Mesenchymal stromal cells inhibit proliferation of virus-specific CD8(+) T cells.

Mesenchymal stromal cells (MSCs) possess broad immunomodulatory capacities that are currently investigated for potential clinical application in treating autoimmune disorders. Third-party MSCs suppress alloantigen-induced proliferation of peripheral blood mononuclear cells providing the rationale for clinical use in graft-versus-host disease (GvHD). We confirmed that MSCs strongly inhibited proliferation of CD8(+) T cells in a mixed lymphocyte reaction. However, MSCs also suppressed proliferation of T cells specifically recognizing cytomegalovirus (CMV) and influenza virus. Inhibition was dose dependent, but independent of the culture medium. MSCs inhibited proliferation of specific CD8(+) T cells and the release of IFN-γ by specific CD8(+) T cells for immunodominant HLA-A2- and HLA-B7- restricted antigen epitopes derived from CMV phosphoprotein 65 and influenza matrix protein. This is in contrast to a recently reported scenario where MSCs exert differential effects on alloantigen and virus-specific T cells potentially having an impact on surveillance and prophylaxis of patients treated by MSCs.

Specific treatment of autoimmunity with recombinant invariant chains in which CLIP is replaced by self-epitopes.

The invariant chain (Ii) binds to newly synthesized MHC class II molecules with the CLIP region of Ii occupying the peptide-binding groove. Here we demonstrate that recombinant Ii proteins with the CLIP region replaced by antigenic self-epitopes are highly efficient in activating and silencing specific T cells in vitro and in vivo. The Ii proteins require endogenous processing by antigen-presenting cells for efficient T cell activation. An Ii protein encompassing the epitope myelin basic protein amino acids 84-96 (Ii-MBP84-96) induced the model autoimmune disease experimental allergic encephalomyelitis (EAE) with a higher severity and earlier onset than the peptide. When applied in a tolerogenic manner, Ii-MBP84-96 abolished antigen-specific T cell proliferation and suppressed peptide-induced EAE more effectively than peptide alone. Importantly, i.v. administration of Ii proteins after EAE induction completely abrogated the disease, whereas peptides only marginally suppressed disease symptoms. Ii fusion proteins are thus more efficient than peptide in modulating CD4(+) T cell-mediated autoimmunity, documenting their superior qualities for therapeutic antigen delivery in vivo.

The cluster of BTN genes in the extended major histocompatibility complex.

We sequenced the 170-kb cluster of BTN genes in the extended major histocompatibility complex region, 4 Mb telomeric of human leukocyte antigen class I genes, at 6p22.1. The cluster consists of seven genes belonging to the expanding B7/butyrophilin-like group, a subset of the immunoglobulin gene superfamily. The main complex is composed of six genes, from two subfamilies, BTN2 and BTN3, arranged in pairs. This alternating pattern must have evolved by duplications of an original block of two genes, one from each subfamily. The sequences from the two subfamilies share approximately 50% amino acid identity. By analysis of repeat elements within each block, these duplications may be dated to approximately 100 million years ago, at about the time of the branching of the Rodentia and Primate lineages. The single BTN1A1 (butyrophilin) gene was positioned approximately 25 kb centromeric to the cluster. Each gene covers approximately 12 kb and consists of seven (BTN2 subfamily) or nine (BTN3 subfamily) coding exons. The predicted leader sequence, immunoglobulin-like IgV (variable)/IgC (constant) ectodomains, and the predicted transmembrane domain are encoded on separate exons and are separated from a B30.2 domain by a variable number of very short exons, 21 and 27 nucleotides in length. BTN transcripts were detected in all tissues examined. Alternative splicing, involving particularly the carboxyl-terminal B30.2 domain, was a notable feature. Most transcripts of BTN2 subfamily genes contained this domain, whereas BTN3 genes did not. Using immunofluorescence, we showed surface expression of BTN-green fluorescent protein fusions in mammalian cell transfectants.

An example of immunodominance: engagement of synonymous TCR by invariant CDR3 beta.

