Isolation and characterization of an I-A-restricted T cell clone with dual specificity for poly(Glu60Ala30Tyr10) (GAT) and Mlsa,dl

We have isolated a BALB/c (H-2d, Mlsb) T cell clone (JTL-G12) specific for the synthetic polypeptide antigen poly(Glu60Ala30Tyr10) (GAT) in the context of self I-A determinants and for Mlsa,d antigens in the absence of GAT. JTL-G12 proliferation in response to GAT was mapped to the Kd, I-Ad subregions by using inbred H-2 congenic and recombinant strains. In addition, monoclonal antibody directed against I-Ad but not Kd or I-As determinants blocked JTL-G12 proliferation in response to GAT presented by syngeneic splenocytes, indicating I-A restriction. The Mls cross-reactivity of this clone was verified by using a panel of inbred strains bearing the Mlsa,b,c,d alleles and by using BXD recombinant inbred strains bearing the Mlsa allele or the Mlsb allele. All of the Mlsa BXD strains of the H-2d or H-2b haplotypes stimulated JTL-G12 in the absence of GAT, whereas all of the Mlsb BXD strains were nonstimulatory. This response pattern is in complete accordance with recognition of the Mlsa determinant encoded by Mls or closely linked loci on chromosome 1. JTL-G12 proliferation in response to GAT/I-Ad and Mlsa,d determinants could be blocked with a monoclonal antibody (GK1.5) directed against L3T4, a structure involved in class II major histocompatibility complex antigen recognition. These results suggest that antigen/class II responsiveness, Mls reactivity, and expression of L3T4 can be properties of a single T cell population.     

High resolution structures of highly bulged viral epitopes bound to major histocompatibility complex class I. Implications for T-cell receptor engagement and T-cell immunodominance

Although HLA class I alleles can bind epitopes up to 14 amino acids in length, little is known about the immunogenicity or the responding T-cell repertoire against such determinants. Here, we describe an HLA-B*3508-restricted cytotoxic T lymphocyte response to a 13-mer viral epitope (LPEPLPQGQLTAY). The rigid, centrally bulged epitope generated a biased T-cell response. Only the N-terminal face of the peptide bulge was critical for recognition by the dominant clonotype SB27. The SB27 public T-cell receptor (TcR) associated slowly onto the complex between the bulged peptide and the major histocompatibility complex, suggesting significant remodeling upon engagement. The broad antigen-binding cleft of HLA-B*3508 represents a critical feature for engagement of the public TcR, as the narrower binding cleft of HLA-B*3501(LPEPLPQGQLTAY), which differs from HLA-B*3508 by a single amino acid polymorphism (Arg156 --> Leu), interacted poorly with the dominant TcR. Biased TcR usage in this cytotoxic T lymphocyte response appears to reflect a dominant role of the prominent peptide x major histocompatibility complex class I surface.     

Fine specificity of antibodies to the synthetic polypeptide poly(L-tyrosine, L-glutamic acid)-poly(DL-alanine)--poly(L-lysine) and its ordered analogs as followed by solid-phase radioimmunoassay

The fine specificity of antibodies against (T,G)-A--L and its ordered analogs (T-T-G-G)-A--L and (T-G-T-G)-A--L was studied. Fifty percent of the antibodies against (T,G)-A--L are directed toward the T-T-G-G determinants and 19% against T-G-T-G-like determinants. The rest of the antibody response to (T,G)-A--L is directed against determinants which exist in (T,G)-A--L but are not cross-reactive with either T-T-G-G- or T-G-T-G-like determinants. Although (T-T-G-G)-A--L and (T-G-T-G)-A--L differ only in the sequence of tyrosine and glutamic acid in their side chains, no crossreactivity was observed between antibodies toward the two ordered polypeptide antigens.     

Adjuvant effect of LPS on in vivo antibody response: Genetic defect in C3H/HeJ mice

Among several inbred strains of mice studied, only C3H/HeJ failed to demonstrate LPS enhancement of antibody response to the synthetic polypeptide (T,G)-A-L. LPS antibody enhancement was designated the LPS/adjv(+) trait and results of testing F₁ and backcross animals were consistent with the postulate that the LPS/adjv(+) trait may be determined by a single autosomal dominant gene.     

