Expression of I-A and I-E,C region-coded Ia antigens on functional B cell subpopulations.

Ia antigens from specific subregions have been examined on functional B cell populations. Expression of both I-A and I-E,C region antigens was demonstrated on cells required for both lipopolysaccharide mitogenesis and polyclonal activation. Similar I-A and I-E,C subregion expression was found on cells required for response to the T-independent antigen, polyvinylpyrrolidone. TNP-specific IgM and hen egg lysozyme-specific IgG plaque-forming cells also express I-A and I-E,C region antigens. No evidence was found for an Ia- population responsive in the systems tested. Further, no evidence of preferential expression of I-A or I-E,C region antigens was observed in any system examined. Therefore, it appears that B cells express both I-A and I-E,C region-coded Ia antigens.     

A single monoclonal anti-Ia antibody inhibits antigen-specific T cell proliferation controlled by distinct Ir genes mapping in different H-2 I subregions

A xenogeneic rat anti-mouse Ia monoclonal antibody, M5/114 (gamma 2b, kappa), was studied for its effects in vitro on T cell proliferative responses. Strain distribution studies revealed that M5/114 could inhibit I-A subregion-restricted T cell responses of the H-2b,d,q,u but not the H-2f,k,s haplotypes, indicating that this xenoantibody recognizes a polymorphic determinant on mouse Ia molecules. This same monoclonal antibody was found to inhibit BALB/c (H-2d) T cell proliferation to both G60A30T10 and G58L38 phi 4. The Ir genes regulating responses to these antigens map to either the I-A subregion (GAT), or the I-A and I-E subregions (GL phi), raising the possibility that M5/114 recognizes both I-A and I-E subregion-encoded Ia glycoproteins. It could be shown, using appropriate F1 responding cells, that M5/114 does in fact affect GAT and GL phi responses by interaction with both the I-A and the I-E subregion products, and not by any nonspecific effect resulting from binding to the I-A subregion product alone. These results are consistent with genetic and biochemical studies directly demonstrating that M5/114 recognizes A alpha A beta and E alpha E beta molecular complexes. The existence of a shared epitope on I-A and I-E subregion products suggests the possibility that these molecules arose by gene duplication. Finally, the precise correlation between the Ia molecules recognized by M5/114 and the ability of this antibody to block T cell responses under Ir gene control strengthens the hypothesis that Ia antigens are Ir gene products.     

Suppression of anti-hapten antibody responses by hapten-specific cytolytic T lymphocytes: role of I-A-associated antigen on target B lymphocytes

Cytolytic T lymphocytes (CTL) specific for 2,4,6-trinitrophenyl (TNP) determinants suppress the effector phase of a secondary anti-TNP antibody responses of murine syngeneic spleen cells in vitro. The cells mediating this suppression are hapten-specific, H-2-restricted, and possess properties typical of CTL. Moreover, the targets of the suppression appear to be antigen-primed B lymphocytes that are recognized by CTL via soluble antigen bound noncovalently to their Ig receptors. The effect of the CTL can be blocked by the addition of monoclonal antibodies directed against I-A molecules but not I-E or H-EK-encoded molecules on the target B cells, even in strain combinations in which the CTL-B cell interaction is restricted only by the H-2K and I regions of the MHC. This result suggests that B lymphocyte-bound antigen tends to associate preferentially with I-A rather than H-2K/D-encoded determinants, and that the suppressive effect of the CTL population is attributable to the minor subset that recognizes hapten-modified Ia antigens. These findings are also discussed in terms of the possible immunoregulatory function of Ia-restricted CTL.     

Regulation of immune responses via genetically restricted cellular interactions. II. I-region-restricted cooperation between idiotypic and anti-idiotypic B lymphocytes

Immunization of BALB/c mice with MOPC-104E myeloma protein induced idiotype-specific enhancing cells which acted on anti-dextran antibody-producing cells. The enhancing cells have surface phenotypes of B cells. Using BALB/c H-2 congenic strains, it was found that the cooperation between anti-idiotypic-enhancing B lymphocytes and dextran-primed B lymphocytes was controlled by major histocompatibility gene complex. Here we have described the loci which restrict the successful cooperation between B lymphocytes, wherein it was revealed that the interaction was restricted to the I-A and I-E subregions in H-2k haplotype and the I-A subregion in H-2b haplotype. Utilizing several monoclonal antibodies specific for Ia antigens, it was revealed that the enhancing B lymphocyte activity was completely inhibited by the pretreatment of antibody-producing B cells with anti-Ia.7 in H-2d haplotype as well as H-2k, and with anti-I-A antibody in H-2b haplotype. The results suggest that the anti-idiotypic B-lymphocyte response to the self idiotype is under control of H-linked immune response (Ir) gene.     

