Defective induction of antigen-reactive proliferating T cells in B cell-deprived mice

Strong priming of T cells adoptively transferred into scid mice

We have examined the requirements for activating unprimed T cells in vivo by transferring T cells into scid mice, which lack mature B and T cells. Purified adult thymocytes and a protein antigen, keyhole limpet hemocyanin (KLH), were injected into scid mice. scid mice injected with T cells and KLH developed cellular lymph nodes containing CD4+ and CD8+ T cells. Cells recovered from the lymph nodes of injected scid mice proliferated and secreted interleukin 2 in response to KLH in vitro. The results indicate that T cells can be primed to KLH in the scid mouse in the absence of B cells.

A cell culture model for T lymphocyte clonal anergy

T lymphocytes respond to foreign antigens both by producing protein effector molecules known as lymphokines and by multiplying. Complete activation requires two signaling events, one through the antigen-specific receptor and one through the receptor for a costimulatory molecule. In the absence of the latter signal, the T cell makes only a partial response and, more importantly, enters an unresponsive state known as clonal anergy in which the T cell is incapable of producing its own growth hormone, interleukin-2, on restimulation. Our current understanding at the molecular level of this modulatory process and its relevance to T cell tolerance are reviewed.

Compartmentalization of MHC class II gene expression in transgenic mice

A set of transgenic mouse lines carrying Ek alpha genes with promoter region deletions was created in an attempt to compartmentalize MHC class II gene expression. Fine immunohistological analyses established that one transgenic line is essentially devoid of E complex in the thymic cortex, another displays almost no E in the thymic medulla or on peripheral macrophages, and two lines display no E on greater than 98% of B cells. We have assayed these mice for immune function: E-dependent tolerance, antigen presentation, T cell priming, and antibody response. Certain of the findings are difficult to reconcile with currently popular hypotheses, e.g., tolerance induction to E molecules in the virtual absence of E complex in the thymic medulla and efficient antibody responses to E-restricted antigens when almost all B cells are E-.

T-cell function in B-lymphocyte-deprived mice

Previous work has identified selective defect(s) in T cells in mice deprived of B lymphocytes by the chronic administration of anti-IgM antibody. Experiments described in the present communication revealed that anti-IgM-treated mice do not possess T cells with surface Ia and FcR, and, unlike T cells from normal animals, they also fail to bind these molecules in vitro. Functional assays disclosed that an anti-suppressor pathway which relies on Ia+ donor and acceptor T cells is interrupted in these mice at both levels. These observations may provide an insight to explain the selective failure of some T cells when B lymphocytes have been deleted.

T cell development in B cell-deficient mice. II. Serological characterization of suppressor T cell factors (TsF1) produced in normal mice and in mice treated chronically with rabbit anti-mouse IgM antibodies

Serological analysis of idiotypic specificities present in azobenzenearsonate (ABA)-specific first-order suppressor T cell factors (TsF1) from C.AL-20 and BALB/c mice revealed a significant difference between TsF from these two strains of mice. The idiotypic composition of TsF1 from BALB/c mice appears to be more heterogeneous, and at least two different fractions can be readily identified. One bears the characteristic BALB/c-associated CRI(C) (crossreactive idiotype) determinants, and the other is non-CRI(C)-bearing. Analysis of ABA-specific TsF1 from animals lacking B cells uncovered a fundamental change in the expression of their idiotypic specificities. TsF from rabbit anti-mouse IgM (anti-mu)-treated C.AL-20 mice failed to express the characteristic CRI(A) determinants. Instead, they express CRI(C) specificities. Similarly, TsF1 from anti-mu-treated BALB/c mice did not express their characteristic CRI(C) specificities, but rather express CRI(A) determinants. These experiments provide strong evidence that the Igh restriction specificity of TsF is dictated by the particular idiotypic specificities expressed. They also clearly demonstrate that B cells and their products play an important role in establishing the idiotypic composition and repertoire of suppressor T cells.

