Characterization of responding cells in oxidative mitogen stimulation

Ia antigens coded by genes of the murine major histocompatibility complex are expressed on the surface of a population of cells critical to the proliferative response of murine spleen cells to the oxidative mitogen neuraminidase/galactose oxidase. By selective depletion with antiserum and complement, Ia antigens coded (or determined) by theI-A andI-J, E, C subregions of theIr region can be detected on the surface of cells required for the response. In addition, I-A-subregion products have a functional significance in cellular activation which can be demonstrated by blocking experiments with anti-la serum in the absence of complement.     

The distribution of Ia antigens on the surfaces of lymphocytes.

The distribution of Ia antigens was studied on murine spleen lymphocytes by an ultrastructural technique employing deep freeze-etched replicas. Ia antigens were labeled on cells from appropriate congenic and recombinant strains of mice by incubating the cells with FITC-conjugated anti-Iak antibody, followed by ferritin-coupled Fab anti-FITC. Ia antigens were detected predominantly on immunoglobulin (Ig)-bearing B lymphocytes. Antigens coded for by the entire Ik region were present on the surfaces of 95% of the positive cells (from B10.BR mice) in densely packed microclusters. Ia specificities coded for by the I-A and I-C subregions (on 4R and B10.HTT mice) exhibited a more variable pattern, with 30 to 35% of the labeled cells having sparsely distributed Ia antigens in relatively discrete microclusters. Binding of anti-Iak antibody at 37 degrees C led to patch formation but not to capping. Modulation of surface Ig left Ia antigens diffusely distributed on the cell surface, indicating that these two membrane proteins are independent molecules.     

Characterization of a spontaneous murine B cell leukemia (BCL1). I. Cell surface expression of IgM, IgD, Ia, and FcR.

The surface marker expression of a spontaneous B lymphocyte leukemia discovered in a BALB/c mouse (BCL1) was examined and found to include a subset of markers known to occur on normal B lymphocytes. The tumor cells bore surface Ig that included both mu- and delta-chains associated with the lambda light chain. Alloantigens coded for within the murine MHC, including H-2D, H-2K, and I-region products, were identified on the tumor cells. Although normal B lymphocytes are thought to express products coded for within both the I-A and I-E subregions, the BCL1 expressed only normal amounts of I-E subregion products. In addition, the H-2 and Ia antigens revealed by 2-dimensional gel electrophoresis exhibited an abnormal pattern of post-translational modifications. The Fc, but not the complement-receptor, was present on the surface of tumor cells. The presence of IgD, Ia antigens, and the responsiveness to lipopolysaccharide (see subsequent paper) have led us to postulate that the BCL1 tumor represents a later differentiative stage than murine B lymphocyte tumors previously described.     

T lymphocyte-enriched murine peritoneal exudate cells. III. Inhibition of antigen-induced T lymphocyte Proliferation with anti-Ia antisera.

The recent development of a reliable murine T lymphocyte proliferation assay has facilitated the study of T lymphocyte function in vitro. In this paper, the effect of anti-histocompatibility antisera on the proliferative response was investigated. The continuous presence of anti-Ia antisera in the cultures was found to inhibit the responses to the antigens poly (Glu58 Lys38 Tyr4) [GLT], poly (Tyr, Glu) ploy D,L Ala-poly Lys [(T,G)-A--L], poly (Phe, Glu)-poly D,L Ala-poly Lys [(phi, G)-A--L], lactate dehydrogenase H4, staphylococcal nuclease, and the IgA myeloma protein, TEPC 15. The T lymphocyte proliferative responses to all of these antigens have previously been shown to be under the genetic control of major histocompatibility-linked immune response genes. The anti-Ia antisera were also capable of inhibiting proliferative responses to antigens such as PPD, to which all strains respond. In contrast, antisera directed solely against H-2K or H-2D antigens did not give significant inhibition. Anti-Ia antisera capable of reacting with antigens coded for by genetically defined subregions of the I locus were capable of completely inhibiting the proliferative response. In the two cases studied, GLT and (T,G)-A--L, an Ir gene controlling the T lymphocyte proliferative response to the antigen had been previously mapped to the same subregion as that which coded for the Ia antigens recognized by the blocking antisera. Finally, in F1 hybrids between responder and nonresponder strains, the anti-Ia antisera showed haplotype-specific inhibition. That is, anti-Ia antisera directed against the responder haplotype could completely block the antigen response controlled by Ir genes of that haplotype; anti-Ia antisera directed against Ia antigens of the nonresponder haplotype gave only partial or no inhibition. Since this selective inhibition was reciprocal depending on which antigen was used, it suggested that the mechanism of anti-Ia antisera inhibition was not cell killing or a nonspecific turning off of the cell but rather a blockade of antigen stimulation at the cell surface. Furthermore, the selective inhibition demonstrates a phenotypic linkage between Ir gene products and Ia antigens at the cell surface. These results, coupled with the known genetic linkage of Ir genes and the genes coding for Ia antigens, suggest that Ia antigens are determinants on Ir gene products.     