Isolation of twelve monoclonal antibodies against Ia and H-2 antigens. Serological characterization and reactivity with B and T lymphocytes

The cell hybridization technique was used for the production of 12 monoclonal antibodies against H-2K^k, H-2D^b, I-A^k and I-E^k antigens. The strain distribution pattern indicated that three antibodies reacted with new H-2 and Ia determinants, respectively, while the majority of determinants defined by the monoclonal antibodies showed good correlation with H-2 and Ia determinants described by conventional alloantisera.Monoclonal Ia antibodies showed strong reactivity with about 90% of surface IgM positive B cells, but not with T cells. In double fluorescence studies, both I-A and I-E determinants were always found to be coexpressed on the same B cells. When the high sensitivity of the fluorescence activated cell sorter was utilized, about 30 to 40% of purified lymph node T cells were found to carry both I-A and I-E antigens, although in a much lower density than B cells. In conclusion, monoclonal Ia antibodies appear to display the same serological and cellular reactivity pattern as do conventional antisera.     

In vivo treatment with monoclonal anti-I-A antibodies: disappearance of splenic antigen-presenting cell function concomitant with modulation of splenic cell surface I-A and I-E antigens

A single injection of anti-I-Ak antibody (AB) into H-2k mice resulted in abrogation of splenic antigen-presenting cell (APC) function for protein antigen-primed T cells or alloantigen-specific T cells. Spleen cells from anti-I-A-treated mice are not inhibitory in cell mixing experiments when using cloned antigen-specific T cells as indicator cells, thus excluding a role for suppressor cells in the observed defect. Also, nonspecific toxic effects and carry-over of blocking Ab were excluded as causes for the defect. Experiments with anti-I-Ak Ab in (H-2b X H-2k)F1 mice showed abrogation of APC function for T cells specific for both parental I-A haplotypes. In homozygous H-2k mice, anti-I-Ak treatment not only abrogated APC function for I-Ak-restricted cloned T cells but also for I-AekE alpha k-restricted cloned T cells. FACS analysis of spleen cells from anti-I-Ak-treated (H-2b X H-2k)F1 mice revealed the disappearance of all Ia antigens (both I-A and I-E determined), whereas the number of IgM-bearing cells was unaffected. The reappearance of APC function with time after injection was correlated with the reappearance of I-A and I-E antigen expression. In vitro incubation of spleen cells from anti-I-A-treated mice led to the reappearance of Ia antigen expression and APC function within 8 hr. Thus, it appears that B cells (as determined by FACS analysis) and APC (as determined by functional analysis) behave similarly in response to in vivo anti-I-A Ab treatment. We interpret these findings as suggesting that in vivo anti-I-A treatment temporarily reduces the expression of Ia molecules through co-modulation on all Ia-bearing spleen cells, thereby rendering them incompetent as APC. Such modulation of Ia molecules does not occur when spleen cells are incubated in vitro with anti-I-A antibodies. These results imply that a primary defect purely at the level of APC in anti-I-A-treated mice may be responsible for the observed T cell nonresponsiveness when such mice are subsequently primed with antigen.     

Expression of the I-E target antigen for T-cell killing requires two genes

TheH?2I ^k region encodes at least two different target antigens for unrestricted T-cell mediated killing. The first is controlled by theI?A region alone and the second depends on a pair of alleles, one located to the left ofI?B (presumably inI?A) and the other to the right ofI?J (presumably inI?E). Hence, effector cells nominally specific for a product of theI?E region do not kill target cells with the sameI?E region as the stimulator unless theI?A region is also shared. Some effectors specific forH?2I ^k , such as A.TH anti-A.TL and B10.A(4R) anti-B10.A(2R), cross-react with B10.A(3R) and B10.A(5R) target cells. A product of theH?2 ^b haplotype was shown to complement products of theH?2 ^d orH?2 ^k haplotypes in forming this cross-reactive determinant. The results are consistent with recent biochemical data on the component chains of Ia antigens.     

