Inhibition of secondary mouse mixed lymphocyte reaction by anti-Ia sera

Secondary mixed lymphocyte reaction (MLR-II) was studied in A.TH anti A.TL and A.TL anti-A.TH combinations in which stimulation was mainly due toH-2I-region differences. In both cases the MLR-II was specifically inhibited by the responder anti-stimulator Ia serum. The level of inhibition was dependent on the ratio of the amount of immune serum to the number of stimulating cells. The inhibitory activity and Ia antibodies were specifically absorbed and eluted together. The results confirm that the lymphocyte-activating determinants of the MLR-II (1) are carried by the Ia molecules and (2) are identical to the serologically defined Ia determinants. —Anti-Ia sera directed against private and public specificities of the stimulating cell induced a higher level of inhibition than anti-Ia sera directed only against public specificities, indicating that both private and public Ia specificities are involved in restimulation during MLR-II. — These results, in connection with others, suggest that the receptor of the proliferating T cell recognizes the same Ia determinant as the combining site of the Ia-recognizing antibody.Abbreviations used in this paper Lad lymphocyte-activating determinant - MLR mixed lymphocyte reaction - MLR-I, MLR-II primary, secondary MLR - PRC primed responder cells - LCT dye exclusion lymphocytotoxicity microtechnique - RR relative response     

Blocking of MLC stimulation by anti-Ia sera: studies with the virus plaque assay.

The development of congenic mouse strains identical at the H-2K and H-2D loci but differing by I-region associated (Ia) determinants has permitted an association to be established between Ia determinants and stimulation in mixed lymphocyte culture reactions (MLR). The present experiments were undertaken to establish whether the Ir-coded control of MLR operated at the level of recognition or of stimulation. Reciprocal MLR were established between A.TH and A.TL mouse spleen cells in the presence or absence of anti-Ia sera directed either at determinants of the stimulating or responding cells. The number of T cells responding was assessed by the virus plaque assay. Anti-Ia sera directed against the responding cells were no more inhibitory of the MLR than normal mouse serum. In contrast, anti-Ia sera directed against determinants of the mitomycin-treated stimulating cells markedly inhibited activation of T cells in the MLR.     

Histocompatibility antigens controlled by theI region of the murineH-2 complex

Spleen cells from A.TH mice, presensitized in vivo by skin grafting, were restimulated in vitro by A.TL lymphocytes, and A.TH anti-A.TL effector cells were generated. The effector cells lysed, in the CML assay, A.TL blasts. This reaction, which was againstI-region antigens, could be inhibited by the addition to the reaction mixture of anti-La sera directed against A.TL antigens. The inhibition was specific, since normal mouse serum, reciprocal antiserum (A.TL anti-A.TH), and anti-H-2 sera did not have a significant effect on the reaction. The Ia antibodies also specifically inhibited the reaction of A.TH anti-A.TL effector cells against CBA targets. Con A blasts were significantly poorer targets inI-region CML than LPS blasts. As CML targets, macrophages and cells of a mammary adenocarcinoma were as good as, if not better than, the LPS blasts. The experiments support the notion that Ia antigens are the targets in theI-region CML.     

Dissection of the poly(Glu60 Ala30 Tyr10) (GAT)-specific T-cell repertoire in H-2I k mice

Twenty-five allospecific monoclonal antibodies (mAb), produced in the A. TH. A.BY, or B10.S (7R) anti-A.TL combinations, were shown to recognize determinants organized in four spatially distinct polymorphic regions on the same I-Ak-encoded molecule(s). These reagents were used to assess the recognition of the class II major histocompatibility complex (MHC) determinants in a series of GAT-reactive A.TL T-cell clones exhibiting various restriction specificity or alloreactivity patterns. Of the proliferative responses of 13 cloned T cells, 12 responses were found to be inhibited similarly by the same set of mAbs.A hierarchy in the blocking effects of these reagents that could be correlated with the spatial organization of their determinants was observed. (i) All the mAbs defining the epitope region I (i.e., recognizing public Ia.1- or Ia.17-like determinants, presumably expressed on the A beta subunit) and some of those identifying new public determinants in the epitope region II profoundly inhibited these T-cell responses. (ii) Intermediate blocking was observed when mAbs recognizing public determinants in the epitope region III were used. (iii) Finally, among the mAbs that identified the epitope group IV, the Ia.19-specific mAb 39.J was inhibitory, whereas mAbs directed against private Ia.2-like determinants were not. By contrast, the GAT-specific proliferative response of the T-cell clone AT-20.1, which recognized its nominal antigen in an extensively cross-reactive MHC-restricted fashion, could only be inhibited by a subset of the mAbs recognizing epitopes in groups I and II, but not by those recognizing epitopes in groups III and IV. It was also shown that the same subset of I-Ak-and I-Au-reactive mAbs displayed similar blocking effects on the proliferation of two T-cell clones exhibiting dual specificity for I-Ak- and I-Au-restricting and/or I-Ak- and I-Au-alloactivating determinants. Finally, all the cloned T-cell responses examined were found to be inhibited by rat mAbs against the LFA.1 molecule or the murine equivalent of the human OKT4 differentiation antigen. These studies suggest that class II specific mAbs can impair proliferation of cloned T-cells by a mechanism(s) other than the masking of the T-cells' restriction determinants per se.     