Absence of the Lyt-2-,L3T4+ lineage of T cells in mice treated neonatally with anti-I-A correlates with absence of intrathymic I-A-bearing antigen-presenting cell function

In an effort to elucidate the role of intrathymic Ia-bearing antigen-presenting cells (APC) on the development of the class II-restricted T cell repertoire, we examined the effect of neonatal anti-I-A treatment on both intrathymic and splenic APC function; on the generation of Lyt-2-,L3T4+, Lyt-2+,L3T4-, and Lyt-2+,L3T4+ T cells; and on the development of class I- and class II-specific T cell functions. Both the thymus and the spleen are completely devoid of Lyt-2-,L3T4+ T cells in young mice treated from birth with anti-I-A, and also lack functions associated with this subset, i.e., alloantigen-specific interleukin 2 production (present report), allo-class II-specific and self-class II-restricted T cell proliferative responses, and helper cell function for the generation of cytotoxic T lymphocyte responses (18). Development of the Lyt-2+,L3T4- subset proceeds undisturbed in these mice, in accord with the previously reported normal levels of cytotoxic T lymphocyte precursors (18). The thymus contains normal numbers of the immature cortical Lyt-2+,L3T4+ cells, indicating that acquisition of the L3T4 marker, in and of itself, is not influenced by anti-I-A treatment. This striking absence of the lineage of T cells responsible for class II-specific T cell functions is correlated with absence of thymic APC function for class II-restricted T cell clones. When anti-I-A-treated mice are allowed to recover from the antibody treatment, splenic and thymic APC function return to normal in 2-3 wk, and thymic Lyt-2-,L3T4+ T cell numbers and functions reappear before such cells are detectable in the spleen. Collectively, these findings suggest that development of the Lyt-2-,L3T4+ lineage of class II-specific T cells is entirely dependent on functional I-A-bearing APC cells in the thymus. In addition, the presence of normal levels of Lyt-2+,L3T4-T cells argues that generation of the two major subsets of T cells (i.e., Lyt-2+,L3T4- and Lyt-2-,L3T4+) occurs through separate events, involving unique sites of interactions between precursor T cells and nonlymphoid major histocompatibility complex-bearing thymus cells.

Internal complementarities in the immune system: regulation of the expression of helper T-cell idiotypes

More than half of BALB/c helper T lymphocytes specific for 2,4,6-trinitrophenyl (TNP)-modified syngeneic spleen cells are inhibited in their proliferative responses to antigen-presenting cells and in their cooperation with B lymphocytes by monoclonal anti-idiotypic antibodies directed to a TNP-binding BALB/c myeloma protein (MOPC 460). This inhibition is specific for anti-TNP-self helper cells of BALB/c origin and is controlled by IgCh-linked genes, as it is not observed with CB.20 helper cells of the same specificity. In contrast, anti-TNP-self helper cells prepared from BALB/c mice that were chronically suppressed with anti-mu chain antibodies and possessed no B lymphocytes were not inhibited by anti-idiotypic antibodies. We conclude that the B-cell antibody repertoires contribute to the selection of the (idiotypic) T-helper-cell repertoires.

Suppressive effects of anti-mu serum on the development of collagen arthritis in rats

Sprague-Dawley rats were maintained in environmentally isolated conditions and some of them were injected beginning at birth with rabbit anti-mu serum to suppress B-cell maturation. All rats were subsequently immunized with chick type II collagen. Ten (28%) of 36 rats injected with anti-mu antiserum failed to develop serum hemagglutinating antibodies to collagen, and there was a significant (P less than 0.0003) reduction in the IgG-specific antibody titer to collagen in these 10 rats compared to the other 26 rats in this group. Only 1 (10%) of the antibody-suppressed rats developed arthritis compared to 20 (77%) of the 26 other rats in the anti-mu-treated group (P less than 0.001). Twenty-two (61%) of 36 immunized rats administered rabbit anti-ovalbumin serum and 14 (88%) of 16 immunized rats kept in the axenic conditions developed arthritis. Delayed-type hypersensitivity to collagen did not differ significantly between the groups. These data provide indirect evidence that antibodies play a role in the inception of collagen arthritis.

