Correlation of Qa-1 determinants defined by antisera and by cytotoxic T lymphocytes

Cytotoxic T lymphocytes (CTL) activated in H-2 identical, Qa-1 disparate mixed leukocyte cultures recognize H-2-nonrestricted target antigens indistinguishable by strain or tissue distribution from serologically defined Qa-1 antigens. Cloned Qa-l-specific CTL define determinants encoded by four Qa-1 genotypes; we used anti-Qa-1 sera in antibody blocking experiments to determine if these determinants reside on molecules recognized by Qa-1-specific antibodies. Antisera containing Qa-1.1-specific and TL-specific antibodies blocked recognition of two CTL-defined determinants associated with Qa-1 ^a . Although both Qa-1 and TL molecules are expressed on activated T cells from appropriate strains, our studies indicated that the CTL recognized Qa-1, not TL. In addition, anti-Qa-1.2 serum inhibited CTL recognition of Qa-1^b- and Qa-1^c-encoded determinants. Qa-1 ^d target cells are unique in that they express determinants recognized by anti-Qa-1^a CTL and by anti-Qa-1^b CTL. Killing of Qa-1 ^d targets by anti-Qa-1^a CTL was not inhibited by anti-Qa-1.1 serum, but was partially inhibited by anti-Qa-1.2 serum. Cytotoxicity of Qa-1 ^d cells by one anti-Qa-1^b CTL clone was inhibited by both anti-Qa-1.2 and anti-Qa-1.1 sera, indicating close association of both serological determinants with the determinants recognized by the CTL. Thus, all of the CTL-defined Qa-1 determinants resided on molecules recognized by Qa-1-specific antibodies, but anti-Qa-1^a CTL and Qa-1.1-specific antibodies did not have identical specificities.Abbreviations used in this paper B6 C57BL/6J - CAB concanavalin A stimulated lymphoblasts - CML cell-mediated lympholysis - CTL cytotoxic T lymphocyte - NMS normal mouse serum - MHC major histocompatibility complex - MLC mixed leukocyte culture - MR maximum release - SMDM supplemented Mishell-Dutton medium - SR spontaneous release     

Regulation of Qa-1 expression and determinant modification by an H-2D-linked gene,Qdm

We examined the regulation of cell surface expression of the Qa-1 alloantigens using a panel of monoclonal anti-Qa-1 cytotoxic T-lymphocyte (mCTL) lines. In contrast to previous reports of tissue-specific expression, we found that Qa-1 was widely expressed, resembling the prototypical class I H-2K/D molecules. We further found that an H-2D-linked gene, which we termed Qdm for Qa-1 determinant modifier, controlled expression of certain CTL-defined Qa-1 antigenic determinants. H-2D ^khomozygous haplotypes expressed a recessive allele of the modifier, Qdm ^k, whereas all other H-2 haplotypes tested expressed a dominant allele, Qdm ⁺. The Qdm ⁺ allele regulated in trans Qa-1 epitope expression from a Qdm ^kchromosome, modifying expression of particular CTL-defined Qa-1 antigenic determinants rather than affecting levels of cell surface expression. Mechanisms of Qdm function may include either a novel protein modification system or an unprecedented case of antigen recognition restricted by a nonclassical major histocompatibility complex molecule.     

Further serological analysis of the Qa antigens: Analysis of an anti-H-2.28 serum

Further serological analyses of the tissue and strain distributions for the Qa-2 antigens indicate that this locus should be subdivided into two loci,Qa-2 andQa-3. TheQa-2 locus determines a lymphocyte alloantigen which is present predominantly on Thy-1+ cells. The lymphocyte alloantigen determined by theQa-3 locus is more limited in its tissue distribution and appears only on lymph node and splenic lymphocytes. Testing of anti-H-2.28 sera has revealed that at least one anti-H-2.28 serum contains anti-Qa-2 and/or anti-Qa-3 activity.     