Human T lymphocytes become glucocorticoid-sensitive upon immune activation

A murine model for Transfer Factor (TF) was used in an attempt to identify the nature of its antigen-specific component. TF was prepared from lymph node cells of CBA/Ca/T6 mice sensitized 30 days previously with 2,4-dinitrofluorobenzene (DNFB). To assay for the specific component of TF, 2 × 10⁷ lymphocyte equivalents were injected intravenously into normal syngeneic recipients. Lymph node cells obtained 18–24 hr later gave a positive response in the macrophage migration inhibition (MMI) test in the presence of the soluble analog of DNFB (sodium 2,4-dinitrobenzenesulfonate). The activity of TF was abrogated by absorption with anti-Ia sera including both an Ia alloantiserum (A.TH anti-A.TL) and a xenogeneic rabbit anti-serum which exclusively recognizes carbohydrate-defined Ia antigens. Analysis by paper chromatography using the technique for purification of carbohydrate-defined Ia antigens revealed that MIF production was obtained exclusively with those fractions known to contain Ia antigenic activity. In addition, pretreatment of TF with insoluble conconavalin A (Con A) which has an affinity for carbohydrate-defined Ia antigens resulted in removal of its activity. Taken together these findings pointed to the presence in TF of I-region gene products. Absorption with antibody directed against the dinitrophenyl determinant abolished the capacity of TF to stimulate macrophage inhibition factor production suggesting that it might also contain antigen fragments possibly in association with Ia. No evidence was, however, obtained for H-2 restriction of the action of TF in vivo since it was found to exert an effect in a variety of strain combinations including A.TH and Balb/c which share no known common I-region specificities. Parallel experiments were carried out with the lymphocyte transformation assay since this is known to be a measure of the nonspecific components in TF. Pretreatment with mouse allo-anti-Ia^k serum directed against both protein-and carbohydrate-defined Ia antigens caused a partial reduction in the proliferative response. In contrast no change in response was observed when the TF was absorbed with insoluble Con A or anti-DNP serum. Furthermore, lymphocyte transformation was obtained with only one of the three paper chromatography fractions positive in the MMI assay as well as two other different fractions. Taken together, these findings permitted a distinction to be made between specific and nonspecific components of TF and indicated that the specificity of TF could be explained in terms of the presence of I-region gene coded products possibly in association with antigen fragments.     

Clonal analysis of B and T cell responses to Ia antigens. IV. Proliferative T cell clones recognizing E beta and/or E alpha allodeterminants

The allospecific T cell recognition of the I-Ek molecule was assessed by using eight A. TH anti-A. TL proliferative T cell clones, all of which expressed the Thy-1-2+, Lyt-1+, Lyt-2-, Ia-, and p94,180+ cell surface phenotype. The use of panels of stimulating cells from homozygous of F1 hybrid strains indicated each T cell clone exhibited specificity for distinct alloactivating determinants including: i) a private E beta k-controlled determinant expressed in cis- or trans-complementing E beta kE alpha strains; ii) an apparently nonpolymorphic E alpha determinant resembling the serologic specificity Ia.7, i.e., present in all strains carrying E alpha and E beta expressor alleles; and iii) a series of conformational I-E determinants, the expression of which required a precisely defined combinatorial association of E beta plus E alpha chains. Two clones were found to be reactivated by cis- but not trans-complementing E beta k E alpha k strains, and another recognized an allodeterminant shared by the I-Ab molecule. Various I-Ek-reactive monoclonal antibodies (mAb) directed to epitopes presumably expressed on either E alpha (epitope clusters I and II) or E beta (epitope cluster III) chains inhibited the proliferative responses of seven clones recognizing private E beta k or unique E beta E alpha conformational activating determinants. By contrast, the restimulation of the clone directed to a nonpolymorphic E alpha determinant was selectively blocked by anti-Ia.7 mAb defining epitopes on the E alpha chains but not by those directed to the E beta chain. On the basis of these data, it was concluded that the recognition sites of most anti-I-Ek proliferative T cells were expressed on the E beta chain or the E beta plus E alpha interaction products, and that a minority of such alloreactive T cells could be activated through recognition of the E alpha chain per se.     