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.     

Sharing of Ia antigens between species. IV. Interspecies cross-reactivity of monoclonal antibodies directed against polymorphic mouse Ia determinants

The specificity of interspecies Ia cross-reactions has been analyzed by testing a panel of monoclonal antibodies (mAb) to mouse I-E and I-A antigens for reactivity with pig Ia antigens. Our earlier studies showed that mouse anti-I-E alloantisera recognized common determinants on Ia antigens of other species, whereas anti-I-A alloantisera showed much more limited cross-reactivity. These results were confirmed using a panel of 17 anti-I-E mAb, 10 of which were cytotoxic to pig cells. 2D gel electrophoretic analyses of precipitates with these mAb of 35S-labeled, NP40 solubilized pig cells revealed a limited set of protein spots that appeared to be identical to the subset of pig Ia antigens precipitated by A.TH anti-A.TL alloantiserum. Because the cross-reactive mouse sera were produced in mouse strains that do not express an I-E molecule (H-2b and H-2s), it was anticipated that the cross-reacting antibodies would be reactive with the monomorphic determinant of the I-E molecule, Ia.7. However, comparison of the reactivity of these mAb with pig cells and mouse cells revealed that the cross-reactivity on pig cells correlated not with Ia.7 but rather with detection of epitope(s) of the I-E molecule associated with inter-strain polymorphism. Anti-I-A cross-reactions were also detected, but were weaker and more limited. These findings may have implications for the evolution of Ia antigens in mammalian species.     

Characterization of the target cell antigen in I region-mediated lympholysis.

Cytotoxic T lymphocytes (CL) can be produced by culturing I region disparate spleen cells as previously reported. More recently, it was shown that these CL can lyse other target cells which shared only the I-A subregion with the stimulator cells, i.e., lysis of these target cells is not H-2K/D restricted. Since I region-mediated lympholysis represents the only strong exception ruling out the obligatory role for H-2K/D products in mediating cytolysis of target cells, it is important to characterize further the target antigen recognized by CL in this system.A.TH anti-A.TL or (A.TL × B10.A) Fl anti-B10.HTT CL were generated in a 4-day primary culture system. The CL, shown to be Thy-1⁺, are able to kill targets that share only the central region of H-2 with the stimulator cells. These I region-specific CL can also lyse target cells that express a cross-reacting Ia antigen with the stimulator cells. Incompatibilities at IA/IB and IE/IC gave stronger cell-mediated lympholysis than incompatibilities at IA/IB only. Experiments involving the use of cold target competition, inhibition by specific anti-Ia serum, and target cells containing different proportions of Ia⁺ cells, strongly suggest that the target antigens recognized by the CL are in fact Ia antigens.     

Expression of I-region gene products on mouse tail epidermis cells.

Mouse epidermal cells express Ia antigens. Epidermal cells from C3H and B10. A mice express I-A and I-E region gene products. Products associated with I-B and I-J were not detectable. A weak reaction was seen with anti-I-C sera. Products of the I-A region appear to be preferentially expressed when compared to I-E-region gene products. Ten percent of epidermal cells possess IgG-specific Fc receptors and 15% of epidermal cells can phagocytize latex particles. Our studies suggest that Ia-positive epidermal cells in mice are not necessarily limited to Langerhans cells.     

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.     

Properties of H-2L locus products in allogeneic and H-2 restricted, trinitrophenyl-specific cytotoxic responses.

The role of the recently defined L antigen (a second D region product) in allogeneic and TNP-specific syngeneic primary CML responses has been investigated. The lysis by anti-L specific cytotoxic effector cells was not inhibited when the target cells were pretreated with an antiserum directed against K and D, whereas an antiserum against L completely abrogated this response. Therefore, H-2L products are recognized on the target cell independently of H-2K and H-2D locus products. Both A.SW cells as well as B10 cells were found to respond to Ld alloantigens, in addition to Dd alloantigens when stimulated by cells differing only in the D region. The results of cold target blocking and antiserum inhibition experiments failed to detect cytotoxic cells with specificity of L antigens in association with TNP, under conditions in which TNP-specific effectors to K and D antigens were demonstrable. These findings suggest that there is a more limited involvement of H-2L locus products than the H-2K or H-2D locus products in the induction and specificity of these responses.     