Identification of a new CML target antigen controlled by a gene associated with theQa-2 locus

BALB/cBy anti-BALB/cJ spleen cells were tested in a secondary cellmediated lympholysis assay. The effector cells generated displayed a positive cytotoxic effect against Con A lymphoblasts from only those strains that were typed serologically as having theQa-2 ^a allele. Confirmation that the target antigen is controlled by a locus closely associated with or identical toQa-2 was obtained by the findings that target cells from B6.K2 (Qa-2 ^a,Qa-3 ^a) mice were lysed by the effector cells, while those from theQa-2, 3 congenic strain B6.K1 (Qa-2 ^b,Qa-3 ^b) were not. The fact that target cells from aQa-2-positive/Qa-3-negative strain (DBA/1,Qa-2 ^ai,Qa-3 ^b) were killed indicates that the target antigen is controlled, at least in part, by theQa-2 locus, not the Qa-3.There is no observedH-2 genetic restriction for this cytotoxic effect, since target cells which have theQa-2 ^a allele but differ from the stimulator cells at theH-2K, D, andI regions were lysed efficiently.     

Molecular heterogeneity of D-end products detected by anti-H-2.28 sera

In capping experiments with peripheral T lymphocytes, two anti-H-2.28 sera (AKR anti-AKR.L, anti-K^b, and C3H anti-0H.B10, k anti-b) that do not contain any Qa-2-specific antibodies are able to redistribute not only the H-2.28-positive H-2 molecules, but also Qa-2 molecules. This is due to the capacity of these sera to react with Qa-2 molecules because on cells where all known molecules of the H-2 ^d haplotype were capped (K1^d, K2^d, D^d, M^d, L^d, L2^d), both antisera still reacted when the cells came from a Qa-2 positive D^d strain (B10.A) but not when the cells were of Qa-2 negative strain (BALB/cByA). The reaction with la and non-H-2 antigens was excluded in these experiments. These data show that Qa-2 and H-2 antigens share some specificities of the H-2.28 family. Other anti-private and anti-public anti-H-2 sera failed to react with the Qa-2 molecules.     

A new serologically defined locus,Qa-1, in theTla-region of the mouse

A new cell-surface antigen, specified by a gene betweenH-2D andTla is described. The provisional notationQa-1 is suggested for the locus determining this newly recognized cell surface component. Qa-1 is distinguished from known TL antigens by the following two criteria. Its expression is not confined to thymocytes — it occurs on lymph node cells (LNC) also; and the phenotypes of the new congenic recombinant strains B6.K1 and B6.K2, derived fromH-2D/Tla crossovers, are Qa-1⁺ Qa-2^–TL^– and Qa-l⁺Qa-2⁺TL^–. Qa-1 antigen is defined by reaction of the standard TL typing serum, (B6 × A -Tla ^b)F₁ anti-A strain leukemia ASL1, with lymph node cells (LNC) in the cytotoxicity assay. Qa-1 antigen evidently is expressed, at least, on a subpopulation of T cells as well as on thymocytes. The gene order isH-2D, Qa-1, Qa-2, Tla.Abbreviations used in this paper LNC lymph node cells pooled from inguinal, axillary, brachial, and mesentric nodes - BA⁺ (C57BL/6-Tla^axA)F1 - BA^– (C57BL/6 × A -Tla ^b)F₁ - PBS phosphate buffered saline pH 7.2 - Thy thymocytes - RMIg Rabbit anti-mouse immunoglobulin Please address proofs and communications concerning this paper to Dr. Thomas Stanton, Sloan Kettering Institute, 1275 York Ave., New York, N.Y. 10021     

Molecular heterogeneity of D-end products detected by anti-H-2.28 sera

Immunoprecipitation of NP-40 lysates of 125I-labeled lymph-node cells with different anti-H-2 sera and with anti-Qa-2 serum has shown that the BALB/cByA strain (H-2d, Qa-2-negative) expresses, besides H-2Ld, another molecule that is not detectable in the BALB/c-H-2dm2 strain. Electrophoresis in SDS polyacrylamide gels indicated that this molecule, provisionally designated Lq, has an apparent molecular weight of 41000 daltons, in contrast to approximately 49000 daltons for H-2Kd and H-2Ld, and 47000 daltons for H-2Dd molecules. The anti-Qa-2 serum precipitated from the Qa-2-positive strains BALB/cHeA but not from the Qa-2-negative strains BALB/cByA and BALB/c-H-2dm2 a protein that gave a very strong band corresponding to the molecular weight 41000 daltons in the gel electrophoresis. The biochemical characteristics of the Lq molecule are thus more similar to those of Qa-2 than of H-2 antigens.     

