LP-BM5 murine retrovirus-induced immunodeficiency disease in allogeneic SCID chimeric mice. Inability to recognize a putative viral superantigen does not prevent induction of disease.

T cell recognition of viral superantigens has been postulated to contribute to the pathogenesis of the immunodeficiency disease induced in mice by infection with the LP-BM5 murine leukemia virus complex. A candidate superantigen has been identified in the B cell lymphoma line B6-1710 derived from an LP-BM5-infected C57BL/6 (H-2b) mouse. We have asked whether the stimulatory activity expressed by B6-1710 behaves as a superantigen by assessing the ability of T cells from fully allogeneic H-2b-->H-2d SCID chimeric mice to respond to the line. T cells from allochimeric mice failed to respond to B6-1710, whereas they responded normally to Staphylococcus enterotoxin B, a well characterized superantigen. Despite this finding, allochimeric mice were fully susceptible to the immune deficiency disease induced by LP-BM5 virus infection. These findings show that the role of superantigen expression in retrovirus-induced immune deficiency disease remains to be defined.

Allogeneic chimerism in scid mice after neonatal transfer of bone marrow.

Allogeneic chimeras are valuable tools for studies of complex immune cell interactions in vivo. Mice with severe combined immune deficiency (scid) should be ideal hosts for chimerism with allogeneic bone marrow cells as these animals lack mature T and B lymphocytes capable of reacting against donor alloantigens. However, it has been difficult to achieve full reconstitution of adult scid mice even using coisogenic bone marrow grafts without prior irradiation of the recipient. We explored ways to generate complete reconstitution of scid mice with allogeneic bone marrow. Unirradiated adult scid recipients of allogeneic bone marrow were only marginally reconstituted. Adult scid mice pretreated with 250 R were reconstituted with allogeneic bone marrow as measured by serum IgM concentration, peripheral lymphoid cellularity, and mitogen responses, but a potentially important immunologic deficit was found in these mice: 250 R caused a 70% loss of scid macrophages and dendritic cells which persisted at least 5 months. By contrast, when scid mice were injected i.p. with allogeneic bone marrow within the first 24 h after birth, rapid and complete reconstitution of both T and B cell lineages was achieved, and the animals had APC that were both donor and host in origin. Considering the extent and duration of engraftment (43 wk) by allogeneic cells in neonatally transplanted scid mice, it was anticipated that their bone marrow would be chimeric. However, the bone marrow contained very few donor-derived cells, suggesting that lymphopoiesis may be taking place in other organs in these chimeras.

T-dependent destruction of thyroid isografts exposed to IFN-gamma.

Several autoimmune diseases are accompanied by tissue-specific expression of class II molecules of the MHC, and it has been suggested that this elicits a T cell response against tissue-specific Ag to which the individual is not tolerant. However, recent transgenic studies have indicated that non-lymphoid expression of class II genes in the pancreas, liver, and kidney is either innocuous or induces peripheral tolerance. To test this hypothesis in another organ-specific autoimmune disease, we attempted to induce autoimmune thyroiditis in normal mice with class II+ thyroid tissue. Normal thyroid lobes were cultured with and without IFN-gamma and then transplanted to adult isogeneic recipients. The thyroid that had been induced to express class II genes by IFN-gamma was destroyed in normal mice, whereas the control cultured thyroid and the native cervical gland survived. Both types of transplants remained intact and functional in congenic nu/nu recipients, indicating that neither exposure to IFN-gamma nor expression of class II genes compromised the thyroid. Thus, in some tissues, exposure to IFN-gamma and/or the induction of class II expression can lead to T-dependent autoimmune disease.

Selective expression of class II E alpha d gene in transgenic mice.

Class II genes of the MHC must be expressed by APC for activation of CD4+ T cells and efficient delivery of T cell help to B lymphocytes. Class II genes have restricted tissue expression and are under complex regulation. By using various deletion constructs of the class II E alpha d gene in transgenic mice we have mapped different 5' flanking regions which control E alpha d gene expression in distinct cell types. We demonstrate dissociate expression of E alpha d within the macrophage lineage as well as within the B cell lineage, and present evidence for a repressive element operative in B cells and macrophages. We describe the generation of novel transgenic lines with limited constitutive and inducible E alpha mRNA and I-E protein.