Antibody-dependent cellular cytotoxicity effector cells lack Ia antigens.

Surface immunoglobulin (sIg)-positive and sIg-negative subpopulations of macrophage-depleted murine splenic lymphocytes were obtained by Sephadex anti-Fab immunoabsorbent fractionation. These lymphocyte subpopulations were analyzed for the presence of Thy 1 and Ia alloantigens and also for Fc receptors by fluorescence microscopy. Concurrently, these lymphocyte subpopulations were studied for effector cell activity in antibody-dependent cellular cytotoxicity (ADCC). Effector cells mediating ADCC were contained in the sIg-negative lymphocyte subpopulation and sIg-positive lymphocytes did not mediate cytotoxicity. The majority of sIg-positive lymphocytes were found to bear Ia antigens and Fc receptors, and these cell surface structures were associated in that treatment of these cells with anti-Ia sera inhibited binding of complexed immunoglobulin to Fc receptors. In contrast, most sIg-negative, Thy 1-negative lymphocytes lacked Ia Antigens, and the Fc receptors detected on such cells were not blocked by anti-Ia sera. In addition, a small subpopulation of sIg-negative, Ia antigen-positive, Fc receptor-positive lymphocytes was found. Elimination of this subpopulation of Ia antigen-positive cells from sIg-negative lymphocytes, by treatment with anti-Ia serum and complement, did not diminish ADCC effector cell activity in the resultant cell population when compared with untreated sIg-negative lymphocytes. Thus, in murine spleen, nonphagocytic mononuclear cells that lack both sIg and Ia antigens were shown to mediate ADCC.     

Turnover and shedding of Ia antigens by murine spleen cells in culture.

Lactoperoxidase-catalyzed radioiodination was used to examine the metabolic fate of surface Ia antigens on murine spleen cells in culture. Ia antigens, detected predominately on splenic B lymphocytes, were lost from the cultured cells with biphasic kinetics: a 4 to 6 hr rapid phase, t 1/2 = 5 hr followed by slow release through 20 hr, t 1/2 = 30 hr. The rapid loss of Ia antigens observed was abolished by both harsh iodination conditions and nonphysiologic incubation conditions. The rapid decline in Ia activity was shown to be due to shedding of intact Ia antigens from the cell and to predominant release of IA subregion-coded proteins. Release of Ia antigens from the cell was accomplished by replacement at the cell surface, and thus reflected net membrane Ia turnover. Ia shedding was shown to be extremely temperature dependent, reflecting both a comparatively high activation enthalpy and entropy requirement for turnover.     

Selective effects of anti-Ia serum and complement treatment upon polyclonal B lymphocyte responses to dextran sulfate and lipopolysaccharide.