Cellular requirements for the generation of primary cell-mediated lympholysis responses to Qa-1 antigens

Mixed leukocyte cultures (MLC) between NZB responder spleen cells and Qa-1-disparate stimulator spleen cells were employed to determine the cellular requirements for the generation of primary anti-Qa-1 cell-mediated lympholysis (CML) responses. Although primary anti-Qa-1 cytotoxic lymphocytes (CTL) were generated during H-2-homologous stimulation, anti-Qa-1 CTL were not detectable from MLC in which the stimulators were H-2 allogeneic. Anti-Qa-1 CTL also were not generated from MLC in which the stimulators were semiallogeneic. Thus, H-2 identity between responder and stimulator cells was not sufficient to permit the generation of primary anti-Qa-1 CTL when H-2 disparity was also present. The capacity for H-2 disparity to prevent anti-Qa-1 CML responses was further demonstrated in MLC containing both H-2-allogeneic and H-2-homologous stimulator cells. Therefore, in subsequent studies we employed NZB responders and H-2-homologous, Qa-1-disparate stimulators. When various subpopulations of stimulator cells were studied for their ability to induce anti-Qa-1 CTL, nylon wool-adherent cells were found to be potent stimulators, but nylon wool-nonadherent cells were not. Furthermore, depletion of macrophages from the stimulator population abrogated the generation of anti-Qa-1 CML responses, despite the presence of responder macrophages in the culture. In contrast, all fractionated subpopulations stimulated anti-H-2 CML responses. When macrophage-enriched cells were used as stimulators, anti-Qa-1 CTL could be generated with approximately 80-fold fewer stimulator cells than when unfractionated splenocytes were used as stimulators. These findings indicated that stimulator macrophages were essential for the generation of primary anti-Qa-1 CTL. Direct evidence for macrophage expression of Qa-1-antigens was obtained by using a Qa-1b-specific CTL clone. These studies provide i) the first evidence for Qa-1 expression on macrophages, ii) a basis for comparison of the cellular interactions necessary to generate CTL against H-2K/D-encoded vs Qa-1-encoded class 1 antigens, and iii) a model for investigating the mechanisms responsible for the immunodominance of H-2K/D alloantigens.     

Recognition by cytotoxic T lymphocytes of Qa-2 antigens. Sensitivity of Qa-2 molecules to phosphatidylinositol-specific phospholipase C

Con A splenic lymphoblasts were incubated with phosphatidyl-inositol specific phospholipase C (PIPLC) derived from Bacillus thuringiensis and subsequently analyzed for Qa-2 Ag with the Qa-2 reactive mAb Qa-m2. This treatment completely removed Qa-2 detectable Ag on lymphoblasts from H-2d animals, indicating that these molecules are likely anchored to the cell membrane through phosphatidyl inositol (PI). Although exposure of lymphoblasts from H-2b mice to PIPLC greatly reduced Qa-2 expression, a subpopulation of cells retained a limited quantity of the Ag. Bulk cultured anti-Qa-2 CTL generated against the Qa-2 region from H-2b haplotype mice lysed Qa-2+ targets from B6.K2 (H-2b) and BALB/cJ (H-2d) animals. Pretreatment of these lymphoblast targets with PIPLC completely abolished lysis of the BALB/cJ target cells, whereas lysis of B6 targets was reduced only slightly. Anti-Qa-2 CTL clones tested against PIPLC-treated B6 target cells revealed two patterns of reactivity. One group of clones was unaffected in its ability to lyse PIPLC-pretreated targets and cross-reacted on Q6d/Ld molecules expressed on transfected L cells. A second group was unable to lyse PIPLC-pretreated lymphoblasts and cross-reacted on Q7d/Ld targets. These data suggest that H-2b-derived lymphoblasts express two different types of Qa-2 molecules with respect to PIPLC sensitivity; one type is sensitive to PIPLC and cross-reactive with Q7d, the other type is resistant to PIPLC and cross-reactive with Q6d. In contrast, H-2d lymphoblasts express only the PIPLC-sensitive type of molecules. It was also noted that bulk cultured anti-Qa-2 CTL more readily lysed H-2b target cells expressing a smaller quantity of PIPLC-resistant Ag than H-2d targets expressing a larger amount of PIPLC-sensitive Ag. Further, anti-Qa-2 CTL clones readily lysed PIPLC-treated target cells expressing very low levels of serologically detectable Qa-2. This suggests that recognition of class I molecules anchored to the membrane via a PIPLC-resistant linkage may more readily activate CTL for expression of lytic activity than molecules anchored through PI.     