Regulation of the in vitro presentation of minor lymphocyte stimulating determinants by major histocompatibility complex-encoded immune response genes

Activation of murine B lymphocytes in a splenocyte stimulator population with affinity-purified goat anti-mouse IgD (G alpha M delta) antibody was previously shown by this laboratory to enhance the presentation of strongly stimulatory major histocompatibility complex (MHC) and minor lymphocyte-stimulating (Mlsa,d) determinants in a primary mixed lymphocyte reaction. In the present study, the G alpha M delta treatment of murine splenocytes was employed to enhance the detection of the weakly stimulatory non-MHC Mlsc determinant in order to study the role the MHC might play as a restricting element for the recognition of these minor antigens in a primary mixed lymphocyte reaction. Indeed, enhanced T cell proliferation to Mlsc determinants presented on G alpha M delta-treated splenocytes was observed when the responder and activated H-2-compatible stimulator cell shared certain MHC haplotypes. High responsiveness was associated with the H-2a,k,j,p haplotypes, intermediate responsiveness was associated with the H-2f,g haplotypes and low responsiveness was associated with the H-2b,s haplotypes. (Low X high responder)F1 T cells preferentially responded to the Mlsc determinants presented on G alpha M delta-treated stimulator cells of the F1 or parental high responder H-2 haplotype. When mitomycin C instead of irradiation was used to inactivate normal (non-IgD-treated) splenocytes, a similar preferential response of T cells to Mlsc determinants presented on stimulator cells of a high responder H-2 haplotype was also observed. The inability of G alpha M delta-treated splenocytes of the low responder haplotype to elicit substantial levels of T cell proliferation across an Mlsc difference could not be attributed to the failure of these stimulator cells to become activated by the anti-Ig antibody. In addition, co-culture experiments could not identify the poor T cell response to Mlsc determinants presented on certain MHC haplotypes as being caused by the induction of nonspecific suppressor cells. Presentation of Mlsc determinants caused by transgene product complementation was detectable in F1 mice derived by crossing one parent that had the Mlsc non-MHC genes and a poorly permissive H-2 haplotype with a parent that expressed a permissive H-2 haplotype but lacked the Mlsc non-MHC genes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cross-stimulation of antigens under separate histocompatibility-linkedIr gene control

The antibody response of rats to the related polypeptide antigens (T,G)-A —L, (H,G)-A -L, and (Phe,G)-A -L is controlled byIr gene(s) linked to the major histocompatibility genes. When lymph node cells of rats primed with one of these polypeptides were cultured with the homologous antigen, a proliferative secondary response was induced with cells from high, but not from low responder strains. Thus, responsiveness as defined by antibody production is clearly reflected in this cellular in vitro assay.In contrast to the antipolypeptide antibodies which crossreact extensively, no crossreaction could be detected on the cellular level among the three polypeptides except for one combination: (T,G)-A -L-primed cells were strongly cross-stimulated by (Phe,G)-A -L, but the opposite was not true. The two antigens, however, show a distinct response pattern in various rat strains. The unilateral cross-stimulation may be explained by the special chemical relationship of determinants containing tyrosine and phenylalanine residues. It could occur on the level of the T cell receptor or, if distinct from it, on that of theIr gene product.Abbreviations used in this paper are as follows GT linear copolypeptide, poly (L-Glu, L-Tyr) - (T,G)-A-L the branched synthetic polypeptides poly(L-Tyr, L-Glu)-poly-DL-Ala-polyL-Lys - (H,G)-A -L the branched synthetic polypeptides poly(L-His, L-Glu)-poly-DL-Ala-poly-L-Lys - (Phe,G)-A-L poly(L-Phe, L-Glu)-poly-DL-Ala — poly-L-Lys - i.m. intramuscularly - LDH_A lactate dehydrogenase, isozyme A - MBSA methyl ester of bovine serum albumin - PHA phytohemagglutinin ofPhaseolus vulgaris     

Augmentation of the antibody response by hapten help: I. Dominant genetic control

