Lymphoid specificity of a copy number-related expression of the H2-Kb transgene.

Transcriptional regulation of the MHC class I genes leading to their developmental and tissue specific expression is still poorly understood in spite of the recovery of a large variety of cis-controlling sequences and trans-acting factors pertaining to the 5' enhancer and the downstream regulatory element. Here we produced a series transgenic lines of mice with a genomic subclone of the H2-Kb gene consisting of 367 bp of the 5' upstream region, the coding region and 1.5 kb of the 3' downstream region and carrying all hitherto known regulatory sequences. The comparison of nine transgenic lines carrying the same H2-Kb transgene made it possible to ask whether the cis-information present in the transgene was sufficient for the tissue- and developmental-specific expression and its copy number dependence. We found the proper developmental onset of expression of the transgene at day 13 p.c. and correct tissue specific mRNA levels in adult mice. While in lymphoid tissues and in lung the number of transgene copies still correlated with RNA levels, the copy number dependence was completely lost in liver, kidney and embryonic tissues. Comparison with previously published H2-Kb transgenes indicates that the H2-Kb locus-controlling region is composed of more than one element.

Identification of the Tapasin gene in the chicken major histocompatibility complex.

The Tapasin molecule plays a role in the assembly of major histocompatibility complex (Mhc) class I molecules in the endoplasmic reticulum, by mediating the interaction of class I-beta2-microglobulin dimers with TAP. We report here the identification of the Tapasin gene in the chicken Mhc (B complex). This gene is located at the centromeric end of the complex, between the class II B-LBI and B-LBII genes. Like its human counterpart it comprises 8 exons, but features a significantly reduced intron size as compared to the human gene. Chicken Tapasin codes for a transmembrane protein with a probable endoplasmic reticulum retention signal. Exons IV and V, and possibly exon III, code for separate domains that are related to the immunoglobulin (Ig) superfamily (this relationship was so far unrecognized for human Tapasin domain IV which has lost its two cysteines). Two different cDNAs corresponding to the Tapasin gene were isolated, possibly related to alternative splicing events; the Ig-like domain encoded by exon IV is missing in one of the cDNAs, suggesting either that this domain is not necessary for the protein to perform its function, or that the two alternatively spliced cDNAs are translated into two functionally different forms of the protein.

Allogeneic recognition of class I molecules: anti-H-2Ld repertoire of H-2b mice includes T cells recognizing mutant class II H-2b (Abm12) molecules.

Two major histocompatibility complex (MHC) class I-reactive T cell clones derived from H-2b mice, generated against the allogeneic Ld molecule, were found to recognize the H-2b class II mutant Abm12 molecule as well. In addition, these clones also recognize the class II A(s) molecule, and display a class II-dependent reactivity to staphylococcal enterotoxin B. Neither the class I nor the class II alloreactivities of the clones were found to be dependent on other MHC molecules. Both clones express CD4+CD8- phenotypes. The CD4 molecule appears to be involved in their class II reactivity, while little or no role for CD4 could be detected in the class I reactivity. This is the first report of a class I/class II cross-reactivity being mediated by CD4+ T cells. The structural basis for this cross-reactivity is discussed.

Biochemical and functional characteristics of soluble MHC molecules derived from H-2Ld/Q10d chimeric gene.

We have constructed a chimeric class I gene in which the 5' half of the H-2Ld gene is linked to the 3' half of Q10d. The resulting H-2Ld/Q10d protein is homologous to the native H-2Ld heavy chain for the three external domains except for an Arg to His substitution at position 260. The transmembrane and intracytoplasmic domains of the H-2Ld chain are replaced by the short low hydrophobic transmembrane-like domain of the Q10d chain. Following DNA-mediated gene transfer into mouse L cells, transformants were selected for the presence of specific mRNA. Radiolabelling and immunoprecipitation analysis revealed secretion of a 48-46 kd chain weakly associated with beta 2-microglobulin. This molecule reacts with H-2Ld-specific mAb that identify determinants on the first and second domains as well as with an anti-Q10 carboxyl-terminal peptide antiserum, but is not recognized by a mAb specific for a determinant of H-2Ld third domain. The integrity of antibody reactivity of the first and second domains together with beta 2-microglobulin association suggest that our molecule may be considered a good soluble counterpart of the native membrane H-2Ld molecule with which to perform functional studies. In order to analyze the immunogenic capacities and T-cell recognition of the soluble H-2Ld molecules, T-cell lines were produced from mice of various inbred strains immunized with supernatant from H-2Ld/Q10d-transfected fibroblasts. Characterization of these T cells revealed that they expressed a CD4+CD8- phenotype, and recognized H-2Ld/Q10d products in a class II-restricted manner.