Anti-Qa-2-induced T cell activation. The parameters of activation, the definition of mitogenic and nonmitogenic antibodies, and the differential effects on CD4+ vs CD8+ T cells

The MHC Ag Qa-2 is a glycolipid anchored class I molecule expressed at high levels on all peripheral T lymphocytes. In this study we found that anti-Qa-2 antibodies could stimulate the proliferation of murine T cells in vitro. Anti-Qa-2-induced proliferation required secondary cross-linking with anti-Ig antibody and the presence of PMA. Only Qa-2+ strains could be induced to proliferate by anti-Qa-2 antibody, but under the conditions employed, anti-CD3 could induce proliferation in Qa-2+ and Qa-2-strains. Interestingly, only anti-Qa-2 reagents directed against the alpha 3 domain of the Qa-2 class I molecule were effective in inducing proliferation. Furthermore, unlike purified CD4+ cells, purified CD8+ cells were unable to be stimulated by the anti-Qa-2 antibodies. These results lead to the inclusion of Qa-2 in a group of physiologically relevant, glycolipid-anchored, cell-surface molecules, mobilization of which can generate signals that initiate the proliferation of T cells. Such molecules may play a secondary role in cellular activation after the primary engagement of the TCR.     

Biochemical analysis of an MHC-linked hematopoietic cell surface antigen,Qa-2

The region of the murine 17th chromosome telomeric to H-2D encodes a group of serologically defined cell surface antigens termed Qa-1-5. These antigens are of interest because their expression is restricted to hematopoietic cells. In addition, the molecular weight and subunit structure (ie, association with β-2 microglobulin) of Qa-2 molecules are similar to H-2 and TL antigens. In the present studies, we have prepared isotopically labeled Qa-2 and H-2 molecules from mitogen-stimulated C57BL/6 spleen cells. Comparative peptide mapping of tryptic peptides from Qa-2 and H-2 molecules (K^b, D^bK^k, D^d) reveal that Qa-2 has a unique primary structure. However, considerable homology is indicated since 30–40% of the Qa-2 peptides cochromatograph with peptides derived from H-2K^b, H-2D^b, H-2K^k, and H-2D^d. Studies by other investigators have demonstrated that similar levels of structural homology are observed when H-2K, H-2D, and H-2L tryptic peptides are analyzed. We conclude from these studies that the Qa-2 alloantigen is structurally related to a class of cell surface molecules (ie, H-2) that play critical roles in immune recognition processes. These data further suggest that the genes encoding Qa-2 and H-2 molecules have arisen from a common primordial gene.     

Genetic and functional analyses of the primary in vitro CTL: Response of NZB lymphocytes toH-2-compatible cells

Spleen cells from NZB mice make an unexpected primary cytotoxic T lymphocyte (CTL) response to BALB/c cells in vitro. In this study, it is shown that this response is comprised of at least three independent components. These include a response to antigens recognized in association with H-2^d products, a response to Qa-1^b-associated antigens which is notH-2-restricted and a response directed toward antigens not associated with either H-2^d- or Qa-1^b-coded determinants. The last response appears to be the weakest of the three. In addition, cells from NZB F₁ mice which were either homozygous (Qa-1 ^a /Qa-1 ^a ) or heterozygous (Qa-1 ^a /Qa-1 ^b ) forQa-1 alleles, all responded to BALB/c cells. These data suggest that the NZB CTL response to BALB/c cells is not solely dependent on antigens coded for by genes in theH-2D-Tla region for either the sensitization or effector phases of the response. The ontogeny of the NZB anti-BALB/c CTL response coincides with that of a number of B-cell abnormalities but is shown in experiments with-suppressed NZB mice to be independent of B-cell dysfunction. Studies with (NZB x B10.D2)F₁ + B10.D2 mice demonstrated that the anti-BALB/cCTL response to antigens coded for outside ofQa-1 is governed by at least two genes. Finally, it is shown that another conventionallyH-2-restricted response, that to TNP-modified isologous cells, is neither significantly cross-reactive nor markedly elevated in NZB mice. — The foregoing observations suggest that some subsets of NZB T lymphocytes are intrinsically abnormal. The possibilities that the apparent hyperreactivity of NZB CTL precursors, evidenced in the response to BALB/c cells, is primary or results from the secondary effects of excess T-cell help are discussed.     

