Production of heterologous antibodies to T-killers of mice immunized against H-2 antigens

Rabbit antisera were obtained against cytotoxic small peritoneal lymphocytes (IPEL) of CBA (H-2k) mice immune to alloantigens C57BL/6 (H-2b) and to the enriched 5-day MLC cytotoxic blast lymphocytes (MLC--CL). After appropriate absorption by cells and tissues of intact mice the cytotoxicity of the sera was lost relative to normal lymphoid cells. The absorbed anti-CPL serum inhibited, in the presence of complement, the cytotoxic effect of CPL but not that of MLC--CL on 51Cr-labeled allogeneic macrophages. This inhibition was restricted by idiotypic and strain specificity. Conversely, the absorbed anti-MLC--CL serum inhibited the cytotoxic effect of both CPL and MLC--CL of various mouse strains, irrespective of their immunologic specificity. It is supposed that the effect of the anti-CPL serum is mainly caused by antibodies againts idiotypic determinants of the killer T receptors, whereas the effect of the anti-MLC--CL serum is due to antibodies against differentiation antigens of the proliferating lymphocytes.     

Detection of at least two distinct mouse I-E antigen molecules by the use of a monoclonal antibody

In an attempt to determine whether the expression of more than a single Ia antigen is determined by the I-E subregion of the mouse major histocompatibility complex (MHC), sequential immunoprecipitation analyses were performed by using a monoclonal antibody and alloantisera reactive with I-E subregion products. 3H-leucine-labeled glycoprotein preparations obtained from H-2d spleen cells were precleared with the monoclonal antibody 14-4-4S and then examined for residual Ia activity precipitable by an alloantiserum detected by SDS-polyacrylamide gel electrophoresis. Residual Ia activity was observed for all three strains of the H-2d haplotype tested. The residual Ia activity could be detected by sera absorbed with B10.A spleen cells, indicating that products of the I-E subregion rather than of the I-C subregion were responsible for this activity. No separable I-Ek molecules were detected in products of B10.A cells with the use of combinations of two monoclonal antibodies (including 14-4-4S) and several appropriate alloantisera. These findings indicate the presence of at least two similar but distinct I-E antigens encoded by the H-2d haplotype.     

Enhancement of murine T cell I-J expression by limited proteolysis

I-J-encoded structures on peripheral T cells and thymocytes appear normally to be blocked or shielded by material that is susceptible to proteolysis. Limited proteolysis with trypsin, papain, pronase, or chymotrypsin increased the number of peripheral T cells and thymocytes lysed by anti-I-Jk serum and complement. Proteolysis did not induce I-Jk expression on B cells or on negative strain T cells. Increased lysis was enzyme concentration and time dependent and was not due to increased susceptibility of protease-treated cells to lysis by antibody plus complement; proteolysis rendered T cells and thymocytes less susceptible to lysis by anti-H-2Kk, anti-H-2Dd, and anti-Lyt-2 antibodies. Absorption experiments showed that I-Jk determinant density was increased in the protease-treated T cell population. The I-Jk determinants detected are proteins or glycoproteins; extended proteolysis removed these molecules from the T cell surface. Treatment of T cells or thymocytes with activated macrophage culture supernatant containing proteolytic activity produced a small but reproducible increase in I-Jk expression. Proteolysis of lymphocyte membranes, possibly mediated by macrophages, may have a role in cellular differentiation and immune activation.     

Separation of the immune response genes for LDH-B and MOPC-173. II. Description of an immune response defect in B10.ASR7

By using the intra-I region recombinant mouse strain B10.ASR7 (H-2as3), the immune response (Ir) genes for LDH-B and MOPC-173 were genetically and serologically separated, as assayed by T cell proliferation. Previous work demonstrated that H-2s and H-2b strains respond to LDH-B and MOPC-173 whereas H-2a and H-2k strains failed to respond due to haplotype-specific suppression of I-Ak molecule-activated T helper cells by I-Ek molecule-activated T suppressor cells. In the experiments reported here, B10.ASR7 mice, which lack I-Ek expression, mounted a significant T cell proliferative response to LDH-B but not to MOPC-173. Separation of the Ia determinants used in restricting these two antigen responses was further confirmed when pretreatment of B10.S(9R) (A beta sA alpha sE beta sE alpha k) macrophages with A.TL anti-B10.HTT serum (anti-As beta Es beta Js) adsorbed with B10.ASR7 spleen cells blocked the MOPC-173 response but not the LDH-B response. Unadsorbed serum blocked both antigen responses. The B10.ASR7 E beta allele was determined to be s due to the ability of (A.TL X B10.ASR7)F1 hybrids to mount a T cell proliferative response to the terpolymer GLPhe. Monoclonal antibody blocking of the B10.ASR7 T cell proliferative response to LDH-B demonstrated that the Ia.2 and Ia.17, and not the Ia.15 epitopes are spatially related to the Ia epitopes involved in the restriction of the B10.ASR7 LDH-B T cell proliferative response. In addition, B10.ASR7 helper T cells generated in response to LDH-B were suppressed in a haplotype-specific manner by I-Ek molecule-restricted suppressor T cells in that (A.TL X B10.ASR7)F1 hybrids failed to respond to LDH-B. This nonresponsiveness was eliminated by treatment with monoclonal antibodies directed against the I-Ek molecule. These results suggest the possibility that the immune response defect in B10.ASR7 could be related to the site of recombination.     