Diabetes and tolerance in transgenic mice expressing class II MHC molecules in pancreatic beta cells.

Insulin-dependent diabetes is caused by the loss of insulin-producing beta cells in pancreatic islets. It has been proposed that aberrant expression of Class II Major Histocompatibility Complex (MHC) molecules on beta cells stimulates an autoimmune attack against beta cell antigens. To test this hypothesis, we generated transgenic mice that express Class II MHC molecules (E alpha d/E beta b, or I-Eb) on beta cells. Diabetes was found in 100% of transgenic progeny from three expressing transgenic mouse lines, but without evidence for lymphocytic infiltrates. Furthermore, T lymphocytes appeared to be tolerant to the transgene I-Eb molecule, despite the absence of expression of I-Eb in the thymus or any other lymphoid tissue. The results suggest that novel expression of Class II MHC molecules on nonlymphoid cells is by itself insufficient to initiate autoimmune responses against tissue-specific antigens.

Transgenic mice selectively lacking MHC class II (I-E) antigen expression on B cells: an in vivo approach to investigate Ia gene function.

The E alpha MHC class II gene with 1.4 kb of 5'-flanking and 0.5 kb of 3'-flanking sequences was introduced into (H-2b X s)F2 mice, which do not express their endogenous E alpha gene. The transgene was expressed in thymic tissue and in adherent spleen cells and was induced in peritoneal exudate cells by gamma-interferon. In contrast to the normal E alpha gene, there was no expression in B lymphocytes. Since transgenic animals made with constructs containing 3.2 kb and 2 kb of 5'-flanking sequences show normal expression pattern of the E alpha gene, it appears that deletion of 5'-flanking sequences between -1.4 kb and -2 kb inactivated or eliminated regulatory sequences required for expression of E alpha specifically in B cells. The presence of pBR327 DNA linked to the -1.4 kb E alpha transgene suppresses expression in peripheral adherent cells, yielding mice expressing E alpha only in the thymus. These mice appear to be tolerant to I-E, as measured in mixed leukocyte response experiments.

Tissue-specific, inducible and functional expression of the E alpha d MHC class II gene in transgenic mice.

We have introduced the class II E alpha d gene into (C57BL/6 X SJL) F2 mice which do not express their endogenous E alpha gene. The mRNA expression of the E alpha d gene shows the same tissue distribution as the endogenous class II genes except in the case of one mouse, which carried 19 copies of the E alpha d gene. In this mouse expression of E alpha d mRNA was seen in all tissues tested. Expression of the transgene was induced by gamma-interferon in isolated macrophages from the transgenic mice. In addition, fluorescence activated cell sorter (FACS) analysis, mixed lymphocyte response and antigen-presentation experiments showed that the product of the transferred gene is expressed on the cell surface and functions as a major histocompatibility complex restriction element. Transmission of the gene occurred only with female transgenic mice, all males were infertile or did not transmit the gene, suggesting an effect of the transferred DNA sequence on male reproductive function.

Presentation of antigen by B cells: functional dependence on radiation dose, interleukins, cellular activation, and differential glycosylation.

Whether resting B cells can present antigen to T cells is controversial. Several factors can influence the outcome of an assessment of the presenting function of resting B cells: the method of purifying resting B cells and maintaining them in culture without altering their resting state, the sensitivity of resting B cells to gamma-irradiation, the activation state of the T cells used to assess presenting function, and the requirement for exogenous interleukin 1. We have examined all of these variables and find that one adherent antigen-presenting cell is functionally equivalent to four LPS-activated B cells and to 1000 resting B cells. In addition, we have examined the potential functional relevance of the differential glycosylation of Ia molecules on resting B cells compared with adherent antigen-presenting cells. Altering the surface glycosylation of resting B cells by neuraminidase treatment results in a 25-fold increase in B cell antigen presentation without altering their resting state. More important, among antigen-presenting cells the effect of neuraminidase is limited to resting B cells. It also appears to involve a restricting element such as the Ia molecule rather than total cell surface charge, because neuraminidase treatment has no effect on the capacity of resting B cells to serve as accessory cells in the Con A response.

Does T-cell restriction to Ia limit the need for self-tolerance?

Why did two classes ofMHC molecule evolve as restricting elements in T-cell function? Here Carol Cowing discusses the hypothesis that incomplete self-tolerance may explain the necessity for class II MHC restriction.

