labelled anti-sera^2–6, but on T cells surface immunoglobulins are sparse and difficult to demonstrate^3,5,7. Marked differences therefore exist between the membranes of T and B cells which cannot be seen directly in ultra-thin sections examined by electron microscopy. In this study, freeze-fracturing was used to produce replicas of the membranes of lymphocytes from normal and T cell-depleted mice in an attempt to demonstrate directly possible intramembraneous differences between T and B cells.     

Specific activation of human T lymphocytes by Robinia pseudoacacia seeds' lectin.

Human peripheral blood and tonsil lymphocytes were fractionated into T and B cells by centrifugation after rosetting with native sheep erythrocytes and tested with Robinia pseudoacacia lectin. The purity of B- and T-enriched populations was checked by E-rosette formation or heterologous antisera specific for B or T lymphocytes. The proliferative response of T cells to Robinia lectin from all the donors tested was not found to differ from that of unfractionated cells, whereas no response of highly purified B cells could be observed to the lectin even with different concentrations of the lectin and different culture periods. B cells, however, were found to bind as much ³H labeled Robinia lectin as unfractionated lymphocytes. In addition, treatment of cells by antihuman T-lymphocyte antigen (HTLA) serum and complement before addition of Robinia lectin completely abolished their response, whereas similar treatment by antihuman B lymphocyte and monocyte antigen (HBLMA) serum did not prevent the T cells from incorporating thymidine. The Robinia lectin, like the other phytomitogens, thus appears to be a specific T-cell activator.     

T cell activation of primed rabbit blood lymphocytes by antigen.

Activation of primed rabbit PBL by homologous antigen in the early proliferative phase (on days 3--5) mainly involves lymphocytes which neither secrete specific antibody nor contain immunoglobulin in their cell membrane. This stimulation is antigen-specific, and evidence is given that the major proportion of these cells are T lymphocytes. The B cells forming Av-CHO-specific PFC were studied by autoradiography on days 6 and 12 of culture. Since incorporation of radioactive thymidine was found in the majority of PFC, these cells are also in proliferation.     

Analysis of Ly-6.2-bearing murine lymphocyte subpopulations in relation to the T-lymphocyte markers,Thy-1, Lyt-1, and Lyt-2

Using immunofluorescence with a monoclonal anti-Ly-6.2 antibody and FACS analysis we have confirmed that the Ly-6.2 antigen is present on approximately 70% of mature T cells and B cells but on few immature lymphocytes. There is a wide range of antigen density among the Ly-6.2⁺ populations, with the mean density higher on T cells than B cells. Following Con A activation of splenocytes there was a sixfold increase in Ly-6.2 antigen density though approximately 20% of the activated lymphocytes were Ly-6.2^?. The increase in Ly-6.2 density was specific since similar density increases did not occur for the closely linked antigens ThB and H $\text{9}\text{25}$. By panning a predominantly T-cell population for Lyt-2-bearing cells, it was found that Lyt-2⁺ lymphocytes were either negative or dully staining for Ly-6.2. However, activated cells bearing the Lyt-2 antigen were all Ly-6.2 positive. Double-staining experiments showed that T cells which had high Ly-6.2 antigen densities also had high Thy-1 antigen densities. Corticosteroid-resistant thymocytes were highly enriched for Ly-6.2-bearing cells compared to untreated thymocytes and had staining profiles for Ly-6.2 which were similar to peripheral T cells, supporting the idea that steroid treatment selects for a phenotypically mature thymic population.     

Alterations in the human immune response to the hepatitis B vaccine among the elderly

The specific binding of hepatitis B (HBs) antigen by lymphocytes from old people immunized with hepatitis B vaccine was explored. For that purpose HBs antigen was combined with fluorescent microspheres, and labeled antigen was allowed to react with lymphocytes from HBs vaccine-responsive or unresponsive people. Lymphocytes from 10 responders and 14 nonresponders were tested for their antigen-binding ability. For controls, lymphocytes were incubated with microspheres bearing human albumin. Lymphocytes from 8 out of 10 responders were able to recognize HBs antigen; for the nonresponders the ratio was 9 out of 14. HBs-binding lymphocytes were B cells but not T lymphocytes. B and T cells from responders and nonresponders were combined and cultivated for 8 days in the presence of HBs antigen, and antibody-producing cells were counted. Neither B cells alone nor B cells plus T cells from nonresponders were able to produce antibody. On the other hand B cells from unresponsive old people produced antibodies when they were cultivated in the presence of HBs antigen and T cells from responsive old people. These data suggest that some elderly individuals who do not produce antibody after in vivo immunization by HBs vaccine do have antibody-producing cells. Instead of a gap in their immune repertoire, these people are suffering from immune dysfunction.     