The structural basis of the T cell response against immunodominant tetanus toxin (TT)-derived peptides was investigated using TT-specific T cell clones raised from a DRB1*0301 homozygous donor. Three peptides forming T cell epitopes were identified, including one, TT(1272-1284), that stimulated four different TT-specific T cell clones. TCR sequence analysis revealed that these synonymous TCR shared only arginine at the third position of the CDR3 beta loop. This prominent residue may form a salt bridge with a corresponding aspartate at the relative position 8 (P8) of the antigenic peptide TT(1272-1284) as suggested from amino acid replacement analysis. A similar scenario was observed for a second TT epitope, TT(279-296), and its corresponding TCR. These examples show that immunodominance may result from a single strong amino acid interaction between TCR CDR3 beta loops here in contact with the C-terminus of the antigenic peptide. Such a dominant interaction could compensate for weaker contacts between other residues of the TCR and the antigenic peptide, and would allow the recognition of a single peptide-MHC complex by a broader synonymous TCR repertoire and could thus contribute to its immunodominance.

MHC class II-associated invariant chain peptide replacement by T cell epitopes: engineered invariant chain as a vehicle for directed and enhanced MHC class II antigen processing and presentation.

Proteolysis of the invariant chain (li) leads to the generation of abundant MHC class II-associated invariant chain peptides (CLIP), which bind in the MHC class II binding groove via supermotifs in a manner similar to that of antigenic peptides. We have engineered an li vector with the capacity to express any antigenic peptide of interest instead of CLIP, for T cell stimulation. When peripheral blood mononuclear cells (PBMC) were pulsed with li hybrids encoding T cell epitopes of tetanus toxin or acetylcholine receptor, stimulation of T cells was dramatically enhanced compared to stimulation after priming with either the native or recombinant proteins. Site-specific insertion of antigenic sequences into the CLIP region promoted enhanced antigenicity of li hybrids which were shown to be processed intracellularly in a chloroquine-sensitive compartment. Naturally processed T helper epitopes were visualized directly on the surface of PBMC and identified as analogs of CLIP associated with MHC class II molecules. This novel li vector provides a flexible and efficient system for the delivery of defined peptide epitopes to T cells which might be useful in the development of specific vaccines and in the study of intracellular processing.

Human histocompatibility leukocyte antigen (HLA)-DM edits peptides presented by HLA-DR according to their ligand binding motifs.

Human histocompatibility leukocyte antigen (HLA)-DM is a facilitator of antigen presentation via major histocompatibility complex (MHC) class II molecules. In the absence of HLA-DM, MHC class II molecules do not present natural peptides, but tend to remain associated with class II-associated invariant chain peptides (CLIP). Recently, DM was shown to catalyze the release of CLIP from HLA-DR. We have investigated which peptides bound to HLA-DR are vulnerable to release upon encountering DM. By directed substitution of allele-specific anchor residues between CLIP and DR3-cognate peptides and the application of recombinant DM we show that DM catalyzes the release of those peptides bound to HLA-DR3 that do not have appropriate anchor residues and, hence, no optimal ligand binding motif. Thus, HLA-DM acts as a peptide editor, facilitating selection of peptides that stably bind to class II molecules for eventual presentation to the immune system from the pool of available peptides.

Major histocompatibility complex class II-associated peptides determine the binding of the superantigen toxic shock syndrome toxin-1.

Superantigens bind to major histocompatibility complex (MHC) class II proteins and interact with variable parts of the T cell antigen receptor (TCR) beta-chain. Cross-linking the TCR with MHC class II molecules on the antigen-presenting cell by the superantigen leads to T cell activation that plays an essential role in pathogenesis. Recent crystallographic data have resolved the structure of the complexes between HLA-DR1 and staphylococcal enterotoxin B (SEB) and toxic shock syndrome toxin-1 (TSST-1), respectively. For TSST-1, these studies have revealed possible contact sites between the superantigen and the HLA-DR1-bound peptide. Here, we show that TSST-1 binding is dependent on the MHC-II-associated peptides by employing variants of T2 mutant cells deficient in loading of peptides to MHC class II molecules as superantigen-presenting cells. On HLA-DR3-transfected T2 cells, presentation of TSST-1, but not SEB, was dependent on HLA-DR3-associated peptides. Thus, although these superantigens can be recognized in the context of multiple MHC class II alleles and isotypes, they clearly bind to specific subsets of MHC molecules displaying appropriate peptides.