Antigenic Heterogeneity of Qa-2 Antigens in C57BL/6

The Qa-2 antigens are class I-like molecules encoded by genes mapped telomeric to the H-2D region on chromosome 17 in the mouse. A panel of 8 new monoclonal anti-Qa-2 antibodies derived from a C3H.KBR anti-C3H. SW immunization was studied. Immunoprecipitation of¹²⁵I-labeled C57BL/6 splenocyte antigens showed that all of these antibodies precipitated 40 kDa molecules which could be completely precleared by the monoclonal antibody 20-8-4, which had previously been shown to crossreact with Qa-2. One of the monoclonal antibodies (1-12-1), however, was found not to completely preclear Qa-2 antigens precipitable by the other 7 antibodies or by 20-8-4, suggesting the existence of at least two different species of Qa-2 molecules. Cell lines transfected with Q7 or Q9 genes were reactive with all 9 antibodies and the Qa-2 antigens expressed on surface membranes of these cells were completely precleared by both 20-8-4 and 1-12-1. Therefore, the observed heterogeneity of these molecules cannot be explained by an antigenic difference between the Q7 and Q9 gene products. 2D gel analyses showed identical pI spectra between Qa-2 molecules precipitated with 20-8-4 and 1-12-1. In addition, all of the monoclonal antibodies reacted with labeled antigen preparations following treatment with Endo F or neuraminidase, indicating that carbohydrate moieties are probably not responsible for the antigenic difference between the two species of Qa-2 antigen.     

Expression and regulation of Q8 b in a transfected cell line

RNase protection experiments showed that Q8 ^b was actively transcribed in a stably transfected cell line. Moreover, Q8 ^b responded to interferon- (IFN-) treatment with increased levels of mRNA expression. Thus Q8 ^b demonstrates a regulatory response to IFN- characteristic of many other class I genes. Cell surface expression of a Q8^b product could also be detected by flow cytometric analysis with the Qa-2-specific monoclonal antibody D3.262. The expression of the Q8^b cell surface product increased only slightly after cells were treated with IFN-. The Q8^b cell surface product was not sensitive to cleavage by phosphatidylinositol-phospholipase C. These results suggest that the Q8^b product, unlike the predominant forms of Qa-2-bearing molecules, is not anchored via phosphatidylinositol to the cell membrane. These results also suggest that Q8 ^b has the potential to contribute to the Qa-2 phenotype in vivo. Address correspondence and offprint requests to: L. Flaherty.     

Structure and expression of glycoproteins controlled by the Qa-1 a allele

The alloantigen controlled by the Qa-1 ^a allele is a glycoprotein that exists in two forms. The first, an intracellular molecule of apparent M_r of 44 000 daltons, appears to be a kinetic precursor of the second, a cell-surface molecule with an apparent size of 47 000 daltons. The intracellular form of Qa-1 is distinct from that of the TL glycoprotein in two ways: (1) its polypeptide backbone is approximately 5000 daltons shorter, and (2) it possesses three sites of high-mannose carbohydrate attachment, while TL has only one. In the cell-surface form of Qa-1, all three carbohydrate chains are processed to structures that resist endoglycosidase H digestion, presumably complex-type oligosaccharides. Concomitant with these late carbohydrate-processing steps is the formation of stable complexes between Qa-1 and ₂-microglobulin. The timing of this association provides a further contrast between Qa-1 and TL, which is associated with ₂-microglobulin shortly after its synthesis. The Qa-1 glycoproteins have been identified genetically by their synthesis in B6-TL⁺ (Qa-1 ^a /Tla ^a ) splenocytes but not in splenocytes of congenic 136K1 and B6.K2 (Qa-I ^b /Tla ^b ) mice, and by their absence from the products of BALB/c (Qa-I ^vb /Tla ^c ) splenocytes. The cells synthesizing Qa-1 are at least as prevalent in Ig⁺ spleen-cell populations as in T-cell-enriched splenic Ig^– populations. Thus, active Qa-1 synthesis appears to take place at a high rate in normal splenic B cells without mitogenic stimulation.Abbreviations used in this paper EDTA disodium ethylenediaminetetraacetate - Endo H endo--N-acetylglucosaminidase H - FCS heat-inactivated fetal bovine serum - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - Ig immunoglobulin - PBS Dulbecco's phosphate-buffered saline - SDS sodium dodecyl sulfate - TL thymus leukemia antigen     