The objective of the present work was to characterize those genetic factors that determine susceptibility to “hapten help,” i.e., the augmentation of B-cell responses by hapten-reactive T cells. After mice had been sensitized to the hapten azobenzenearsonate (ABA), one of two approaches was used to assay hapten help. In the first, circumvention of tolerance to low doses of bovine γ-globulin (BGG) was augmented in CBA but not in C57BL/6 mice, as measured by serum anti-BGG antibody after challenge with ABA-BGG. Second, similar strain differences but on a larger scale were demonstrated in the anti-BGG plaque-forming cell (PFC) response of spleen cells from hapten-primed nontolerized mice after challenge with ABA-BGG. Results with the F1-hybrid of a cross between a high responder and a low responder for hapten help demonstrated that high responsiveness is dominant. Experiments with recombinant inbred mice from high- and low-responder progenitor strains suggested that hapten help is associated not with the major histocompatibility complex (H-2) so much as with minor histocompatibility antigens such as H-22 and/or H-24, both of which are on chromosome 7.     

Antigen-specific T-cell factor in cell cooperation and genetic control of the immune response.

Cell interactions between thymus-derived (T) and bone marrow-derived (B) lymphocytes in the antibody response appear to involve soluble T-cell mediators known as 'factors.' This paper describes the properties of a T-cell factor that has specificity for the inducing antigen, a synthetic polypeptide (T, G)-A--L, and is able to replace T cells in the thymus-dependent antibody response to (T, G)-A--L. Besides antigen specificity, the main features of the molecule are that it is nonimmunoglobulin; it has a molecular weight of about 50,000; and it is a product of the I-A subregion of the H-2 complex (the mouse major histocompatibility complex). These properties suggest that the factor is closely related to the T-cell receptor, which may, by inference, also be a product of the H-2 complex. The factor cooperates well with allogeneic B cells. It can also be absorbed by bone marrow cells and B cells. Studies on the genetic control of the immune response to (T, G)-A--L using the T-cell factor indicate that two immune response genes in the H-2 complex are involved in genetic control, one expressed in T cells and the other in B cells. This two gene hypothesis has been confirmed by showing that an F1 between two low responders to (T, G)-A--L can be a high responder.     

Genetic control of IgM responses to (T,G)-A — L

The primary antibody response to aqueous immunization with a low molecular-weight lot of (T,G)-A — L (#420) was studied in congenic pairs of inbred mouse strains. Two new genetic controls were identified, both of which quantitatively regulate the production of IgM anti-(T,G)-A — L antibody. Testing of F₁ and F₂ progeny demonstrated that one of these genes is linked to the major histocompatibility (H-2) complex, and that high response is dominant over low response. Whether this gene is identical toIr-1A is not yet known. The other gene, designatedIg-TGAL _M , is linked to the immunoglobulin heavy-chain allotype locus (Ig-1) and is expressed in a genedose dependent manner. Following secondary challenge with (T,G)-A — L 420, quantitative differences in IgG antibody response were observed inIr-1A high-responder congenics differing only at theIg-1 locus. Breeding studies, however, failed to demonstrate any linkage between this locus and the quantitative control of IgG anti-(T,G)-A — L antibody. These data demonstrate thatH-2-linked immune response genes can regulate IgM as well as IgG antibody responses, that genetic control of the IgM response to (T,G)-A — L is linked toIg-1, and that bothH-2-linked andIg-1-linked genes may simultaneously affect an IgM antibody response to the same antigen.Abbreviations used in this paper are (T,G)-A — L poly-l-(Tyr,Glu)-poly-d,l-Ala-poly-l-Lys - NMS normal mouse serum - SRBC sheep red blood cells - i.p. intraperitoneal - PBS phosphate-buffered saline - RAMG polyvalent rabbit anti-mouse globulin - 2-Me 2-Mercaptoethanol - 2-MeS 2-Me-sensitive - PFC plaque-forming cells - ABC antigen-binding cells     

Inverse Ir gene control of the antibody and T cell proliferative responses to human basement membrane collagen

The immune response to pepsin-soluble human basement membrane-derived type IV collagen in mice has been characterized. Both T cell proliferative and antibody responses have been shown to be under major histocompatibility complex (MHC)-linked Ir gene control in inbred and MHC congenic mice. However, unlike previous examples studied, this response shows a separation of these two types of immunologic responsiveness. Only mice having I-As give potent in vitro T cell proliferative responses to type IV collagen whereas all mice except those having I-As give high antibody responses to this antigen. In (I-As X I-Anon-s) F1 mice, the T cell proliferative response was dominant, whereas antibody responses were markedly reduced compared with the responder parent. Given the recent demonstration that class II MHC-restricted, L3T4+ T cells can be divided into two sets, one of which helps for antibody responses and the other of which produces interleukin 2 and can also suppress such responses, it seems likely that these data can be accounted for on the basis of differential activation by this antigen of these two cell sets in mice of different MHC genotypes.     