The ontogeny of murine B lymphocytes. I. Induction of phenotypic conversion of Ia-to Ia+ lymphocytes.

When bone marrow and spleen cells of 4 week-old mice are fractionated on a discontinuous BSA gradient, a small fraction of Ia- cells is obtained which can be induced in vitro to express the Ia alloantigen within 2 hr. This is in precise parallel to the prothymocyte induction system of Komuro and Boyse. Ia specificity is ascertained by the use of two reciprocal antisera, A.TH anti-A.TL (anti-Iak) and A.TL anti-A.TH (anti-Ias), which yield the expected reaction pattern on induced bone marrow cells of (B6 X A)F1 (Iak) and SJL/J (Ias) mice. Induction can be effected by a number of agents, such as catecholamines, prostaglandin PGE1, cAMP, bacterial endotoxin, lipid A, ubiquitin, and thymopoietin. The last requires a 100-fold higher concentration for Ia+ induction as compared to prothymocyte induction, thus implying a lower affinity for the B cell receptor than for the thymocyte receptor. Ia- to Ia+ conversion involves cells different from prothymocytes, as indicated by: 1) the specific cytolytic effect of our anti-Ia sera which were shown to be free of activity against thymocytes; 2) an additive cytolytic effect of anti-Ia and anti-Thy-1 sera; and 3) the fact that the Ia inducible cells are sensitive to pretreatment with anti-immunoglobulin and C. This finding that Ia- precursor cells are already Ig+ is of interest for the B cell ontogeny, as it implies that Ig expression precedes Ia expression.     

Secondary mouse mixed lymphocyte reaction (MLR) in vitro: Correlation between primed cells reactivity and serological typing for Ia specificities

B10.M (H-2^f) spleen lymphocytes were cultured for 14 days with X-irradiated B10.P (H-2 ^p ) lymphocytes. These primed cells were then tested for their capacity to respond to a secondary stimulation induced by a panel of mouse cells carrying differentH-2 haplotypes. The third-party cells induced various degrees of proliferation which could be expressed as a percentage of the proliferation induced by the primary stimulating strain (relative response = RR) and could then be classified according to the RR. Anti-Ia antibodies present in a B10.M anti-B10.P serum were studied by the dye exclusion lymphocytotoxicity technique (LCT) against the same panel, after absorption of H-2K, D antibodies on B10.P platelets. The strain panel could then be classified according to the LCT titers of the absorbed immune serum. A significant correlation (r=0.96,P<0.01) was found between both classifications. According to the Ia chart, the public specificities involved were Ia.6, 7, and 13, but these did not fully explain either the primed cell reactivity or the LCT results. An unexpected crossreactivity was observed between B10.P and B10. Absorption-elution experiments with A.TH anti-A.TL serum demonstrated that B10 and B10.P share the Ia.3 antigen. These results indicate that the structure(s) recognized by the primed lymphocytes is the Ia antigen(s).Abbreviations used in this paper RR Relative response - LCT Dye exclusion lymphocytotoxicity technique - MLR Mixed lymphocyte reaction - PC Primed cell - MHC Major histocompatibility complex - PLT Primed lymphocytes typing test     

Demonstration of carbohydrate- and protein determined Ia antigens by monoclonal antibodies