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.     

Blocking action of the soluble H-2 antigens and H-2 antibody isolated by various methods and mouse immune lymphocytes]

The treatment of tumour and lymphoid cells of mice with 3M KC1 solution having high ionic strength, nonionic detergent and by subsequent freeze-thawing resulted in obtaining serologically active H-2 antigen preparation capable of specifically blocking the cytotoxicity of H-2 antisera. The antigenic activity of the preparations thus obtained depended on the source from which they were isolated (spleen cells and their membrane fragments proved to be the best source), on the degree of maturity of tumor cells and the degree of purification of the preparation, as well as on the methods of solubilization. The blocking action of soluble H-2 antigens on the cytotoxicity of immune lymphocytes depended on the method used for isslating these antigens. The interaction of immune lymphocytes and H-2 antisera with soluble antigens was probably effected by different mechanisms.     

Narrow specificity of T-suppressor receptors immune to H-2 complex antigens

Specific d anti-b and b anti-a suppressor T cells induced by intravenous injection of mice with gamma-irradiated allogenic lymphoid cells, are not a homogenous population of cells as shown by their selective absorption on macrophage monolayers of various H-2 haplotypes. This is proved by separation of suppressor T cells to two subpopulations, at least, each of them being able to react with the products of only one (K or D) end of the H-2 complex. Moreover, the fine specificity study of d anti-b suppressor T cells enriched by elution from macrophage monolayers of different H-2 haplotypes, demonstrated these suppressors to represent a set of narrow-specific clones, each of them carried receptors reactive in a selective fashion with a particular determinant of the H-2 molecule irrespective of this linkage with other products of the H-2 complex. Two such clones reactive with H-2a and H-2f third-party antigens, respectively, were isolated by elution from the corresponding cell monolayers, each of them accounted for about 1.5% of the total d anti-b suppressor population. These data are discussed in the light of differences of suppressor T cells from other T cell subclasses and their resemblance to B cells with respect to the clonal structure and the receptor specificity.     

F1 hybrid-anti-parental H-2b cell-mediated lympholysis: genetic control of target antigens by the H-2D region

The immunogenetic specificity of (C57BL/6 X DBA/2)F1 anti-parental C57BL/6 cytotoxic T lymphocytes (CTL) induced in primary mixed spleen cell cultures was determined in direct lytic and competitive inhibition assays. A large panel of peritoneal exudate cells (PEC) bearing nonrecombinant and recombinant H-2-Tla haplotypes was the source of target and inhibitor cells. All PEC of H-2b, H-2bc, H-2j, and H-2ja types, irrespective of background genetic constitution, were as susceptible to direct lysis as C57BL/6 PEC, but PEC of H-2a, H-2d, H-2k, H-2q, H-2s, and H-2u types were not. The possible involvement of the Tla region in controlling target antigens was excluded by testing PEC obtained from 4 H-2/Tla or intra-Tla recombinant mouse strains. The genes controlling target antigens were mapped to the D region with the aid of 9 intra-H-2 recombinants; for target PEC to be lysed it was necessary and sufficient that Db antigens be part of the H-2 phenotype. These results were confirmed by competitive inhibition assays. Resident peritoneal cells not exposed to fetal bovine serum were also lysed by F1 anti-parental H-2b CTL, a demonstration that target antigens are expressed on normal cells.     