The role of the macrophage in genetic control of the immune response.

The ability of an animal to mount an immune response is controlled by a number of autosomal dominant immune response (Ir) genes that are linked to the major histocompatibility complex of the species. In the guinea pig, alloantiserums raised by cross-immunization of inbred strain 2 and strain 13 animals specifically inhibited the in vitro proliferative responses of (2 X 13) F1 lymphocytes to those antigens the response to which is controlled by Ir genes linked to the alloantigens against which the serums are directed. A genetic analysis indicated that the inhibitory activity of the alloantiserums was directed against the alloantigens rather than the products of specific Ir genes. The interaction of antigen-pulsed macrophages with immune T lymphocytes is also mediated by the 2/13 alloantigens and alloantiserums are capable of inhibiting macrophage-T lymphocyte interaction. Studies involving combinations of macrophages and lymphocytes that differed at alloantigens or Ir gene products or both raised the possibility of the expression of the Ir gene product in the macrophage.     

Anti-influenza virus cytotoxic T lymphocytes recognize the three viral polymerases and a nonstructural protein: responsiveness to individual viral antigens is major histocompatibility complex controlled

It has recently been shown that antiviral major histocompatibility complex class I-restricted cytotoxic T lymphocytes can recognize proteins that serve as internal viral structural components (influenza A virus nucleoprotein, vesicular stomatitis virus nucleocapsid protein). To further examine the role of internal viral proteins in cytotoxic T-lymphocyte recognition, we constructed recombinant vaccinia viruses containing individual influenza A virus genes encoding three viral polymerases (PB1, PB2, PA) and a protein not incorporated into virions (NS1). We found that cells infected with each of these recombinant vaccinia viruses could be lysed by anti-influenza cytotoxic T lymphocytes. Cytotoxic T-lymphocyte responsiveness to the individual viral antigens varied greatly between mouse strains. By using congenic mouse strains, responsiveness to PB1 and PB2 was found to cosegregate with major histocompatibility complex haplotype. These findings provide further evidence that internal antigens play a critical role in cytotoxic T-lymphocyte recognition of virus-infected cells. Additionally, they suggest that the cytotoxic T-lymphocyte response to viral antigens may often be restricted to only a fraction of the major histocompatibility complex class I repertoire.     

Linkage of the gene controlling the synthesis of the fourth component of complement to the major histocompatibility complex of the guinea pig

C4-deficient (C4D) guinea pigs are lacking in C4 synthesis, a condition that appears to be caused by a structural gene defect. This defect is inherited as a simple autosomal recessive trait. We have demonstrated linkage between C4D and the major histocompatibility complex of the guinea pig (GPLA). Inbred C4D and inbred strain 13 guinea pigs appear to have the same GPLA haplotype. The use of these two strains should provide an animal model for reconstitution studies of C4 synthesis and for studied exploring the possible role of C4 in cellular and humoral immune responses.Abbreviations used in this paper are C4D deficiency of the fourth component of complement - MHC major histocompatibility complex - GPLA major histocompatibility complex of the guinea pig - MLC mixed lymphocyte culture     

Analysis of the major histocompatibility complex in Syrian hamsters. III. Cellular and humoral immunity to alloantigens.