Serological Cross-Reactivities of Murine and Human Class II Antigen Determined by Murine Xeno Anti-Human Class II Antibody

Murine anti-human class II antibodies were shown to cross-react with polymorphic determinants of murine class II antigens. The cross-reacting antibodies were raised in B10.S(9R) mice by immunizing with human nylon wool adherent cells (Ad cells) from peripheral blood leukocytes. The B10.S(9R) anti-human Ad cell antiserum bound to the molecules consisting of two chains with molecular weights of 35K and 28K dimers which were purified with a lentil-lectin column. The B10.S (9R) anti-human class II antiserum was also revealed to contain two distinct cross-reacting antibodies with polymorphic determinants of murine class II antigens coded for by the I-A subregion of the H-2. One is specific for a determinant of class II molecules coded for by I-A^b,d,q, and the other seems to be specific for class II molecules coded for by I-A^a,k,r.     

Arsonate-specific murine T cell clones. IV. Properties of I-E- and I-A-restricted clones

The T cell antigen L-tyrosine-p-azobenzenearsonate is unique in being a simple determinant that can be presented in the context of both I-A and I-E. I-E-restricted T cell clones derived from B10.A(5R) mice were found to fall into three groups: Type I clones recognized antigen only in the context of syngeneic apcs, Type II clones recognized antigen with the same highly specific major histocompatibility complex restriction but in addition proliferated in response to allogeneic stimuli; Type III clones were "degenerate" in their major histocompatibility complex-restricted recognition of antigen and proliferated when antigen-presenting cells bearing Eb beta Ek alpha (syngeneic), Ek beta Ek alpha, or Ed beta Ed alpha were used. These observations allow some conclusions to be drawn about sites on the I-E molecule that may be functionally significant in the presentation of this antigen. By using the B cell hybridoma LK35.2 as target cells, some of these T cell clones act as cytotoxic cells in the Class II-restricted manner predicted from the results of proliferative assays. Class II-restricted cytotoxicity can therefore be controlled by both I-A and I-E mouse Ir gene loci.     

Acquisition of syngeneic I-A determinants by T cells proliferating in response to poly (Glu60Ala30Tyr10)

The T cell proliferative response in mice to the synthetic polymer GAT is under Ir gene control, mapping to the I-A subregion of the H-2 major histocompatibility complex (MHC). Antigen-dependent proliferation in vitro of in vivo GAT-primed lymph node cells can be inhibited by a monoclonal antibody to Ia-17, an I-A public determinant. Using this antibody for direct immunofluorescent analysis, T cells in GAT-stimulated proliferative culture are identified that express syngeneic I-A during culture. This expression is strictly antigen dependent, requires restimulation in vitro, and requires the presence of I-A-positive adherent antigen-presenting cells. T cells bearing I-A can be enriched by a simple affinity procedure, and I-A-positive cells separated on a FACS are shown to retain antigen-specific reactivity. The acquisition of I-A determinants by T cells under these culture conditions is not nonspecific. The Ia determinants borne by T cell blasts appear to be dictated by the I subregion to which the relevant Ir gene maps, and which codes for the Ia molecule involved in presentation of the antigen. Thus, (B6A)F1 (H-2b X H-2a)F1 LNC express I-Ak antigens when proliferating to GAT but not when stimulated by GLPhe, the response to which is under I-E subregion control. The relation of Ir gene function to Ia-restricted antigen presentation and self-Ia recognition is discussed.     

Surface expression and synthesis of I-A and I-E/C encoded molecules by B lymphocytes and Ig-secreting cells.

Splenocytes from recombinant mice were radiolabeled before or after deletion of subpopulations by cytotoxic anterisera (+C) directed against I-A, I-E/C, IgM, or Ig. Examination of the lysates of the surviving cells by immunoprecipitation demonstrated that 1) virtually all I-A and I-E/C molecules are co-expressed and synthesized by Ig+, IgM+ lymphocytes, 2) I-A, I-E/C, and IgM molecules are present on many of the cells secreting IgM and IgG, and 3) populations of Ig-bearing or Ig-secreting cells that lack detectable I-A and I-E/C antigens can be identified in spleen cell populations. The co-expression of I-A and I-E/C on most cells of the B cell lineage is discussed in terms of our present concepts of Ir gene control of immune responses.     