Ten monoclonal alloantibodies were examined by submitting each antibody to five independent tests in order to determine whether they reacted primarily with the glycoprotein or glycolipid class of Ia antigens. The tests employed were as follows: (1) the ability to participate an Ia-like protein from the cell surface as detected by SDS-PAGE; (2) inhibition by protein-Ia extracts free of CHO-Ia; (3) inhibition by CHO-Ia extracts free of protein-Ia; (4) neuraminidase sensitivity of the antigen and (5) inhibition by simple sugars. Using these tests, three of the ten monoclonal antibodies were shown to recognize a CHO-Ia antigen while seven recognized the protein class of Ia antigens. The three CHO-Ia-specific monoclonal antibodies recognized Ia specificities 2, 9 and 17. Monoclonal antibodies recognizing protein-defined Ia.2 and 17 specificities were also characterized. These results imply that some Ia specificities, as defined by genetic testing, can occur both as carbohydrate-defined and protein-defined determinants.--Sugar inhibition studies showed that CHO-Ia.2 has D-glucosamine as its immunodominant sugar while CHO-Ia.17 shows preference for a beta-linked galactose. Furthermore, studies with neuraminidase demonstrated that sialic acid plays a role in the antigenic determinants of CHO-Ia.9 and CHO-Ia.17. Finally, it is noteworthy that CHO-Ia.2, the private specificity of the k haplotype, appears to be expressed only on cells and not in serum. These studies clearly demonstrate the existence of the two Ia antigen classes and emphasize the complexity of the murine I region.     

Cellular immune response to acetylcholine receptors in murine experimental autoimmune myasthenia gravis: inhibition with monoclonal anti-I-A antibodies

Gene(s) at the I-A subregion of the murine major histocompatibility complex influence susceptibility to experimental autoimmune myasthenia gravis. C57Bl/6 mice immunized with acetylcholine receptors (AChR) in complete Freund's adjuvant demonstrated cellular and humoral immune responses to AChR. They developed muscle weakness characteristic of myasthenia gravis and demonstrated a reduction in the muscle AChR content. The kinetics of AChR-specific lymphocyte proliferation generally correlate with anti-AChR antibody response. AChR-specific lymphocyte proliferation was also observed in C57Bl/6 splenocytes after secondary immunization with AChR. The in vitro cellular reactivity to AChR in experimental autoimmune myasthenia gravis (EAMG) mice (C57Bl/6) was suppressed by monoclonal anti-I-Ab antibodies directed against private (Ia20) or public (Ia8) specificities, suggesting a critical role for these Ia determinants in the cellular immune response to AChR in murine EAMG.     

Comparison of antigens recognized by xenogeneic and allogeneic anti-Ia antibodies: Evidence for two classes of Ia antigens

Previously published data suggest that both xenogeneic and allogeneic anti-Ia sera can recognize carbohydrate-defined antigenic determinants on the surface of lymphocytes. There is also evidence, based on studies with allogeneic anti-Ia sera, that protein-defined Ia antigens exist. In this paper the relationship between these two types of Ia antigen was examined. It was found that in capping studies, the allogeneic anti-Ia serum could cap off the antigens recognized by the xenogeneic antiserum, whereas the xenogeneic antibodies could, at least partially, clear the surface of lymphocytes of Ia antigens detected by the allogeneic antibodies. On the other hand, when immunoprecipitates of radioiodinated cell-surface antigens were examined by SDS-polyacrylamide-gel electrophoresis, it was found that the xenogeneic anti-Ia serum did not immunoprecipitate any labeled material. In contrast, the allogeneic antiserum immunoprecipitated a labeled molecule which corresponded to the protein-defined Ia antigen described by others. Finally, it was shown that serum Ia antigens could be bound by either mouse or rabbit anti-Ia antibody, and this binding blocked any further reactivity with either serum. These results were interpreted as suggesting that two separate classes of Ia antigen molecule appear on the lymphocyte surface-one class has carbohydrate-defined antigenic specificities and the other has protein-defined determinants. Allogeneic anti-Ia sera contain antibodies against both these antigenic systems, whereas xenogeneic sera recognize only the carbohydratedefined series. The genetic implications of this interpretation are discussed.     

Lymphocytes express Ia antigens of foreign haplotype following treatment with neuraminidase

Evidence is presented which indicates that neuraminidase (NA) treatment of spleen cells both destroys old Ia antigens and reveals new Ia specificities which are not normally expressed by splenocytes. It was found that NA treatment unmasked alien I-A^k-like specificities on A.TH (I ^s ) spleen cells, and I^s-like antigens on A.TL (I ^k ) spleen cells. These conclusions were based on direct testing of NA-treated targets with a range of alloantisera and on cell-absorption experiments. Furthermore, the cellular distribution of NA-exposed antigens resembled that of convential Ia antigens, the new antigens being expressed on more than 90 percent of splenic B cells and a subpopulation of splenic T cells. However, although some of the antigens exposed by NA on A.TH cells appeared to resemble the Ia. 3 and 15 specificities, additional antigens were involved which did not correlate with any previously described Ia antigens.Sugar inhibition experiments demonstrated the NA-exposed antigens to be carbohydrate in nature, D-galactose being an effective inhibitor in these studies. The proportion of- and-linked D-galactose residues associated with the new antigens depended upon the target cell used and the anti-Ia serum tested. Furthermore, glycolipid extracts from lymphoid cells were shown to contain the NA-exposed antigens.Collectively, these results support the existence of carbohydrate-defined Ia antigens. The simplest interpretation of the findings is that NA clips off terminal sialic acid residues from carbohydrate-defined Ia antigens on the cell surface and exposes subterminal sugars which resemble antigens expressed by otherI-region haplotypes.     