Among the genetic loci incorporated into the major histocompatibility complex in every species studied to date have been prominent genes encoding for strong histocompatibility determinants that elicit detectable alloantibody responses and which are the chief antigenic targets of cell-mediated cytotoxicity reactions. The K and D regions of the H-2 complex in the mouse and the A, B, and C regions of the HLA complex in man are representative examples. Syrian hamsters, as described in this report, do not make alloantibodies to antigens of this type and only very poorly do they carry out in vitro cell-mediated cytotoxicity to target cells putatively bearing these antigens. Since hamsters are quite capable of discriminating analogous antigenic differences in xenogeneic species, and xenogeneic sources cannot distinguish immunologically between the antigens encoded by the two hamster major histocompatibility alleles. Hm-1a and Hm-1b, we conclude that the hamster strains we work with are serologically indistinguishable by the methods used here. However, they obviously differ for determinants which elicit T cell-mediated responses, as evidenced by their ability to express acute skin graft rejection, mixed lymphocyte reactivity, graft-vs-host reactions, and cell-mediated cytotoxicity reactions. Such alloreactivity may reflect a mutation at an SD locus, affecting antigenic sites recognized only by T cells, or that the available hamster strains are SD identical, but differ at loci similar to the I region loci in mice. Alternatively, we cannot exclude the possibility that Syrian hamsters somehow fail to express properly the genes coding for SD determinants.     

Genetic control of sensitivity to Moloney leukemia virus in mice. II. Mapping of three resistant genes within the H-2 complex.

The level of viremia and the appearance of leukemias were studied after inoculation wtih Moloney leukemia virus (M-MuLV) in different H-2 congenic strains of mice. The viremia was regularly measured on individual mice with a radioimmunoassay of the major internal virion component p30. Three genes within the major histocompatibility complex controlled the level of circulating virus. Two of them, called Rmv.1 and Rmv.2, appear to be located in the I region, respectively, in the IA, and the IC-S or G regions. The third gene, Rmv.3, was mapped to the D end of the complex in the D or T region. Crosses between resistant and sensitive strans demonstrated that the H-2 associated resistance was inherited as a dominant or semi-dominant Mendelian trait. Rmv.1, Rmv.2, and Rmv.3 were shown to complement for resistance in trans when the hybrids between sensitive strains were examined. A good correlation was found between viremia and the appearance of leukemias, the most viremic strains being also the most leukemic. Nevertheless, additional non-H-2 genes must control viremia and/or the appearance of leukemia since, despite high levels of viremia, some sensitive strains do not become leukemic.     

Immunochemical properties of the aminopropeptide of procollagen type III

The precursor-specific aminopropeptide of bovine type III procollagen is a strong immunogen in rabbits, guinea pigs and mice and induces antibodies which do not cross-react with type I procollagen. The antibody response is regulated by immune response genes associated with the major histocompatibility complex. Major antigenic determinants were found in the compact, non-collagenous domain (fragment Col 1) located at the N terminus of the aminopropeptide and were destroyed by reduction of disulfide bonds. Minor antigenic determinants independent of disulfide bonds also exist in fragment Col 1 and could be localized on a distinct tryptic peptide. Fragment Col 1 showed a lower affinity for antibody when compared with the intact aminopropeptide which causes a non-parallel shift in radioimmuno-inhibition profiles. Monovalent antibody fragments showed an average tenfold reduction in affinity constant and failed to distinguish between aminopropeptide and fragment Col 1. This indicates that the stronger binding of bivalent antibody by the triple-stranded aminopropeptide is due to multiple interactions with both antibody binding sites which are lost for a single-stranded antigen (Col 1) or with monovalent antibody fragments.     

Nucleoside specificity in the carrier IgG-dependent induction of tolerance.

Induction of tolerance to nucleoside haptens in BALB/c mice with isologous IgG conjugates bearing four nucleosides simultaneously (A, G, C, T)-IgG was confirmed. A mixture of separate nucleoside-IgG tolerogens (A-IgG, G-IgG, C-IgG, and T-IgG) was as effective or more effective that the (A, G, C,T)-IgG form in suppressing the response to (A, G, C, T)-KLH. The nucleosides acted independently and simultaneously, since tolerogens with varying combinations of nucleosides caused specific suppression of the respones to only those nucleosides present on the tolerogen. Nucleoside-IgG conjugates did not suppress the response to denatured DNA-methylated bovine serum albumin, in which larger oligonucleotide determinants predominate. In varying combinations, guanosine was the dominant nucleoside both for immunization and for induction of tolerance. After three or four immunizations, control immunized animals made mainly IgG anti-nucleoside antibodies and this IgG antibody formation was preferentially suppressed in tolerogen-treated animals. Tolerance could be established before the primary or secondary immunization and it then persisted for at least 75 days through a fourth course of immunization. The same dosage of tolerogen did not reverse a strongly established anti-nucleoside antibody production after a tertiary response.     