H-2 I alloantigens and recall of memory cytotoxic responses

AQR mice were immunized with H-2K and H-2 I encoded alloantigens presented by (Ax6R)F₁ splenocytes. Spleen cells from these alloimmune mice were subsequently restimulated in vitro with B10.A lymphocytes and/or B10.T(6R) lymphocytes, thus presenting them with the immunizing H-2K and H-2 I alloantigens independently. When stimulated with B10.A lymphocytes, alloimmune lymphocytes develop significant cytotoxicity against the immunizing H-2K target antigens. When stimulated with a similar number of B10.T(6R) spleen cells, alloimmune lymphocytes undergo a prominant proliferative response, but develop little, if any, cytotoxicity against the immunizing H-2 K target antigens. The most efficient restimulation of cytotoxicity occurs when the alloimmune spleen cells are simultaneously restimulated by B10.A and B10.T(6R) lymphocytes. Stimulation with the immunizing H-2 I alloantigens alone is not sufficient for regeneration of detectable cytotoxic responses from alloimmune spleen populations. Stimulation with the immunizing H-2K alloantigens alone appears to be both necessary and sufficient to stimulate alloimmune cytotoxic responses. Although the immunizing H-2 I alloantigens are apparently not required to generate alloimmune cytotoxic responses, they markedly potentiate the cytotoxic responses induced by the immunizing H-2K alloantigens.     

Properties of reticulum cell sarcomas in SJL/J mice

While T cells from SJL and from F₁ hybrids of SJL that do not express I-E antigens give strong proliferative responses to RCS, T cells from F₁ hybrids expressing surface I-E do not. The nature of the stimulating antigen on the RCS cell surface was examined using monoclonal antibodies. Complete inhibition of the T-cell proliferative response was obtained with antibodies to I-A antigens, whereas antibodies to I-E antigens did not inhibit at all. This inhibition was mediated via an effect of the antibodies on the stimulating cells. Biochemical characterization of immunoprecipitated ¹²⁵I- and 's S-labeled RCS antigens was performed using two-dimensional gel electrophoresis. Using this technique, I-A antigens were readily detected. However, neither Ia.7-specific antibodies nor antibodies specific for E_α : E _β complexes precipitated any E alpha or E beta chains. Comparison of I-A antigens from RCS and normal SJL spleen cells revealed minor mobility differences in the gels, possibly due to differences in glycosylation, the significance of which needs to be further evaluated. Examination of RNA extracted from RCS, using E alpha and A alpha cDNA probes showed that RCS cells do not transcribe the E alpha gene as has been shown previously for normal H-2 ^s cells. Furthermore, DNA from RCS cells showed a defect in the E alpha gene similar to that known to exist in normal H-2 ^s cells. Our findings exclude the presence of E alpha on RCS cells and suggest a major role for I-A, either alone or in conjunction with another as yet unidentified cell surface antigen, in the stimulation of T cells.     

Genetic analysis of Ia determinants expressed on Con A-reactive cells.

Pretreatment of mouse lymphoid cells with anti-Ia sera and C abrogated the proliferative responses of these cells to Con A. Studies were carried out with several anti-Ia reagents and intra-H-2 recombinant mouse strains to map the I subregion(s) whose products are expressed on Con A-reactive cells. Treatment with a (B10.A X A)F1 anti-B10 reagent and C abrogated the ability of BALB/c cells to respond to Con A. Absorption studies on this reagent demonstrated that Con A-reactive cells express Ia determinants coded by the I-A subregion. The results with two additional reagents, B10.A(4R) anti-B10.A(2R) tested on B10.BR cells and (B10 X D2.GD)F1 anti-B10.D2 absorbed with B10.A cells and tested on BALB/c cells, demonstrated that Con A-reactive cells also express Ia determinants encoded to the right of I-A. Several antisera and strain combinations were evaluated in which the antisera could contain antibodies specific for products of genes encoded by the I-J subregion, but the results were inconclusive. These data demonstrate that there are at least two different I subregions, one in I-A and one to the right of I-A, that code for antigens expressed on Con A-reactive cells.