Subpopulations of B lymphocytes have been shown to vary in their expression of Ia alloantigens and polyclonal responsiveness to thymic independent antigens. We have demonstrated that the polyclonal B cell antibody response to dextran sulfate is less sensitive to removal of Ia-positive cells than is the response to LPS. This is a consistent finding whether alloantibody and complement (C) pretreatment is directed toward cells bearing Ia antigens coded for by the entire I region or by the I-A or I-E subregions. Heterogeneity appears to exist within the dextran sulfate-sensitive population in that using high antibody; cell ratios during antibody and C-mediated cell selection results in an inhibition of the proliferative but not the antibody response. This result may indicate a differential expression of Ia antigens on dextran sulfate-sensitive B cells that respond by proliferation versus those cells that produce antibody. Alternatively, proliferative responses to dextran sulfate may be more dependent upon Ia-positive accessory cells than is the polyclonal antibody response.     

A human alloantiserum precipitates Ia-like molecules from chronic lymphocytic leukemia cells.

Alloantigens specific for human B lymphocytes can be identified with selected antisera. These antigens have similarities to murine Ia antigens in that they are found on human B lymphocytes and are controlled by genes linked to genes controlling HLA. Chronic lymphocytic leukemia cells bearing B cell antigens were labeled with 3H leucine and the membrane components reacting with the B cell antisera isolated by immunoprecipitation. These membrane components had m.w. of 33,000 and 24,000 daltons similar to the murine Ia antigens. The results complete the homology of murine Ia and human B cell alloantigens.     

Hybrid Ia antigens: Genetic,serologic, and biochemical analyses

Ia specificities 22 and 23 were found to be determinants on hybrid Ia molecules, formed by the noncovalent binding of a 26,000–28,000 dalton beta polypeptide chain (A_e) coded by the I-A subregion and a 32,000–35,000 dalton alpha chain (E_α) coded by the I-E subregion. For expression of Ia. 23 the A_e chain, coded by the I-A subregion, must be derived from the H-2^d haplotype, while A^b, A^s, or A^k can provide the complementing beta chain for the expression of Ia. 22. For expression of Ia. 22 and Ia. 23, most Ia. 7 positive strains can provide the complementing alpha chain (E_α), with the one exception of B 10. PL (E^u), which is Ia. 7 positive but will not complement with A^d to express Ia. 23. Antisera were also produced against hybrid Ia antigens by immunizing with F₁ cells expressing Ia. 22 or Ia. 23 generated by transcomplementation. These antisera detect the same specificities as conventional anti-Ia. 22 and anti-Ia. 23 sera produced against cis-complementing Ia antigens. It is postulated that hybrid Ia determinants are involved in recognition and generation of immune response to antigens under dual Ir gene control. It is also suggested that there are 2 types of Ia specificities: (1) allotypic Ia specificities expressed on the alpha or beta chains (for example, Ia. 7 on the E_α chain) and (2) hybrid Ia specificities, which are unique interaction determinants formed by the association of alpha and beta chains (for example, Ia. 22 and Ia. 23). These interaction gene products may be involved in antigen recognition and presentation.     

The murine Kupffer cell. I. Characterization of the cell serving accessory function in antigen-specific T cell proliferation.

Murine Kupffer cells, the tissue macrophages of the liver, were isolated by collagenase digestion, differential sedimentation over Metrizamide, and glass adherence. The resultant cell population was more than 86% phagocytic, and 95% of cells stained positively for alpha-naphthyl butyrate esterase activity. The cells also had cell surface receptors for complement (C) and the Fc portion of IgG. In addition, a large proportion of Kupffer cells was shown to bear Ia antigens: about half of the cells bore I-A subregion-encoded antigens and about half bore I-BJE or I-EC subregion-encoded antigens. Kupffer cell populations were capable of reconstituting antigen-stimulated proliferative responses of antigen-primed, macrophage-depleted, lymph node T cells. The ability to reconstitute proliferation was enriched in the adherent population and was resistant to radiation and treatment with an anti-Thy antiserum and C. We conclude that isolated murine Kupffer cells bear the Ia phenotype of accessory cells that function in antigen presentation and that Kupffer cells can participate in the induction of antigen-specific immune responses. These data suggest that Kupffer cells may play a role in modulating responses to enterically derived antigens.     