Demonstration of H-2 antigens on preimplantation mouse embryos using conventional antisera and monoclonal antibody

Mouse embryos at the 2-cell, 8-cell, and blastocyst stages of development were examined for the presence of H-2 antigens by immunoperoxidase labeling and transmission electron microscopy. Conventional antisera made in congenic mouse strains were used to study embryos of four different haplotypes: b, a, k, and d. Blastocysts showed uniform heavy labeling of all cells of the trophectoderm, 8-cell embryos showed lighter labeling of only some of the cells, and 2-cell embryos showed no labeling. Similar results were found for all four haplotypes studied. In addition, monoclonal antibody 11-4.1 (anti-Kk) was reacted with homologous (H-2k) and heterologous (H-2b) blastocysts. Positive results with the monoclonal antibody corroborates the concept that H-2 antigens are expressed on early mouse embryos.     

Relationship between trinitrophenyl and H-2 antigens on trinitrophenyl-modified spleen cells. I. H-2 antigens on cells treated with trinitrobenzene sulfonic acid are derivatized.

Spleen cells were treated with TNBS in order to determine if cell surface H-2 antigens are derivatized with TNP. By labeling the cell membrane of the TNP-modified cells with 125I, followed by detergent lysis and immune precipitation with anti-TNP, it was determined that no H-2 antigenic activity remained in the supernatant. Further, by the use of an antibody-induced antigen redistribution assay it was found that previous exposure to TNP-modified cells to anti-TNP in the absence of complement rendered these cells resistant to lysis by anti-H-2 in the presence of complement. Together these data indicate that at the concentration of TNBS used for modification, H-2 antigens are derivatized with TNP. However, in addition to H-2, other proteins including immunoglobulin were also derivatized with TNP. Anti-TNP cytotoxic effector cells were blocked from their cytotoxic activity by anti-TNP antiserum. These data indicate that TNP directly couples to H-2 antigens on the cell surface of TNP-modified cells and that TNP is associated with the antigenic determinant that the cytotoxic T cell recognizes.     

The specificity and significance of the inhibition of Fc receptor binding by anti H-2 sera

The possibility that Ia antigens are unique among H-2 antigens in their relationship to the Fc receptor was investigated in an EA rosette assay. Antibody specific for antigens in various regions of theH-2 complex was incubated with mouse cells, and the ability of the cells to form rosettes with antibody-coated chicken erythrocytes was tested. Antibody raised against the H-2 antigens of Ia-negative tumor cells was highly effective in inhibiting rosette formation. A variety of antisera againstK-, I-, andD-region antigens tested in recombinant mice inhibited EA rosette formation, suggesting that antigens in each of these regions could be detected in rosette inhibition. The F(ab′)₂ fragments of all antisera tested also produced specific EA rosette inhibition. Finally, antibody against Ia antigens failed to inhibit bone marrow RFCs, although antibody against H-2K and H-2D antigens did inhibit. Although H-2 serology is in a state of rapid change at present, it must be concluded that in this assay, antibody against antigens in theK andD regions as well as theI region can inhibit EA rosette formation. Inhibition of these rosettes by anti H-2 sera is therefore not due to a special association of Ia antigens with Fc receptors.     

Separation of the immune response genes for LDH-B and MOPC-173. I. Description of an immune response defect in B10.BASR1

By using the intra-I-region recombinant mouse strain, B10.BASR1 (H-2as4), the immune response (Ir) genes for LDH-B and MOPC-173 were genetically and serologically separated, as assayed by T cell proliferation. Previous work demonstrated that the H-2s and H-2b strains respond to LDH-B and MOPC-173, whereas the H-2a and H-2k strains failed to respond due to haplotype-specific suppression of I-Ak-activated T helper cells by I-Ek-activated T suppressor cells. In the experiments reported here, B10.BASR1 mice, which lack I-Ek expression, mounted a significant T cell proliferative response to MOPC-173 but not to LDH-B. Separation of the Ia determinants used in restricting these two antigen responses was further confirmed when pretreatment of B10.S(9R) (A alpha sA beta sE beta sJk) macrophages with A.TL anti-B10.HTT (anti-A beta sE beta sJs) serum absorbed with B10.BASR1 spleen cells blocked the LDH-B response but not the MOPC-173 response. Unabsorbed serum blocked both antigen responses. The primary immunogenic determinant recognized by LDH-B or MOPC-173 immune T cells was not present on both antigens, as MOPC-173-primed T cells and LDH-B-primed T cells responded only to the priming antigen. Lastly, by using the A beta mutant strain, B6CH-2bm12, it was shown that the Ir gene and Ia determinants affected by this mutation had no effect on the LDH-B and MOPC-173 proliferative responses. These results suggest the possibility of an intragenic recombinatorial event in either the A alpha or A beta chain resulting in the separation of these two immune response gene functions.     