Use of hybridoma-resistant variant cell lines to study H-2D b/FMR-specific cytotoxic T cells

An H-2D ^b b heterozygous tumor cell line and a variant subclone bearing a mutant gene product were used to analyze the H-2D^b specificity of cytotoxic T lymphocytes (CTL) generated during a Moloney murine sarcoma virus (MSV) infection. When the mutant cells were used as targets for MSV-specific CTL, the amount of cell lysis, compared with that seen with the nonmutant parental cells, was drastically decreased. However, cells of the mutant clones remained susceptible to allogeneic CTL specific for the nonmutant H-2D^b molecule. The mutant cells also did not differ from the parent cells in their level of viral antigen expression. Biochemically the parental and mutant molecules were similar but not identical. The data indicate that minor alterations of the H-2 antigens caused by somatic mutation may prevent virus-infected cells from being recognized as targets by CTL.     

H-2-linked genes determine the level of the primary in vitro anti-Mls response

The level of cell proliferation and interleukin-2 (IL-2) production observed in an anti-Mls mixed lymphocyte reaction between spleen cells from H-2 compatible, Mls incompatible mouse strains is determined by the H-2 haplotype of the mouse combination. Thus, while AKR (H-2 ^k) spleen cells stimulated strong M1s^a responses in H-2^k responder cells, AKR H-2b spleen cells stimulated no or negligible M1s^a responses in responder cells from H-2 ^bmouse strains. This effect was observed at the levels of IL-2 production and cell proliferation. The magnitude of the response observed using F₁ (H-2 ^k/H-2 ^b) responder cells was found to be a function of stimulator rather than responder cells. The poor stimulatory capacity of AKRH-2 ^bspleen cells was also shown not to be due to the loss of the stimulatory Mls ^aallele during the construction of the congenic strain from AKR and C57BL/6 parental strains. Using stimulator cells from a second series of congenic mice, we found H-2 ^b(strain DLLP) again to represent a poorly Mls^a stimulatory H-2 haplotype. In addition, H-2^q (DBA/1) cells displayed very poor Mls^a stimulatory potential while H-2^d (D1.C) cells were efficient Mls^a stimulators. Again the effect was shown to be at the level of the stimulator cells. In toto, our findings indicate that the H-2 ^kand H-2 ^dhaplotypes encode strong Mls^a stimulatory potential while the H-2 ^band H-2 ^qhaplotypes determine poor Mls^a stimulatory potential in primary in vitro responses, measured as cell proliferation and IL-2 production.Abbreviations used in this paper: CTL cytotoxic T lymphocyte - IL-1 interleukin-1 - IL-2 interleukin-2 - MLR mixed lymphocyte reaction - NMS normal mouse serum     

Immunogenetic analysis ofH-2 mutations

Spleen cells carrying theH-2K ^b allele and sensitized against TNP-modified stimulator cells in vitro displayed a cytotoxic effect against TNP-modified target cells carrying a mutation in theH-2K ^b allele (haplotypesH-2 ^ba ,H-2 ^bd , andH-2 ^bf ). Similar crossreactivity in TNP-CML was observed in the reciprocal direction. Spleen cells carrying theH-2K ^k allele and sensitized against TNP-modified stimulators displayed a cytotoxic effect against TNP-modified target cells carrying a mutation in theH-2K ^k allele (haplotypeH-2 ^ka ) and vice versa. The effector cells in these assays were sensitive to anti-T cell serum in the presence of complement, and supernatants from immune cultures did not induce nonimmune cells to display a cytotoxic effect. Titration of effector cells from mutant and wild-type strains of theH-2 ^b haplotype indicated no detectable quantitative differences in their activities. These data demonstrate that crossreactivity in TNP-CML occurs in closely related allogeneic strains that have recently undergone mutation in theH-2 complex.     