Supermotifs enable natural invariant chain-derived peptides to interact with many major histocompatibility complex-class II molecules.

Class II-associated invariant chain peptides (CLIPs) compete with natural allele-specific ligands for binding to several purified HLA-DR molecules. Truncation and substitution analysis showed that a minimal sequence of 13 amino acids is sufficient for excellent binding to DR17 and DR1. Hydrophobic residues at relative positions 1 and 9 (P1 and P9) which are shared among these DR-ligands, and are found to be anchored in complementary pockets by x-ray crystallography allow specific binding. Two flanking residues at either end next to the specific contact sites Met107 and Met115 contribute to binding irrespective of their side chains, suggesting H-bonds to the major histocompatibility complex (MHC) molecule. Thus, CLIPs behave like conventional ligands, however, lack their allele-specific contact sites. Introduction of the DR17-specific contact site aspartate at P4 dramatically improves invariant chain-peptide binding to DR17, but reduces DR1 binding. By contrast, binding to DR1, but not DR17 is strongly improved after introduction of the DR1-specific contact site alanine at P6. In addition, analyzing the fine specificity of the hydrophobic contact sites at P1 and P9, CLIP variants reflected the allele-specific preferences of DR17- or DR1-ligands, respectively, for aliphatic or aromatic residues. Alignment studies suggest that CLIPs are designed for promiscuous binding in the groove of many MHC class II molecules by taking advantage of one or more supermotifs. One such supermotif, for example, does not include the DR17-specific contact site aspartate at P4, which in conventional natural ligands like Apolipoprotein (2877-94) is necessary to confer a stable conformation. Introduction of aspartate at P4 generates a CLIP variant that is stable in the presence of sodium dodecyl sulfate, such as allele-specific ligands. Studying the stability of class II-CLIP complexes at pH 5, we found that CLIPs, similar to anchor-amputated ligands, can be released from class II molecules, in contrast to conventional natural ligands, which were irreversibly bound. Taken together, our data provide compelling evidence that CLIP peptides bind into the class II groove.

Analysis of allele-specific contact sites of natural HLA-DR17 ligands.

The sequence motif of peptide ligands naturally associated with DR17 has indicated conserved residues at the relative positions P1-P4-P6-P 8.9 or 10. Eight naturally processed DR17 ligands were synthesized to study the role of conserved residues in DR17 binding. In their majority, they showed an excellent ability to bind to purified DR17 molecules. Binding experiments with variant peptides confirmed aspartate as the DR17-specific contact site at P4. In addition, hydrophobic or aromatic residues at P1 and P9, probably interacting with the NH2- and COOH-terminal pockets, and lysine or chemically related amino acids at P6 were important for binding. A core peptide of 10 amino acids, bordered by the terminal contact sites, is sufficient, although the ability to bind is reduced approximately 10-fold compared with the binding capacity of the natural ligand. Ala substitution of flanking stretches at either end completely restores the binding capacity to that of the natural ligand. This suggests that regions flanking the peptide core contribute to the binding strength nonspecifically, i.e., by forming H-bonds to MHC molecules. Natural DR1 and DR12 ligands like HLA-A2 (103-117) and transferrin receptor (140-156) failed to bind to DR17 molecules. However, substituting leucine for aspartate at P4 transformed DR1 and DR12 ligands into excellent DR17 binders. This conversion, enabled by a single amino acid substitution, emphasizes the importance of aspartate as the DR17-specific contact site and suggests that terminal contact residues are shared among DR1, DR12, and DR17 ligands. In contrast, additional aspartates introduced next to the contact site at P4 impaired the binding capacity. Regarding this specific role of asparate we expect that DR17-specific ligands will be rarely found among "promiscuous" peptides binding to several different DR molecules.

Natural peptide ligand motifs of two HLA molecules associated with myasthenia gravis.