Expression of ia antigens by murine keratinizing epithelial langerhans cells

Immunofluorescent and immunoelectron-microscopic staining methods were utilized to investigate the localization of Ia antigens in murine keratinizing epithelia. Approximately 3-5% of epidermal cells were shown to be Ia positive. Only dendritic Langerhans cells in the interfollicular epidermis and outer root sheaths were found to express Ia antigens. These Ia determinants were shown to be controlled by both theI- A andI- EC subregions of theH-2 complex. The results were confirmed by identifying positively stained cells containing Langerhans cell granules at the ultrastructural level. No staining was noted on the surface of keratinocytes, melanocytes, or immigrant lymphocytes. The results presented are in close agreement with those previously reported for Ia-bearing Langerhans cells in human and guinea pig epidermis.     

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.     

Molecular associations of class II MHC antigens in mitogen-stimulated B cells

Previously, we showed that murine B cell membrane proteins undergo rearrangements in the plasma membrane to form new molecular associations in response to mitogenic stimulation. These complexes were covalently stabilized by photoreactive cross-linking agents and were analyzed by SDS PAGE. We have now identified certain complexes that involve class II MHC products, the Ia antigens. Upon stimulation of B cells with LPS, Ia surface molecules (as identified by radioimmunoprecipitation with polyclonal anti-Ia antiserum) enter into a molecular complex with a 95-kd membrane-associated protein (p95) to form a 200-kd complex that may be stabilized by the cross-linking agent dithiobisphenylazide (DTPA). This molecular association is not observed upon stimulation with mitogenic anti-Ig reagents, nor with the polyclonal B cell activator 8-bromoguanosine. p95 is not a disulfide-linked molecule itself, and by separate immunoprecipitation experiments we have established that it is not a component of surface Ig, transferrin receptor, the B cell Fc receptor, or CR1, the receptor for complement component C3b. Further analysis of the association of Ia antigens with surface proteins, with the use of monoclonal antibodies directed against I-A or I-E, has demonstrated that each subregion gene product forms a unique molecular association. Precipitation of radiolabeled lysates from LPS-activated B cells with anti-I-A reveals the aforementioned association with p95. In contrast, the I-E antigen apparently forms complexes with a multimer of a 15-kd protein to give complexes of 45, 60, 75, and 90 kd. When analyzed by two-dimensional diagonal gels (nonreducing/reducing), only the I-E bands are revealed by autoradiography, indicating that the putative p15 that associates with I-E may not be accessible to surface labeling. The disparate molecular associations for I-A and I-E suggest that the formation of these distinct protein complexes may be functionally related to a different role in the process of cellular activation for each of these Ia subregion gene products.     

Expression and function of I region determinants on immunocompetent cells. I. Selective expression of I-C region determinants on immune cells.

We have examined the cytotoxic activity of anti-Iak serum and complement on various immune functions of BALB/c (H-2d) cells. Since the cytotoxic action of this antiserum on H-2d cells defines specificity Ia.7, an I-C region product, we have looked at the selective expression of this antigen. We have mainly used the in vitro anti-Lac2 response to study the cells involved in the induction and regulation of antibody. The data presented here show that Ia.7 is present on both IgM and IgG precursor B cells and in lesser amounts on plaque-forming cells. The antiserum also recognizes with less efficiency a product on specific T suppressor cells, which is possibly coded for by the adjacent I-J subregion. Both fluorescence and functional tests indicate the absence of Ia.7 on macrophages. It is also lacking on T helper cells. When we tested the antiserum on the in vitro cytotoxic responses to alloantigens, we found that neither T effector cells nor their precursors were affected.     

Epidermal Ia molecules from theI-A andI-EC subregions of the mouseH-2 complex

Immune response region-associated (Ia) antigens encoded by genes in theI-A orI-EC subregions have been detected on murine epidermal cells by indirect immunoprecipitation, using antisera produced against murine lymphoid cells. The Ia antigens encoded by genes in these subregions are composed of two polypeptides with approximate molecular weights of 33,000 and 28,000. The Ia antigens are not derived from contaminating B- or T-cell populations. The Ia molecules from lymphocytes and epidermal cells appear to have identical subunit structures and very similar, if not identical, molecular weights. The possible biological role of the Ia antigens on epidermal cells is discussed.     