Fractionation of Specific Antigen-reactive Cells in an <Emphasis Type="Italic">in vitro</Emphasis> System of Cell-mediated Immunity

ACCORDING to present concepts the diversity of antibodies is determined by a similar diversity of the precursors of antibody-producing cells. The existence of a diversified cell population in the lymphoid organs was most directly demonstrated by specific adherence of antigen-reactive cells on antigen columns. Antigen-binding cells were specifically eliminated from lymphoid cell populations of both preimmunized^1,2 and non-immunized donors^3–5. The non-bound cells were incapable of producing antibody to the antigen applied on the column, yet they could produce antibody to non-related antigens. Plaque forming cell precursors, plaque forming cells and memory cells towards various antigens were separated^1–5. In all these cases the cells which specifically adhered to the antigenic column were most probably bone marrow-derived lymphocytes (B cells). On the other hand, no such specific adherence was achieved with thymus-derived lymphocytes (T cells), such as those involved in carrier recognition during immunization with hapten carrier conjugates⁶ and in cell-mediated immunity.     

Properties of Educated T Cells for Rosette Formation and Cooperation with T Cells

IT has been shown that the humoral antibody response in mice to many antigens requires cooperation between thymus derived lymphocytes (T cells) and bone marrow derived lymphocytes (B cells)^1,2. The B cells are the direct precursors of antibody secreting cells and, although T cells react specifically with antigen, their role is unknown^2–6.     

A novel method for producing target cells and assessing cytotoxic T lymphocyte activity in outbred hosts

Background  

Cytotoxic T lymphocytes play a crucial role in the immunological control of microbial infections and in the design of vaccines and immunotherapies. Measurement of cytotoxic T lymphocyte activity requires that the test antigen is presented by target cells having the same or compatible class I major hystocompatibility complex antigens as the effector cells. Conventional assays use target cells labeled with ⁵¹chromium and infer cytotoxic T lymphocyte activity by measuring the isotope released by the target cells lysed following incubation with antigen-specific cytotoxic T lymphocytes. This assay is sensitive but needs manipulation and disposal of hazardous radioactive reagents and provides a bulk estimate of the reporter released, which may be influenced by spontaneous release of the label and other poorly controllable variables. Here we describe a novel method for producing target in outbred hosts and assessing cytotoxic T lymphocyte activity by flow cytometry.     

Antigen presentation in acquired immunological tolerance

In acquired tolerance, previous exposure to antigen under certain conditions induces specific unresponsiveness instead of specific immunological memory. It has been studied as an approach to the mechanisms of self-tolerance that operate on immunocompetent T and B lymphocytes once they leave their sites of origin in the thymus and the bone marrow. Possible mechanisms involve induction of specific suppressor cells or inactivation of antigen-specific lymphocytes (clonal anergy) as a consequence of abortive antigen presentation, in which the antigen receptor is effectively engaged but certain poorly defined accessory signals the T lymphocytes require are lacking. We propose that small, resting B lymphocytes, which lack these accessory signals, are the inactivating antigen-presenting cells in acquired tolerance to proteins and to the class II transplantation antigens. B lymphocytes, which can use their antigen receptors to gather and process antigens that are present at very low concentrations, may play a role in self-tolerance. In addition, B lymphocytes and T lymphocytes rendered anergic by encounter with self antigens could persist as self-specific suppressor cells to block an autoimmune response of autoreactive clones that had escaped deletion or anergy.     

Cooperation of dendritic cells with naïve lymphocyte populations to induce the generation of antigen-specific antibodies in vitro

The production of monoclonal antibodies by hybridoma technology is dependent on lymphocytes taken from vertebrates which have to be immunized against the corresponding antigen. We present here our first experiments which should allow the replacement of this in vivo immunization step by an in vitro immunization procedure. This work provides new possibilities for the specific activation of immune cells in order to use them for the generation of antibodies which are not of murine origin. Bone marrow-derived dendritic cells were loaded with antigen and co-cultured with naïve T and B lymphocytes of non-immunized mice. The interaction and activation of the different cell types were investigated by measuring the expression of specific cell surface markers, the release of activation-dependent interleukins and the secretion of antigen-specific antibodies. We could demonstrate that dendritic cells process and present antigen fragments and activate T cells, that T cells proliferate and release activation-induced interleukins, and that B cells maturate under the influence of activated T cells and secrete antigen-specific antibodies.     

Specific Collaboration between T and B Lymphocytes across a Cell Impermeable Membrane <Emphasis Type="Italic">in vitro</Emphasis>

ANTIBODY production to many antigens including heterologous erythrocytes^1–3, serum proteins^4,5 and hapten protein conjugates^6,7, occurs as a result of an interaction between antigen and thymus-derived (T) and non-thymus-derived (B) lymphocytes. Although the specificity of the antibody response is determined by T as well as B cells^8–10, T cells do not actively secrete any of the known classes of immunoglobulin molecules¹¹. Their function seems rather to initiate the sequence of events whereby antigen is presented to B cells in an immunogenic form capable of stimulating antibody synthesis¹².     