T cells discriminate between Ia antigens expressed on allogeneic accessory cells and B cells: a potential function for carbohydrate side chains on Ia molecules.

Previous studies have shown that the peptides obtained from accessory cell and B-cell Ia molecules are identical but that the alpha chains of B-cell Ia molecules are more extensively sialylated than those of accessory cells. The present studies were designed to determine whether this glycosylation difference can account for the functional difference in the capacity of the two cell types to activate alloreactive T cells. The experimental data show that normal resting B cells lack the capacity to induce DNA synthesis or differentiation in alloreactive T cells. T cells do recognize polymorphisms in B-cell Ia molecules, however, because they can be specifically primed for a subsequent proliferative stimulus of the same haplotype. The mitogenic signal for T cells is delivered by either allogeneic accessory cells or neuraminidase-treated B cells. Therefore, the T-cell receptor(s) may contain a site specific for the nonpolymorphic asialocarbohydrate moiety on the alpha chains of accessory cell Ia molecules.

Differential glycosylation of murine B cell and spleen adherent cell Ia antigens.

Examination of I-A and I-E molecules from purified B cells and splenic adherent cells from various haplotypes revealed a consistent difference in isoelectric focusing (IEF) that has been localized to the alpha-chain. alpa-Chains from B cells appeared heterogeneous and contained acidic IEF bands absent from the adherent cell I-A molecules. No difference in Ia beta-chain or H-2 IEF patterns was observed when B cell and adherent cell preparatios were compared when B cell and adherent cell preparations were compared. I-A alpha-chain preparations from the 2 cell sources showed no differences in 3H-leucine-labeled tryptic peptides separated by reverse-phase high-pressure liquid chromatography. Digestion with neuraminidase, kinetics of labeling, and subcellular distribution indicated that the extra acidic IEF bands in B cell Ia represent a mature, more heavily sialated form of alpha-chain that is not present in adherent cells. The selective differential glycosylation of B cell and adherent cell Ia could have some relation to the function of those cell types or to cell type-specific recognition of those cells.

Characterization of the stimulator cells in the murine primary mixed leukocyte response.

Macrophage-enriched and depleted spleen cell populations were examined for their ability to stimulate a murine 1 degree mixed leukocyte response. A quantitative comparison of unfractionated spleen cells, Sephadex g-10 passed spleen cells, 4-hr glass adherent and 24-hr glass adherent spleen cells revealed that a potent 1 degree MLR stimulator cell was phagocytic and that T and B lymphocytes failed to stimulate a response. By using several inb;ed and recombinant mouse strains congenic for different subregions of the MHC, it was found that macrophage-enriched cells were capable of inducing an MLR against K, D, I-A, and I-E differences and against K and D mutants. Both macrophage-enriched and depleted spleen cells failed to stimulate responses when the stimulator and responder differed at I-J, I-C, S, or G. Moreover, MLR stimulation induced by K or D region differences alone was dependent upon stimulator cells that expressed Ia antigens. Therefore, it would appear that only a minor subpopulation of the cells that express the relevant MHC alloantigens is immunogenic in the murine 1 degree MLR.

A subpopulation of adherent accessory cells bearing both I-A and I-E or C subregion antigens is required for antigen-specific murine T lymphocyte proliferation.

A murine T lymphocyte proliferation assay that used antigen-primed lymph node T cells, was antigen specific, and required exogenous accessory cells was used to characterize the accessory cells that supported proliferation. These cells were Thy 1.2 negative, radioresistant, glass-adherent, and were functional only if alive. The accessory cell function of spleen adherent cells was much greater than that of peritoneal cells. Also, the accessory cell function of spleen adherent cells was proportional to the length of time such cells were incubated with antigen and very small numbers of such cells provided accessory cell function. Cytotoxic studies with subregion-restricted anti-Ia antibodies and complement indicated that accessory cell function resided in a subpopulation of spleen adherent cells that bore both I-A and I-E or C subregion antigens. The function of such cells was not related to a selective ability (vs other spleen adherent cells) to take up antigen. These data indicate that antigen-specific stimulation of T lymphocyte proliferation requires at least one specific subpopulation of spleen adherent cells that can be phenotypically identified by its expression of Ia antigens and are consistent with the possibility that Ia antigens may be Ir gene products.

Cellular and genetic control of antibody responses in vitro. III. Immune response gene regulation of accessory cell function.