The abnormal function of T cells in chronically anti-mu-treated mice with no mature B lymphocytes

T cells from anti-mu-treated mice, normal goat serum ( NGS )-treated mice or untreated control mice were compared with respect to their surface antigenic phenotypes, T cell mitogenic responses, helper function and precursor frequency of helper T cells. Anti-mu treatment arrested the development of B cells at an immature stage, as determined by flow microfluorometry; it resulted in no serum IgM, but detectable levels of IgG by solid-phase radioimmunoassay. Proliferative responses to phytohemagglutinin and concanavalin A were significantly decreased in T cells obtained from mu-suppressed C57BL/6 mice, but not from control mice. When T cells from anti-mu-treated mice were tested in vitro for their helper activity to collaborate with B cells from nu/nu C57BL/6 mice to give plaque-forming cells to sheep red blood cells, they provided far less help than did T cells from control mice. The frequency of T helper cells, as measured by limiting dilution analysis, was much lower in the anti-mu- than in the NGS -treated mice. Cell mixing experiments provided evidence for active suppression of T helper function among splenocytes taken from mu-suppressed mice.

Splenic B cells function as immunogenic antigen-presenting cells for the induction of effector T cells

Previous studies performed in our laboratory have revealed that an ordered, sequential, tricellular interaction is obligatory for the antigen-driven induction of a specific effector memory T cell. Thus, it was found that antigen-pulsed peritoneal macrophages signal, in spleen cells, the generation of antigen-specific initiator lymphocytes. These lymphocytes, following injection to syngeneic recipients, recruit, in the draining lymph nodes, "virgin" antigen-reactive T lymphocytes. Although the nature of the first and last cell in the interacting sequence was well characterized, the identity of the intermediary initiator splenic cell was obscure. Studies were carried out to characterize the nature of the splenic initiator cells. It was found that spleen cells from nu/nu, adult thymectomized and neonatal thymectomized, or spleen cells from normal donors which had been subjected to cytolysis using anti-Thy-1.2 antibodies in the presence of complement, did generate, following interaction with keyhole limpet hemocyanin (KLH)-fed macrophages, specific initiator cells. Carrageenan impairment of spleen macrophages did not affect the generation of initiator cells, nor did the depletion of dendritic cells from the spleen. On the other hand highly enriched B cell, but not highly enriched T cell populations, when seeded on KLH-pulsed macrophages, generated antigen-specific initiators, which, in vivo, recruited antigen-reactive T cells. It thus appeared that B lymphocytes can function as intermediary obligatory antigen-presenting cells and actively transfer immunogenic signals from peritoneal antigen-presenting cells to T lymphocytes. These findings may therefore suggest that antigen-specific B cells do not function solely as antibody-producing cells, but, once activated by macrophages, may control the induction and differentiation of some antigen-reactive T cell subsets. Thus, one can view the B cell as an important regulatory cell of both cellular and humoral immune functions. The significance of this observation with regard to Ir gene control at the level of B lymphocytes is discussed.

Defective induction of antigen-reactive proliferating T cells in B cell-deprived mice. II. Anti-mu treatment affects the initiation and recruitment of T cells

Mice injected from day of birth onwards with rabbit anti-mouse IgM (antim-mu) antibodies were found to be B cell-deficient and defective for the induction of antigen-reactive proliferating T cells (TPRLF). This defective induction was not due to the absence of circulating antigen-specific antibodies since the daily injections of such antibodies during exposure to antigen did not restore the ability of anti-IgM treated animals to generate TPRLF. Analyzing the cellular events implicated in the induction of virgin antigen-reactive T cells, anti-mu-treated mice manifested impairment of the three interacting cell types involved in the induction of TPRLF. Thus, peritoneal and splenic antigen-presenting cells from such animals were impaired in their capacity to signal a primary antigen-specific T cell reaction. Their splenic lymphocytes could not function as initiator cells in transferring immunogenic signals to recruit TPRLF in normal recipients. Potent antigen-specific splenic initiator cells failed to induce the recruitment of specific TPRLF in anti-mu-treated mice. The defective induction of TPRLF in anti-mu-treated mice may be due to a functional impairment of cells expressing membrane-bound IgM molecules which seemingly play a central role in the transfer of immunogenic signals for the recruitment of antigen-specific circulating T cells. We suggest that splenic B cells function as initiators in the transfer of antigen-induced signals from peritoneal antigen-presenting cells to T cells. These seems to be the primary targets of anti-mu treatment.