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.     

Demonstration of carbohydrate- and protein-determined Ia antigens by monoclonal antibodies

Ten monoclonal alloantibodies were examined by submitting each antibody to five independent tests in order to determine whether they reacted primarily with the glycoprotein or glycolipid class of Ia antigens. The tests employed were as follows: (1) the ability to precipitate an la-like protein from the cell surface as detected by SDS-PAGE; (2) inhibition by protein-la extracts free of CHO-Ia; (3) inhibition by CHO-Ia extracts free of protein-la; (4) neuraminidase sensitivity of the antigen and (5) inhibition by simple sugars. Using these tests, three of the ten monoclonal antibodies were shown to recognize a CHO-Ia antigen while seven recognized the protein class of Ia antigens. The three CHO-Ia-specific monoclonal antibodies recognized Ia specificities 2,9 and 17. Monoclonal antibodies recognizing protein-defined Ia.2 and 17 specificities were also characterized. These results imply that some Ia specificities, as defined by genetic testing, can occur both as carbohydrate-defined and protein-defined determinants.— Sugar inhibition studies showed that CHO-Ia.2 has D-glucosamine as its immunodominant sugar while CHO-Ia. 17 shows preference for a- linked galactose. Furthermore, studies with neuraminidase demonstrated that sialic acid plays a role in the antigenic determinants of CHO-Ia.9 and CHO-Ia.17. Finally, it is noteworthy that CHO-Ia.2, the private specificity of thek haplotype, appears to be expressed only on cells and not in serum. These studies clearly demonstrate the existence of the two Ia antigen classes and emphasize the complexity of the murineI region.     

Cell-mediated cytotoxicity against HLA-D-region products expressed in monocytes and B lymphocytes. I. Blocking by Unlabelled cells and inhibition by antisera

Cytotoxic effector cells against HLA-D-region produts were generated in cultures with HLA-A- and B-matched, HLA-D-mismatched stimulating cells. Monocytes from unrelated donors sharing HLA-D/DR antigens with the primary stimulator were used as target cells. Lysis of target cells was inhibited by addition of unlabelled monocytes having the same HLA-D/DR antigens. Inhibition of cytotoxicity was also observed with unlabelled B cells, but T lymphocytes had little effect. The distribution of the target antigens, therefore, fits the known distribution of the products of HLA-D. In other experiments, a human alloantiserum specific for HLA-DRw3 was found to inhibit cellular cytotoxicity specific for HLA-D/DRw3. Lysis by HLA-D/DRw3-specific effector cells was not inhibited by sera against HLA-DRw2 or DRw7 or by antibodies against HLA-B8 using HLA-B8 positive, DRw3 positive targer cells. A xenogeneic serum against human Ia antigens, produced in rabbits, blocked cytotoxicity directed at DRw2, DRw3 and DRw4. These results suggest that cell-mediated cyctotoxicity was directed against HLA-D/DR or very closely associated determinants.     

Inhibition of stimulation in murine mixed lymphocyte cultures with an alloantiserum directed against a shared Ia determinant.