Surface glycoproteins of resting and activated human T lymphocytes

Summary This review summarizes some recent studies on the surface glycoproteins of human thymocytes and T lymphocytes. Purified cells were surface labeled by the galactose oxidase-NaB³H₄ or periodate-NaB³H₄ techniques. The radioactive membrane glycoproteins were separated by polyacrylamide slab gel electrophoresis and visualized by fluorography. Thymocytes and T lymphocytes show characteristic surface glycoprotein profiles which are easily distinguishable from those of the other main groups of human leukocytes. We observed specific changes in the surface glycoprotein patterns which correlate with the degree of maturation and functional activation of T cells. Surface molecules carrying T cell specific antigens were identified by immune-precipitation from lysates of surface labeled thymocytes and T lymphocytes using rabbit anti-human T cell antibodies. Finally we describe a leukocyte membrane glycoprotein which is a precursor of serum ₁ acid glycoprotein (orosomucoid).     

Anti-idiotype stimulation of antigen-specific antigen-independent antibody responses in vitro. II. Triggering of B lymphocytes by idiotype plus anti-idiotype in the absence of T lymphocytes

Antibodies specific for the idiotypes of B10 anti-(T,G)-A--L antibodies (anti-id) induced B lymphocytes to secrete anti-(T,G)-A--L antibodies in vitro in the absence of both antigen and T lymphocytes, provided either that the B lymphocytes were previously primed in vivo with (T,G)-A--L or that id specific for (T,G)-A--L was added to the cultures. These antigen- and T lymphocyte-independent responses were antigen specific and appeared not to require accessory cells. The results suggested that B lymphocyte activation occurred via the formation of id-anti-id complexes, and evidence was obtained that this activation involved two separate interactions between the B lymphocytes and the id-anti-id complexes. These studies document a previously undescribed regulatory function of anti-idiotype antibodies.     

Separate Thymus Dependent and Thymus Independent Antibody Forming Cell Precursors

COOPERATION between bone marrow-derived (B) and thymus-derived (T) lymphocytes in antibody formation in mice is well established¹ and with sheep red blood cells (SRBC) as the antigen the detectable antibody-forming cells are of marrow and not thymus origin². Gershon and Kondo have recently suggested that the T cells requiring B cell cooperation for antibody production may also require it for tolerance induction, but that other B cells do not require T cell cooperation for either process³.     

Antigen presentation by hapten-specific B lymphocytes. II. Specificity and properties of antigen-presenting B lymphocytes, and function of immunoglobulin receptors

The studies described in this paper were designed to examine the ability of hapten-binding murine B lymphocytes to present hapten-protein conjugates to protein antigen-specific, Ia-restricted T cell hybridomas. BALB/c B cells specific for TNP or FITC presented hapten-modified proteins (TNP-G1 phi, TNP-OVA, or FITC-OVA) to the relevant T cell hybridomas at concentrations below 0.1 microgram/ml. Effective presentation of the same antigens by B lymphocyte-depleted splenocytes, and of unmodified proteins by either hapten-binding B cells or Ig spleen cells, required about 10(3)-to 10(4)-fold higher concentrations of antigen. The use of two different haptens and two carrier proteins showed that this extremely efficient presentation of antigen was highly specific, with hapten specificity being a property of the B cells and carrier specificity of the responding T cells. The presentation of hapten-proteins by hapten-binding B lymphocytes was radiosensitive and was not affected by the depletion of plastic-adherent cells, suggesting that conventional APCs (macrophages or dendritic cells) are not required in this phenomenon. Antigen-pulsing and antibody-blocking experiments showed that this hapten-specific antigen presentation required initial binding of antigen to surface Ig receptors. Moreover, linked recognition of hapten and carrier determinants was required, but these recognition events could be temporally separated. Finally, an antigen-processing step was found to be necessary, and this step was disrupted by ionizing radiation. These data suggest a role for B cell surface Ig in providing a specific high-affinity receptor to allow efficient uptake or focusing of antigen for its subsequent processing and presentation to T lymphocytes.     