The peptide motifs of two HLA molecules, B8 and DR3(17), which are associated with autoimmune diseases including myasthenia gravis, were determined from natural peptide pools using Edman degradation. The majority of HLA-B8 ligands are nonamers preferentially terminated by leucine. As a characteristic feature of the HLA-B8 motif, there is a high degree of conservation of positively charged amino acids at position 3 and 5, exclusively lysine at position 3, and lysine or arginine at position 5. Additional evidence for this allele-specific motif is the presence of these features in several viral peptides recognized by HLA-B8 restricted T cells. The DR3(17) motif is characterized by four conserved anchor-like positions ordered in an almost symmetrical arrangement, as has been found for DR1 and DR5 motifs. A first hydrophobic/aromatic anchor three to four residues apart from the N-terminus (at relative position 1) appears to be a common feature of DR ligands. The second anchor is an aspartate at relative position 4, which is likely to be the DR3(17)-specific contact site in the groove. Two additional conserved positions closer to the C-terminus are occupied by charged amino acids at relative position 6 and by hydrophobic/aromatic residues at positions 8, 9, or 10. Eight individual naturally processed DR17 ligands were sequenced and were found to be derived from exogenous proteins and cytoplasmic membrane receptors. These natural peptides conform well to the determined motif. A single exchange of the anchor-like positions in a model peptide abrogated binding to DR17+ cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Thymectomy and azathioprine have no effect on the phenotype of CD4 T lymphocyte subsets in myasthenia gravis.

The influence of thymectomy and long term immunosuppression on the phenotype of CD4 T lymphocyte subsets, which were defined by the restricted expression of CD45RA and CD45RO markers, was studied by double immunofluorescence in 29 patients in different clinical stages of generalised myasthenia gravis. In the acute stage of myasthenia, before thymectomy and immunosuppression, no differences in CD4 subsets were observed in the peripheral blood from nine patients and 21 matched controls. Four to seven weeks after thymectomy, there was a slightly decreased proportion of CD4+CD45RO+ (UCHL1+) memory cells (p < 0.05, paired t test). Patients on steroids showed a more pronounced decrease of CD4+CD45RO+ cells suggesting, in addition, a drug-related effect. CD4 subsets (CD45RA, CD45RO, and CD29 positive) in the peripheral blood compartment remained largely stable over 18 to 24 months thereafter. In addition, CD4 subsets were examined in 20 patients with myasthenia gravis who had had a thymectomy between two and 17 years before. With the exception of patients on steroids, there were no differences in CD4 subsets in patients on or off azathioprine. These data did not show any relation of CD4 T cell subsets to the clinical course of myasthenia, or significant changes due to thymectomy, or immunosuppression with azathioprine. These results also complement the authors' clinical experience that thymectomy in adults does not leave a deficit in cell-mediated immunity. The slight change associated with steroid treatment might deserve further attention.

T cells from normal and myasthenic individuals recognize the human acetylcholine receptor: heterogeneity of antigenic sites on the alpha-subunit.

The alpha-subunit of the nicotinic acetylcholine receptor is the major target of the autoimmune response in myasthenia gravis. We investigated the proliferative response of T cells from patients with myasthenia gravis and healthy volunteers to recombinant polypeptides of the human acetylcholine receptor including the full-length alpha-subunit (alpha 1-437). T cells from 20 (71%) of 28 patients and 7 (37%) of 19 healthy volunteers responded in primary cultures. Subsequently, specific T-cell lines were established: CD4+, CD8-, UCHL1+, and major histocompatibility complex (MHC) class II-restricted. Using a set of fragments of the alpha-subunit, major antigenic sites could be localized on the extracellular, N-terminal part of the molecule as well as close to the C-terminus. The T-cell response was heterogeneous, both among different individuals and among T-cell lines from a single donor. These T cells did not cross-react with Torpedo acetylcholine receptor, which was previously used as a substitute for human muscle acetylcholine receptor, suggesting that the T cells had a bias for unique human sequences. A single antigenic fragment could be presented in the context of different MHC class II molecules, and different fragments could be presented in the context of the same MHC molecule. This supports earlier observations of considerable heterogeneity in dealing with acetylcholine receptor as an autoantigen on the level of both T cells and antigen-presenting cells. The data also demonstrate that acetylcholine receptor-specific T cells are present in the normal immune repertoire, and emphasize the role of immune regulation for maintaining a state of tolerance.