Cross-reactivity among evolutionarily distant major histocompatibility complex class I molecules (HLA-B27 and H-2Kk) revealed by xenoreactive T lymphocytes.

A set of mouse HLA-B27-reactive cytotoxic T lymphocyte clones were found to recognize the HLA-B27 molecule in an H-2-unrestricted manner, i.e. independently of any mouse major histocompatibility complex (MHC) molecule. The reactivity patterns of these clones on HLA-B27 variants (positive only on HLA-B*2702 and HLA-B*2701) allowed the identification of residues N77 and A81 of the HLA-B27 molecule as important for their reactivity. The location of these residues in the peptide-binding groove (specificity pocket F) suggested that the reactivity of the clones is dependent on HLA-B27-bound peptide(s). However, several other class I molecules sharing these residues (N77 and A81) were not recognized, indicating that other residues might also be involved. One of the clones was found to display an interesting cross-reactivity with allogeneic H-2Kk molecules, sharing N77 and A81 with HLA-B*2702. Sequence comparison suggested the involvement of residue H9, located in specificity pocket B of the peptide-binding groove, and revealed some similarity of pockets B in HLA-B27 and H-2Kk. The structural basis of such T cell-mediated MHC cross-reactions across species barriers is discussed.

Localization of the conformational alteration of MHC molecules induced by the association of mouse class I heavy chain with a xenogeneic beta 2-microglobulin.

Changes in the antigenicity of major histocompatibility complex (MHC) class I molecules resulting from the association of bovine beta 2-microglobulin (beta 2-m) with mouse class I heavy chains were investigated. Mice (H-2b) were immunized with syngeneic Concanavalin A (Con A) blasts induced in the presence of fetal calf serum (FCS) in conditions allowing exchange between mouse and bovine beta 2-microglobulin (beta 2-m). Spleen cells from hyperimmunized mice were fused with myeloma cells and two monoclonal antibodies which required for their reactivity the presence of FCS have been further studied. One of them (CAB 297) recognized a determinant of bovine beta 2-m which is present on free molecules in solution as well as when they are associated with either mouse or bovine class I heavy chains. In contrast, the second monoclonal antibody (CBB 70) did not react with free bovine beta 2-m molecules, nor with beta 2-m associated with bovine class I heavy chains. It did react with cells of some H-2 haplotypes (b, f, p and r) but only when their class I heavy chains are associated with bovine or with human beta 2-m. Therefore, expression of the CBB 70 defined antigenic determinant requires both xenogeneic beta 2-m and class I heavy chain of a given H-2 molecule. In order to precisely localize the antigenic determinant defined by this monoclonal antibody and therefore the region altered by the association of class I heavy chain with xenogeneic beta 2-m, we made use of exon shuffled class I molecules. The results indicate that changes induced by the association of bovine beta 2-m with H-2 class I heavy chain affect the conformation of the alpha 2 domain. These studies illustrate that MHC class I molecules exhibit a considerable conformational flexibility which could influence their ability to bind and present various peptides to the T-cell receptor.

Recognition of HLA-B27 by mouse cytotoxic T-cell clones: a transgenic mouse model.

As a basis for the characterization of mouse T cells involved in the recognition of xenogeneic HLA molecules, a panel of HLA-B27-reactive cytotoxic T-cell clones was generated upon stimulation by cells from HLA-B27-transgenic mice. The HLA-B27-induced T-cell response was found to comprise two categories of clones: some recognizing HLA-B27 independent of H-2 molecules expressed by the target cells (unrestricted clones), others recognizing HLA-B27 in an H-2-restricted manner. The unrestricted clones exhibited diverse specificities, as judged from their various cross-reactivities with other xenogeneic (HLA) or allogeneic (H-2) molecules. In addition, although most of the unrestricted clones were able to react with both mouse and human HLA-B27-transgenic mice. The HLA-B27-induced T-cell which reacted only with HLA-B27-positive mouse, and not human cells. These findings illustrate that both H-2-restricted and unrestricted T cells with diverse specificities contribute to HLA-B27-xenorecognition.

Clonal anergy induced in mature V beta 6+ T lymphocytes on immunizing Mls-1b mice with Mls-1a expressing cells.