Acute lymphoblastic leukemia (ALL) antigens detected with antisera to E rosette-froming and non-E rosette-forming ALL blasts.

Based on the presence or absence of erythrocyte receptors(E) a T cell marker, acute lymphocytic leukemia (ALL), can be divided into E+ALL and E-ALL. We studied cell surface antigens on blasts from 12 children with untreated ALL: eight with E-ALL and four with E+ALL. Heterologous antisera were raised against thymus cells, E+ and E-ALL blasts, appropriately absorbed and tested by immunofluorescence and a radiolabeled antibody assay with normal and leukemic lymphoid cells. By both methods, anti-thymus and anti-E+ALL sera reacted with human thymocytes. Specific binding of anti-E+ALL serum to T antigens was indicated by the fact that a single absorption with thymocytes abolished its binding to allogenic thymocytes, and the reactivity of anti-E+ALL serum with thymus, blood and bone marrow lymphocytes was similar to that of anti-thymus serum. After exhaustive absorption with blood leukocytes, anti-E+ALL and E-ALL sera were negative against normal lymphocytes and bone marrow cells from children with ALL in remission. Anti-thymus and anti-E+ALL sera reacted with blasts from patients with E+ALL, but not with E-ALL. In contrast, anti-E+ALL serum reacted with 40 to 96% of blasts from all children with E-ALL, whereas of the four patients with E+ALL, two were negative and two had the lowest percentage of immunofluorescent cells (10 to 22%). These results were confirmed with the radiolabeled antibody assay. Patients with active E-ALL had cells bearing E-ALL antigen(s) in the peripheral blood and bone marrow, but the number of immunofluorescent cells was lower in blood. Cells reactive with anti-E-ALL serum did not react with thymus cells, blood lymphocytes, remission bone marrow cells, Raji cells, PWM and PHA-induced blasts and CLL cells bearing mIg (uk). These data suggest that the antigen detected on E-ALL blasts by anti-E-ALL serum is neither a HLA-related nor a cell differentiation antigen. Thus, by using antiserum to E+ALL blasts, we have confirmed the presence of a T cell-specific antigen(s) on E+ALL cells. This antiserum did not recognize other leukemia-associated antigens common to E+ and E-ALL. We have also demonstrated an antigen(s) which is regularly expressed on E-ALL blasts and is either not detectable or is present in a lower proportion of E+ALL blasts.     

Immunohistology of thymic nurse cells

The demonstration of thymic nurse cells (TNC), complexes between stromal cells and thymocytes, in cell suspensions of murine thymuses, prompted us to investigate (1) the relationship of TNC to other thymic stromal cell types defined in situ, and (2) the maturation stage of the enclosed thymocytes. To this purpose we incubated frozen sections of TNC suspensions with various monoclonal antisera directed to T cells and stromal cell types, using immunohistology. This approach enabled us to study antigen expression on the "nursing" cell itself and to analyze the phenotype of the enclosed lymphocytes in cross sections of TNC. The results show that lymphocytes enveloped by TNC express high levels of Thy-1, moderate levels of T200, and variable amounts of Lyt-1. Due to enzymatic degradation Lyt-2 expression could not be studied. The enveloped cells also bear PNA receptors, but no detectable I-A/E antigens. Expression of H-2K antigens on enclosed thymocytes varied from weak to absent. The "nursing" cells react with ER-TR4, a monoclonal antibody which detects cortical epithelial-reticular cells. In addition TNC express I-A/E and H-2K antigens. In contrast, TNC do not react with ER-TR 5 and 7, monoclonal antibodies, which detect medullary epithelial cells and reticular fibroblasts, respectively. TNC do not express the macrophage antigens Mac-1 and Mac-2. We conclude that TNC in vitro represent the in vivo association of epithelial-reticular cells with cortical thymocytes. However, the enclosed thymocytes do not constitute a phenotypically distinct subset of subcapsular or outer cortical cells.     

Association of mouse adenovirus-induced cell surface antigen(s) with histocompatibility antigens