T lymphocyte heterogeneity in the rat. III. Autoreactive T cells are activated by B cells

Evidence has been presented to show that CD4+ autoreactive T cell lines (ATs)2 in the rat require periodic stimulation with syngeneic spleen cells for in vitro proliferation. This proliferation can be blocked by treatment of the stimulator (spleen) cells with mAb to Ia antigens. Although ATs are Ia+ and can activate the allogeneic MLR, they fail to be autostimulatory. Fractionation of the spleen cells revealed that ATs can be stimulated with B cells and not by macrophages, although the latter were efficient in several accessory cell functions, including antigen presentation, lectin-dependent T cell activation and allogenic MLR response. Moreover, B cells proliferated and differentiated in response to AT cells. These data are compatible with a model in which ATs respond to hitherto undetermined B cell membrane antigen(s) in association with MHC class II antigens. These results may have important implications in understanding autoimmune responses.     

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.     

Murine class II (Ia) molecules associate with human invariant chain

Polymorphic class II (Ia) major histocompatibility complex (MHC) gene products associate intracytoplasmically with a third nonpolymorphic class II molecule, the invariant chain (Ii), which is encoded by gene(s) unlinked to the MHC. Although the role of the Ii chain in the expression of cell surface Ia molecules is unclear, it has been suggested that the Ii chain helps in the assembly and intracellular transport of class II antigens. In this study, we demonstrate that the murine polymorphic class II antigens of an interspecies mouse-human hybrid, which has segregated the murine invariant chain gene, associates with the human invariant chain gene intracytoplasmically. The murine Ia antigens are expressed on the cell surface and can function as restriction elements in antigen presentation to T cells. The biochemical analysis demonstrates that the regions of the Ii gene that are critical to its interaction with Ia molecules are conserved between species.     

Nature of the antigenic complex recognized by T lymphocytes. IV. Inhibition of antigen-specific T cell proliferation by antibodies to stimulator macrophage Ia antigens.

We have previously demonstrated that nonimmune guinea pig T lymphocytes could be specifically sensitized with TNP-modified allogeneic macrophages after eliminating the alloreactive T cells with bromodeoxyuridine (BUdR) and light treatment. This procedure allowed the unique opportunity to use anti-Ia sera directed against the Ia antigens of only the stimulator macrophages or responder T cells to determine against which cell type anti-Ia would block TNP-specific stimulation. It was found that the TNP-specific DNA synthetic response of BUdR and light-treated T cells stimulated with TNP-modified allogeneic macrophages was totally eliminated by anti-Ia sera directed solely against the allogeneic stimulator macrophage. In contrast, anti-Ia sera directed only against the responder T cells had no effect on their response to TNP-modified allogeneic macrophages. These findings indicate that macrophage Ia antigens are required for efficient T cell-macrophage interactions and raise the possibility that T cell Ia antigens may not be required for collaboration with macrophages. This latter possibility was substantiated by experiments in which we show that treating T cells with anti-Ia sera and complement to remove the Ia-positive cells either before or after priming, or both, had no effect on their ability to be primed and restimulated with TNP-modified macrophages.     

Partial characterization of Ia antigens from murine lymphoid cells

Congenic anti-Ia antisera were used to bind radiolabelled Ia antigens from cells of various strains of mice of knownH-2 haplotype. The results indicate that Ia antigens are proteins of molecular weight 30,000 to 35,000 daltons. The Ia antigens are distinct from known H-2 antigens as judged by independent immunoprecipitation as well as by molecular weight. Ia antigens are synthesized by, and are present on the surface of lymphoid cells as evidenced by incorporation studies using³H-leucine and enzymatic radioiodination of cells, respectively. Tissue distribution of cell surface Ia suggests that Ia antigens are on B cells. Ia antigens were detected in the incubation media of³H-leucine labeled splenocytes suggesting that antigens may be secreted.