The possibility was investigated that Ir genes regulate the function of cells other than T or B cells in the primary IgM responses to the synthetic antigens trinitrophenylated poly-L-(Tyr,Glu)-poly-D,L-Ala--poly-L-Lys [TNP-(T,G)-A--L]and trinitrophenylated poly-,-(His,Glu)-poly-D, L-Ala--poly-L-Lys [TNP-(H,G)-A--L]. The primary responses of (B10 x B10.A)F(1) spleen cells to both antigens were abrogated by Sephadex G-10 passage, and restored by the addition of spleen adherent cells. The cell type in the spleen adherent cell population active in reconstituting the responses to TNP-(T,G)-A--L and TNP-(H,G)-A--L was a non-T, non-B, radiation-resistant, glass-adherent spleen cell. The responses of Sephadex G-10-passed (responder x nonresponder)F(1) spleen cells to TNP-(T,G)-A--L or TNP-(H,G)-A--L were reconstituted by spleen adherent cells from only responder strains. Spleen adherent cells from F(1) mice reconstituted the responses to both antigens. Spleen adherent cells from each of the strains tested reconstituted the non- Ir gene-controlled response to a third antigen, TNP-keyhole limpet hemocyanin. The inability of spleen adherent cells from nonresponder strains to reconstitute the responses to either TNP-(T,G)-A--L or TNP-(H,G)-A--L was not a result of active suppression induced by the presence of nonresponder adherent cells, since a mixture of responder and nonresponder spleen adherent cells reconstituted the responses to both antigens. The use of spleen adherent cells from recombinant strains demonstrated that the autosomal dominant genes controlling the ability of spleen adherent cells to function as accessory cells in the responses to TNP-(T,G)-A--L and TNP-(H,G)-A--L are located in the K or I-A regions of the responder H-2 complex, the same region(s) of H-2 as the Ir genes controlling overall in vitro and in vivo responsiveness to these antigens.

Macrophage Ia antigens. I. macrophage populations differ in their expression of Ia antigens.

By indirect immunofluorescence and microcytotoxicity it was demonstrated that different populations of murine macrophages bear different amounts of Ia antigens on their membranes. At least three subpopulations could be distinguished: those that lack Ia antigens and predominate in peritoneal exudate; cells bearing I-A antigens that are the majority of splenic macrophages and a minor population in the peritoneum; and cells bearing I-C antigens that are a minor population in both spleen and peritoneum. Internal radioisotope labeling studies confirmed that the I region molecules are synthesized by the macrophages. It is suggested that these different macrophage subpopulations may play distinct roles in the immune response.

Immunologic tolerance to heterologous immunoglobulin: its relation to in vitro filtration by macrophages.

The cellular and molecular basis for the difference in ability of BCG to induce tolerance in BALB/c and DBA/2 mice has been examined by in vitro biofiltration. It was found that incubation with the adherent cells from BALB/c but not DBA/2 spleens could remove the material from BGG which inhibited tolerance induction in BALB/c mice. This material was shown to represent only a trace component in BGG, was present in only certain commercial batches of BGG, and was apparently unrelated to the presence of aggregates or endotoxin.

Strain differences in ease of tolerance induction to bovine gamma-globulin: dependence on macrophage function.

DBA/2 mice are highly susceptible while BALB/c mice are resistant to the induction of tolerance with ultracentrifuged BGG. As measured by the clearance of a test dose of 125-I-BGG, 2 mg ultracentrifuged BGG is sufficient to induce complete tolerance in DBA/2 mice, while BALB/c mice exhibit a clearance rate similar to immune controls. BALB/c mice pretreated with carrageenan (a macrophage toxic agent) lose their resistance to tolerance induction with 2 mg ultracentrifuged BGG, while treatment with cobra venom factor does not alter their resistance to tolerance induction. Stimulation of the reticuloendothelial system with BCG produces a reduction in the susceptibility to tolerance of DBA/2 mice. This effect is transitory, with the maximum effect 3 weeks after BCG infection. Biologic filtration of BGG through BALB/c mice results in a preparation which is highly tolerogenic for recipient mice and this ability to filter the immunogenic portion of BGG is radioresistant. The results provide evidence for the concept that the differential susceptibility to the induction of tolerance is related to a macrophage function in the inductive phase of immunity.