Activation of rat B lymphocytes. I. Characterization of anti-immunoglobulin responses and isotype density of rat B cells

Spleen cells of two rat strains, Lewis and Brown Norway (BN), have been activated by lectins and by antibodies specific for immunoglobulin isotypes embedded in their cell membranes. Optimal concentrations of antibodies specific for mu, gamma, or delta-chains of rat augments in vitro incorporation of 3H-TdR 5 to 18-fold in Lewis B lymphocytes and 1.5 to 4-fold in BN B lymphocytes. In addition, F(ab')2 fragments of anti-Ig reagents induced Lewis splenic B cells but not BN B cells to incorporate 3H-TdR. Responses to LPS and dextran sulfate, B lymphocyte mitogens, measured by radioactive uptake, were five to 10 times greater in Lewis B cell populations than in BN B cell populations. Density of surface Ig isotypes and capping kinetics were similar in the two rat strains, although the percentage of T cells, T cell subsets, B cells, and Ia+ B cells differed in the spleens of these strains of rats. Both T lymphocytes and macrophages were needed in culture to effect an optimal response. IL-2 restored the response in B cell cultures depleted of T cells and macrophages, and enhanced 3H-TdR uptake in whole spleen cells of Lewis but not BN rats. The strain-dependent responsiveness of B cells to specific anti-Ig reagents or B cell mitogens appears to be associated with inherent (genetic) defects in T cells and B cells or defects in T cell to B cell cooperation in BN rats.     

Endothelial cells promote the proliferation of lymphocytes partly through the Wnt pathway via LEF-1

The function of T cells and B cells is to recognize specific “non-self” antigens, during a process known as antigen presentation. Once they have identified an invader, the cells generate specific responses that are tailored to maximally eliminate specific pathogens or pathogen-infected cells. Endothelial cells (ECs) can trigger the activation of T cells through their class I and class II MHC molecules. In this study, we examined the effect of ECs on the proliferation of lymphocytes. We report that the proliferation of T and B cells can be improved by interaction with ECs. LEF-1 is one of the main molecular mediators in this process, and the inhibition of LEF-1 induces apoptosis. These results suggest that LEF-1 modulates positively the proliferation of lymphocytes induced by their interaction with ECs.     

T cell activation of antigen-specific antibody responses by large B cells is MHC restricted

The activation of small, resting B cells for antibody synthesis by helper T cells has been proposed to require an MHC-restricted interaction between the T and B cells. Large, activated B lymphocytes were, in contrast, thought to be activated by an unrestricted pathway. We re-examined this issue and found that both large and small size fractionated murine B lymphocytes required an MHC-restricted interaction with helper T cells to be activated for specific antibody synthesis. Polyspecific antibody synthesis in the same cultures was not dependent upon an MHC-restricted T-B interaction for any size category of B cell. These results are interpreted as reflecting the ability of antigen-specific B cells to focus and present antigen to T cells, in contrast to B cells of random specificity, which have no effective focusing mechanism for a given experimental antigen. We found that the polyspecific response required much higher antigen concentrations than the antigen-specific response, a result consistent with the antigen-focusing hypothesis.     

IgE-Mediated Enhancement of CD4+ T Cell Responses in Mice Requires Antigen Presentation by CD11c+ Cells and Not by B Cells

IgE antibodies, administered to mice together with their specific antigen, enhance antibody and CD4⁺ T cell responses to this antigen. The effect is dependent on the low affinity receptor for IgE, CD23, and the receptor must be expressed on B cells. In vitro, IgE-antigen complexes are endocytosed via CD23 on B cells, which subsequently present the antigen to CD4⁺ T cells. This mechanism has been suggested to explain also IgE-mediated enhancement of immune responses in vivo. We recently found that CD23⁺ B cells capture IgE-antigen complexes in peripheral blood and rapidly transport them to B cell follicles in the spleen. This provides an alternative explanation for the requirement for CD23⁺ B cells. The aim of the present study was to determine whether B-cell mediated antigen presentation of IgE-antigen complexes explains the enhancing effect of IgE on immune responses in vivo. The ability of spleen cells, taken from mice 1–4 h after immunization with IgE-antigen, to present antigen to specific CD4⁺ T cells was analyzed. Antigen presentation was intact when spleens were depleted of CD19⁺ cells (i.e., primarily B cells) but was severely impaired after depletion of CD11c⁺ cells (i.e., primarily dendritic cells). In agreement with this, the ability of IgE to enhance proliferation of CD4⁺ T cells was abolished in CD11c-DTR mice conditionally depleted of CD11c⁺ cells. Finally, the lack of IgE-mediated enhancemen of CD4⁺ T cell responses in CD23^-/- mice could be rescued by transfer of MHC-II-compatible as well as by MHC-II-incompatible CD23⁺ B cells. These findings argue against the idea that IgE-mediated enhancement of specific CD4⁺ T cell responses in vivo is caused by increased antigen presentation by B cells. A model where CD23⁺ B cells act as antigen transporting cells, delivering antigen to CD11c⁺ cells for presentation to T cells is consistent with available experimental data.