The topological relationship on the mouse adenovirus (M-Ad)-infected cell surface between virus-induced specific cell surface(s) antigens and serologically defined major histocompatibility antigens (H-2) was analyzed by the cap formation technique. Rhodamine-isothiocyanate (RITC)-labeled anti-S serum failed to stain the surface of virus-infected lymphoid cells which were pretreated with anti-H-2 serum and fluorescein isothiocyanate (FITC)-labeled anti-mouse immunoglobulin serum (anti-M-Ig) to cap the appropriate H-2 antigens. Conversely, the capping of the S antigens by pretreatment with anti-S followed by FITC anti-M-Ig serum induced cocapping of H-2 antigens. The β₂ microglobulins (β₂m) were also shown to be cocapped with S antigens by anti-β₂m or by anti-S serum. The S antigens, however, did not cocap with mouse-immunoglobulins or Thyl. 2 antigens on virus-infected B or T lymphocytes, respectively. To further elucidate the molecular relationship between S and H-2 antigens, radio-iodinated virus-infected cells were solubilized with Nonidet P40 (NP40) and S antigens were precipitated with anti-S serum. When the precipitates were analysed with sodium dodecyl sulfate Polyacrylamide gel electrophoresis, two major peaks were seen at positions of molecules of about 45,000 and 12,000 daltons both of which corresponded with molecules which were observed when NP40 extracts of virus-infected or uninfected cells were precipitated with anti-H-2 serum. Sequential immunoprecipitation analysis of infected cell extracts showed that S antigens were coprecipitated with either H-2K or H-2D antigens. These results suggest that the S antigens are somehow associated with H-2K or H-2D antigens separately.     

Analysis of cytotoxic mechanisms induced by minor histocompatibility antigens in the mouse.

Following immunization of BALB/c (H-2^d) mice against the P815Y (H-2^d) mastocytoma, two populations of effector cells could be identified in the spleen, namely, the cytolytic T cell and a cytostatic effector, which was resistant to anti-T-cell serum and complement and appeared to be adherent. Quantitative comparison of the activities of both effectors has been made with the levels of activity obtained following immunization across the major H-2 barrier in C57BL10 (H-2^b) mice. While T-cell activity was significantly lower in BALB/c mice, the non-T-cytostatic activity was greater compared with C57BL mice. Therefore, H-2 antigens do not appear to be essential for the efficient induction of the cytostatic effector.     

Immunohistological detection of H-2 antigens in vivo induced by IFN-beta in mouse brain tissues

We describe the immunohistological detection of in vivo interferon-beta (IFN-beta)-induced H-2 antigens in mouse brain tissues. Two injections of recombinant mouse interferon-beta (rIFN-beta) were given into the lateral ventricles. Following perfusion with periodate-lysine-paraformaldehyde (PLP) solution, microsliced brain sections were incubated with anti H-2 monoclonal antibody and these subjected to a streptavidin biotin immunohistochemistry technique. Expression of H-2 antigens was demonstrated on neurons, neuroglias and vascular endothelial cells in the hippocampus, cerebral cortex, corpus callosum and other regions of the brain as well as on ependymocytes in the choroid plexus. H-2 antigens were also diffusely distributed in the cytoplasm and axons.     

Tissue-specific cell-surface antigens in embryonic cells

With the use of antisera prepared in rabbits against suspensions of live embryonic chick tissue cells, qualitative differences in cell surface antigens were demonstrated on cells from different embryonic chick tissues by immune agglutination and immunofluorescence. Unabsorbed antisera reacted with both homologous and nonhomologous cells; thorough absorption of the antisera with heterologous tissues removed cross-reacting antibodies, and the antisera acquired a high degree of tissue specificity. Thus, antiretina cell serum absorbed with nonretina cells or tissues, agglutinated only neural retina cells, and was shown by immunofluorescence tests to react specifically with the surface of retina cells, both in cell suspensions and in frozen tissue sections. Comparable results with antisera against cells from embryonic liver and other tissues demonstrated the existence of tissue-specific, phenotypic disparities in the antigenicities of embryonic cell surfaces, in addition to the presence of cell-surface antigens shared by certain classes of cells, and of antigens common to all cells in the embryo. The results are discussed in terms of the possible involvement of such phenotypic determinants in the specification of cell surfaces, in relation to cell recognition and developmental interactions.     

Helper T cell lines to major and to minor histocompatibility antigens are equally effective in the regulation of B cell responses in vivo

Long-term lines of helper T (Th) cells, reactive to minor histocompatibility (minor-H) antigens, were grown by antigen restimulation in the absence of exogenous interleukin-2. These lines were antigen specific and H-2b restricted. When introduced in vivo by adoptive transfer, these Th cells helped syngeneic B cells in an antibody response to other alloantigens. Linked recognition was required for effective help to occur, this suggests B cell presentation of antigen to Th cells in vivo. Parallel titration experiments performed with long-term cultured Th lines to MHC and to minor-H antigens showed that, on a per cell basis, they are equivalent in their ability to help in vivo B cell responses. This shows that any inability to produce antisera to minor-H antigens is not due to a Th or APC defect, but results from either a B cell defect or from suppression.