Tolerance to self-antigens has been shown to develop during ontogeny as a result of the clonal deletion of self-reactive T cells. Tolerance, or better 'nonresponsiveness', to specific antigens can also be induced in adult animals but the mechanism(s) involved are not well understood. Most murine T-helper cells that express the V beta 6 T-cell receptor gene segment are specific for Mls-1a antigens. We have therefore been able to use an anti-V beta 6 monoclonal antibody to follow the fate of Mls-1a specific T cells in adult Mls-1b mice made specifically unresponsive to Mls-1a. We show that the induced unresponsiveness is not due to clonal deletion, but rather to clonal anergy. The anergic V beta 6 T-helper cells express IL-2 receptors and undergo limited blastogenesis in vitro upon stimulation, but do not produce IL-2, in marked contrast to V beta 6 cells from naive mice. Our data appear to represent an in vivo correlate for the induction of anergy that has been observed in T-cell lines in vitro.

Alternative T cell receptor gene usage induced by self tolerance.

Ab-restricted, H-Y-specific T cell clones from C57BL/6 mice were found to use predominantly V beta 6 T cell receptor genes, conferring Mls-1a reactivity. However, the expression of Mls-1a as a self antigen in (DBA/2 x C57BL/6)F1 mice did not turn these mice into nonresponders to H-Y. Instead of V beta 6, they used other T cell receptor genes in this response. Thus, self tolerance appears to bias the repertoire of T cell receptor genes used in response to foreign antigens, without necessarily impairing the immune responsiveness to these antigens.

Immune response to H-2 class I antigens on platelets. II. Specific decrease of H-2 class I-specific antibody response induced by treatment with allogeneic platelets.

Mice pretreated with injections of allogeneic platelets were found to mount a decreased antibody response upon challenge by lymphocytes of the same donor strain. This decrease was mediated by platelets themselves, and not by leucocytes and red cells contaminating the platelet suspension. It affected specifically antibodies reactive with H-2 class I antigens present on donor platelets. This phenomenon may be related to the lack of class II or some non-H-2 antigens on platelets, and/or to properties of their class I antigens (soluble molecules adsorbed from the plasma). These findings emphasize the potential usefulness of purified platelet transfusions preceding organ transplantation in man.

Immune response to H-2 class I antigens on platelets. I. Immunogenicity of platelet class I antigens.

Purified allogeneic murine platelet suspensions were found unable to induce primary anti-H-2 class I antibody or T cell proliferative responses. In contrast, the same platelet suspensions could elicit secondary anti-class I responses. The secondary responses were not due to contaminating leucocytes. Possible explanations, the lack of acolyte determinants (class II or non- H-2) on platelets or inappropriate layout and/or structure of their class I antigens, are discussed. These findings emphasize the importance of sufficient leucocyte depletion before platelet transfusion in the human.

High frequency of Mlsa-reactivity among Ab-restricted, H-Y-specific T cell clones.

A high frequency (80%) of Ab-restricted, H-Y-specific T cell clones, but not of Ab-restricted LDH-B-specific T cell clones, was found to be Mlsa-reactive. This reactivity could be inhibited by class II (A and E)-specific antibodies, and required an E-positive stimulator cell. The proliferation was also blocked by T cell receptor-specific and by CD4-specific antibodies. Possible interpretations of these findings are discussed.

Anti-MHC immunity detected prior to intentional alloimmunization. IV. Natural monoclonal H-2-specific antibodies.

Naturally occurring H-2-specific antibodies can be detected rather frequently in sera of non-alloimmunized mice by sufficiently sensitive techniques (Cerny-Provaznik et al., 1985a; Cerny-Provaznik & Ivanyi, 1985). In this report, we summarize our experiences with the preparation of monoclonal anit-H-2 antibodies obtained from hybridization experiments from non-alloimmunized mice. From a total of 30 spleen cell hybridization experiments, we could isolate only four anti-H-2 monoclonal antibodies (mAB). Two of the mAB are described in this report. Monoclonal antibody By-2 is anti-Kf and mAB By-3 is anti-Db, Ds. We investigated which conditions favour the isolation of monoclonal H-2-specific antibodies from non-alloimmunized mice. The presence of naturally occurring serum antibodies, the age of the spleen donor mouse or non-specific B cell stimulation were not critical for the isolation of natural anti-H-2 mAB. We hypothesise that the 'natural' H-2-specific antibodies represent compartments of the B cell repertoire which were triggered by modified or aberrant self-MHC expression.