Pools of high titered alloantisera were raised by immunizing (B10.A/SgSn X A/WySn)F1 mice with C57BL/10Sn(B10) spleen cells. This serum (F1 anti-B10), when added to one-way mixed lymphocyte cultures (MLC), inhibited stimulation of B10.A splenic responders by both B10 and B10.D2/nSn irradiated, splenic stimulators. The B10 stimulation was suppressed approximately 85% whereas the mean suppression of B10.D2 stimulation was approximately 60%. In the ofrmer case, the serum contained antibodies reactive with multiple major histocompatibility complex determinants on the stimulator cells. In the latter case, the cytoxic reactivity of the serum was directed principally against an I region-associated determinant Ia.8) shared by B10 and B10.D2 and coded for by a gene(s) in the I-A subregion. The magnitude of the suppression of the response to B10.D2 cells (60%) was similar to the reduction in stimulation observed when the Ia.8 difference was eliminated genetically by using (B10 X B10.A)F1 responder cells against irradiated B10.D2 stimulators. Ihhibition of MLC by this antiserum was a function of reactivity with stimulator and not responder cells. Although some pools of F1 anti-B10 antiserum produced partial inhibition of the responder cell in a B10.D2 vs B10.Ax MLC combination, the results were inconsistent and not correlated with the anti-Ia.8 cytotoxicity titers. In addition, an F1 anti-B10 antiserum pool, which consistently failed to inhibit the responder cell, nevertheless inhibited both irradiated B10.D2 and (B10.A X B10.D2)F1 cells from stimulating B10.A responder cells. However, this same antiserum did not inhibit stimulation of B10.D2 responder cells by the (B10.A X B10.D2)F1 stimulators. Thus, the binding of antibodies to the non-stimulating antigens on the F1 stimulator cell did not interfere with the capacity of the appropriate stimulating antigens to cause stimulation. All of these results are consistent with the hypothesis that Ia allo-antigens are the major stimulating determinants of I region-associated MLC reactions.     

Leukemia-cell rejection due to T-region encoded antigens

The role of H-2- and T-region products in determining allogeneic cell rejection was evaluated inH-2 congenic and recombinant mice by transplanting A1ATH and A6ATL leukemia cell lines induced in A.TH and A.TL strains, respectively, by Moloney murine leukemia virus. — InK- orD-region incompatible hosts transplant failure was observed, while inI +T-region incompatible hosts either rejection or prolonged survival was seen. In mice preimmunized with spleen cells fromI- and/orT-region incompatible donors, leukemia cells were rejected by mice immune only to T-region products, and accepted by mice immune only to I-region products. — Cell-mediated cytotoxicity studies confirmed in vivo results. Secondary CTLs specifically directed against I-region products did not lyse the A1ATH and A6ATL cells, and secondary CTLs from A.TH and A.TL mice sensitized against A6ATL and A1ATH cells respectively exerted a lytic action specific for T-region products, while no activity was observed against I determinants. — The data suggest that tumor-transplant rejection may also be governed by histocompatibility antigens encoded in theT region.     

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.     

Characterization of stem cells and progenitors of hemopoiesis by cell sorting.

Cell sorting has been used as a method for characterizing hemopoietic stem cells and progenitors. Fluorescent antibody-surface labels and changes in fluorescence polarization induced by in vitro stimulation with potential hemopoietic regulators were used. As detected by significant enrichment of CFU-S (pluripotent stem cells) in fluorescence-activated cell sorting, some CFU-S bear 'unique antigens' recognized by rabbit anti-human brain sera, human anti-human sperm sera, and 129 anti-F9 serum, but not A . TH anti-A . TL (Ia) ascites. Significant changes in fluorescence polarization induced by in vitro stimulation of mouse bone marrow with potential hemopoietic regulators were also observed; further, progenitors of human T-lymphocyte colonies were observed to exhibit a significantly decreased mean polarization value after short-term stimulation with PHA-LCM (phytohemagglutinin-stimulated leukocyte conditioned medium).     

Unique T cell Ia antigen expressed on a hybrid cell line producing antigen-specific augmenting T cell factor

Hybrid cell lines were established by fusion between keyhole limpet hemocyanin(KLH) binding T cells of A/J mice and an AKR T cell tumor line, BW5147. Hybrids were selected for the presence of Ia antigen and KLH-specific augmenting activity of their extracts in the secondary antibody response. The detailed phenotypic and functional analysis of 1 of these clones, FL10, is reported here. The hybrid was positive for both Thy1.1 and Thy1.2 antigens and possessed the Lyt-1+,2-,3- phenotype. Both VH and Ia determinants were detected on their cell surface. The IA locus was mapped in the I-A subregion, but the Ia specificities were serologically distinct from those of B cell Ia antigen. This was demonstrated by the fact that anti-Ia antiserum preabsorbed with B cells could react with the hybrid cells, whereas none of the monoclonal anti-Ia specific for private and public determinations of Iak could. The extract from the cell line specifically augmented the in vitro secondary antibody response against dinitrophenylated KLH, and this activity was removed by absorption with antigen and conventional anti-Ia antisera. The results indicate that the cell line, FL10, carries Ia antigen unique to the T cell, which is associated with the antigen-specific augmenting molecule.