The expression of Mls c determinants on Mls a,Mls b,and Mls x prototypic strains

In the mouse sytem, specific determinants other than major histocompatibility complex (MHC) gene products are capable of inducing strong primary proliferative responses in naive T cells. These determinants are encoded by at least two gene loci designated as minor lymphocyte stimulatory (Mls) loci. In order to elucidate the biological role of the Mls system, an effort has been initiated to clarify the fundamental immunogenetic characteristics of the Mls system. In this report, we describe the unexpected finding that Mls ^c determinants are expressed on splenocytes of strains including those which have been used as prototypic examples of three other Mls types: Mls ^a (DBA/2, DBA/1), Mls ^b , (BALB/c), and Mls ^x (PL/J). The expression of Mls ^c by these strains was demonstrated both by the response patterns of unprimed T cells from MHC-identical inbred or F₁ hybrid strains and by the responses of a panel of Mls-specific T-cell clones. The experimental results reported here also suggest that the expression of Mls determinants may be influenced by multiple other genes, including MHC-linked genes.Abbreviations used in this paper MHC major histocompatibility complex - MLR mixed lymphocyte reaction - Mls minor lymphocyte stimulating locus antigen - MMC mitomycin C - NNT nylon wool nonadherent T cells     

Experimental allergic orchitis in mice

Inbred strains of mice were studied for their susceptibility to the induction of experimental allergic orchitis after sensitization with mouse testicular homogenate in complete Freund's adjuvant accompanied by injections of extract from Bordetella pertussis. Susceptibility to autoimmune orchitis was found to be linked to the major histocompatibility complex in BALB/c and C57BL/10 mice and mapped to genes encoded within the H-2D ^dregion. In five of six groups of bidirectional (susceptible × resistant) F₁ hybrids, H-2D ^d-linked susceptibility was inherited as a dominant autosomal trait. However, in (BALB/cByJ × DBA/2J)F₁ and (DBA/2J × BALB/cByJ)F₁ hybrids, dominant autosomal resistance to the induction of autoimmune orchitis was observed. Backcross analysis between the resistant F₁ hybrid and the susceptible BALB/cByJ parent suggests that a single independently segregating DBA/2J locus is capable of negating H-2D ^d-linked susceptibility, and controls resistance to the induction of autoimmune orchitis.Abbreviations used in this paper BP extract Bordetella pertussis extract - CFA complete Freund's adjuvant - EAO experimental allergic orchitis - Ir immune response - MHC major histocompatibility complex - MLH mouse liver homogenate - MTH mouse testis homogenate - PI pathology index     

Phosphorylation of the CD8 antigen on cytotoxic human T cells in response to phorbol myristate acetate or antigen-presenting B cells

We have used the monoclonal antibody OKT8 to demonstrate that the cluster designation (CD)8 antigen on cytotoxic human T cells undergoes a previously unreported protein modification. Immunoprecipitation of CD8 with OKT8 from a CD8+ and CD4+ T cell line prelabeled with [32P]phosphate demonstrates that CD8 can be constitutively labeled with phosphate. CD8 undergoes rapid and intense phosphorylation in serine upon addition of phorbol myristate acetate to the cells. CD8 phosphorylation is induced upon addition of heterologous, Epstein-Barr virus-transformed B cells, which cause proliferation and are target cells for a cytotoxic CD8+CD4+ T cell line and a CD8+CD4- T cell clone. Phosphorylation induced by targets is dose-dependent, rapid, and followed by a fast dephosphorylation. Epstein-Barr virus-transformed B cells that do not induce proliferation of and are not targets for the CD8+CD4+ line and the CD8+CD4- clone do not induce CD8 phosphorylation. Cloned CD8+CD4- cells that proliferate in response to target cells, but lyse them only in the presence of lectin do not undergo target cell-induced CD8 phosphorylation. These data suggest that induction of CD8 phosphorylation is antigen-specific and is coincident with the cytotoxic response. Finally, preincubation of effector and target cells with an antibody to a monomorphic determinant of major histocompatibility complex class I antigens reduces target-induced CD8 phosphorylation to a greater extent than antibody to a major histocompatibility complex class II subregion (DR) monomorphic determinant, reinforcing the notion that major histocompatibility complex class I antigens interact with CD8+ cells.