Recognition of the Qa-2k tumor antigen by T cell receptor γ/δ of an immunopotentiator-induced tumoricidal T cell of mice

Tumor-specific expression of Qa-2^k antigen coded by the Q5^k gene on various mouse tumor cells and immunological response of the host mice to the antigen have been demonstrated [Seo et al. (1992) J Exp Med 175: 547; Tanino et al. (1992) Cancer Immunol Immunother 35: 230]. The possibility was examined that Qa-2 antigen is one of the recognition target molecules of immunopotentiator-induced, H-2-nonrestricted tumoricidal lymphocytes of Qa-2^– mice. Lymphocytes stimulated in vivo withP. acnes or culture-induced anomalous killers of B6.K1 mice did not exhibit significant in vitro cytotoxicity against B6.K1 lymphoblasts but lysed their Qa-2,3-congenic counterpart B6 lymphoblasts. To demonstrate the Qa-2 specificity of such cytotoxic cells more precisely, an L cell transformant clone (L^Q7b/Kb), which expressed the 1 and 2 domains of the Qa-2 antigen (Q7^b gene product), was generated by transfecting a cloned plasmid DNA containing a hybrid gene constructed from the 5 half of the Q7^b gene and the 3 half of the H-2K^b gene (pQ7^b/K^b). Using L^Q7b/Kb cells as the target cells and the nylon-wool-nonadherent fraction of lymphocytes fromP. acnes-stimulated (C3H/He × B6.K1)F1 mice (H-2^k, Qa-2^–) as the effector cells of the in vitro cytotoxicity reaction, the presence of cytotoxic cells that recognize the 1/2 region of the Q7^b gene product was demonstrated. The cytotoxic activity was dependent on T cells bearing T cell receptors of the / type (TCR/). The (C3H/He × B6.K1)F1 effector cells, as well as the B6.K1 effector cells also lysed BW5147 lymphoma cells (Qa-2^k+) derived from AKR mice (Qa-2^–, H-2^k). By target-competition experiments it was shown that some of the effector cells lytic to BW5147 were identical to those that lysed L^Q7b/Kb. Therefore some of the tumoricidal cells induced by the immunopotentiator interact with the target tumor cells through recognition of the 1/2 region of the Qa-2^k tumor antigen by TCR/.     

The Qa-1 alloantigens. I. Identification and molecular weight characterization of glycoproteins controlled by the Qa-1a and Qa-1b alleles

Splenocytes from the Qa-Tla congenic strain pairs, A and A-Tlab or B6 and B6-Tlaa, were biosynthetically labeled with 3H-amino acids or cell surface labeled with 125I. Membrane proteins were solubilized with detergent and chromatographed on lentil lectin-Sepharose, and the resulting adherent pools were immunoprecipitated with antisera specific for determinants controlled by the Qa-1a and Qa-1b alleles, Qa-1.1 and Qa-1.2, respectively. Polyacrylamide gel electrophoresis analysis of immunoprecipitates from biosynthetically labeled preparations indicated that both the Qa-1.1 and Qa-1.2 antigens were glycoproteins with a m.w. of approximately 46,000. Qa-1.2 isolated from radioiodinated spleen cells similarly had a m.w. of 46,000. Analysis of anti-Qa-1.1 precipitates from 125I-labeled Qa-1a lysates demonstrated in addition to the 46,000 m.w. component, an electrophoretically heterogeneous protein or series of proteins in the m.w. range of 55,000 to 75,000. The specificity of these reactivities was shown by both antiserum and genetic control immunoprecipitations. These findings indicate that the Qa-1.1 and Qa-1.2 antigens are cell surface glycoproteins that are distinct from the TL antigens, and suggest a further complexity at the Qa-1--Tla locus.