Hanne Quarsten scite author profile

The action of tissue Transglutaminase (TGase) on specific protein-bound glutamine residues plays a critical role in numerous biological processes. Here we provide evidence for a new role of this enzyme in the common, HLA-DQ2 (and DQ8) associated enteropathy, celiac disease (CD). The intestinal inflammation in CD is precipitated by exposure to wheat gliadin in the diet and is associated with increased mucosal activity of TGase. This enzyme has also been identified as the main target for CD-associated anti-endomysium autoantibodies, and is known to accept gliadin as one of its few substrates. We have examined the possibility that TGase could be involved in modulating the reactivity of gliadin specific T cells. This could establish a link between previous reports of the role of TGase in CD and the prevailing view of CD as a T-cell mediated disorder. We found a specific effect of TGase on T-cell recognition of gliadin. This effect was limited to gliadin-specific T cells isolated from intestinal CD lesions. We demonstrate that TGase mediates its effect through an ordered and specific deamidation of gliadins. This deamidation creates an epitope that binds efficiently to DQ2 and is recognized by gut-derived T cells. Generation of epitopes by enzymatic modification is a new mechanism that may be relevant for breaking of tolerance and initiation of autoimmune disease.

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The Intestinal T Cell Response to α-Gliadin in Adult Celiac Disease Is Focused on a Single Deamidated Glutamine Targeted by Tissue Transglutaminase

Arentz‐Hansen

Körner²,

Molberg

et al. 2000

610

485

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The great majority of patients that are intolerant of wheat gluten protein due to celiac disease (CD) are human histocompatibility leukocyte antigen (HLA)-DQ2+, and the remaining few normally express HLA-DQ8. These two class II molecules are chiefly responsible for the presentation of gluten peptides to the gluten-specific T cells that are found only in the gut of CD patients but not of controls. Interestingly, tissue transglutaminase (tTG)-mediated deamidation of gliadin plays an important role in recognition of this food antigen by intestinal T cells. Here we have used recombinant antigens to demonstrate that the intestinal T cell response to α-gliadin in adult CD is focused on two immunodominant, DQ2-restricted peptides that overlap by a seven-residue fragment of gliadin. We show that tTG converts a glutamine residue within this fragment into glutamic acid and that this process is critical for T cell recognition. Gluten-specific T cell lines from 16 different adult patients all responded to one or both of these deamidated peptides, indicating that these epitopes are highly relevant to disease pathology. Binding studies showed that the deamidated peptides displayed an increased affinity for DQ2, a molecule known to preferentially bind peptides containing negatively charged residues. Interestingly, the modified glutamine is accommodated in different pockets of DQ2 for the different epitopes. These results suggest modifications of anchor residues that lead to an improved affinity for major histocompatibility complex (MHC), and altered conformation of the peptide–MHC complex may be a critical factor leading to T cell responses to gliadin and the oral intolerance of gluten found in CD.

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Structural basis for HLA-DQ2-mediated presentation of gluten epitopes in celiac disease

Kim

Quarsten²,

Bergseng³

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

378

324

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Celiac disease, also known as celiac sprue, is a gluten-induced autoimmune-like disorder of the small intestine, which is strongly associated with HLA-DQ2. The structure of DQ2 complexed with an immunogenic epitope from gluten, QLQPFPQPELPY, has been determined to 2.2-Å resolution by x-ray crystallography. The glutamate at P6, which is formed by tissue transglutaminase-catalyzed deamidation, is an important anchor residue as it participates in an extensive hydrogen-bonding network involving Lys-␤71 of DQ2. The gluten peptide-DQ2 complex retains critical hydrogen bonds between the MHC and the peptide backbone despite the presence of many proline residues in the peptide that are unable to participate in amide-mediated hydrogen bonds. Positioning of proline residues such that they do not interfere with backbone hydrogen bonding results in a reduction in the number of registers available for gluten peptides to bind to MHC class II molecules and presumably impairs the likelihood of establishing favorable side-chain interactions. The HLA association in celiac disease can be explained by a superior ability of DQ2 to bind the biased repertoire of proline-rich gluten peptides that have survived gastrointestinal digestion and that have been deamidated by tissue transglutaminase. Finally, surface-exposed proline residues in the proteolytically resistant ligand were replaced with functionalized analogs, thereby providing a starting point for the design of orally active agents for blocking gluten-induced toxicity.

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Tetramer visualization of gut-homing gluten-specific T cells in the peripheral blood of celiac disease patients

Ráki

Fallang

Brottveit

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

141

166

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Tetramers of MHC-peptide complexes are used for detection and characterization of antigen-specific T cell responses, but they require knowledge about both antigenic peptide and the MHC restriction element. The successful application of these reagents in human diseases involving CD4 ؉ T cells is limited. Celiac disease, an intestinal inflammation driven by mucosal CD4 ؉ T cells recognizing wheat gluten peptides in the context of disease-associated HLA-DQ molecules, is an ideal model to test the potential clinical use of these reagents. We investigated whether gluten-specific T cells can be detected in the peripheral blood of celiac disease patients using DQ2 tetramers. Nine DQ2 ؉ patients and six control individuals on a gluten-free diet were recruited to the study. Participants consumed 160 g of gluten-containing bread daily for 3 days. After bread-challenge, gluten-specific T cells were detectable in the peripheral blood of celiac patients but not controls both directly by tetramer staining and indirectly by enzyme-linked immunospot. These T cells expressed the ␤7 integrin indicative of gut-homing properties. Most of the cells had a memory phenotype, but many other phenotypic markers showed a heterogeneous pattern. Tetramer staining of gluten-specific T cells has the potential to be used for diagnosis of celiac disease. tetramers T he development of multimeric MHC-peptide complexes has revolutionized the analysis of antigen-specific T cell responses. Tetramers are such reagents consisting of four soluble recombinant MHC molecules, each loaded with a single peptide and bound to a streptavidin molecule that is coupled with a fluorogenic marker (1). Multivalent engagement of the MHCpeptide complexes leads to a stable binding of the tetramer to T cell receptors on the T cell surface, allowing direct visualization of T cells with a defined specificity.MHC class I tetramer technology has greatly facilitated our understanding of CD8 ϩ T cell responses in viral infections and cancer (2). The benefit of tetramers for characterization and diagnosis of human autoimmune and infectious diseases has, however, been modest (3-6). This particularly relates to MHC class II tetramers used for the characterization of antigen-specific CD4 ϩ T cells. Only a few studies of relevance to autoimmunity exist (7-9). MHC class II tetramers are more difficult to produce than MCH class I tetramers (10, 11), and CD4 ϩ T cells of a given specificity appear to be present at much lower frequencies than their CD8 ϩ counterparts (12, 13). Several criteria have to be met to be able to detect antigen-reactive T cells with MHC II tetramers: both the peptide epitope and HLA-restriction element have to be identified, and sufficient frequency and relative high avidity of reactive T cells are needed (14).Celiac disease, a chronic inf lammatory disorder of the small intestine precipitated by ingestion of cereal gluten proteins, presents as an ideal model to test the potential clinical use of MHC class II tetramers. The disorder is driven by intestinal glu...

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Hanne Quarsten

Tissue transglutaminase selectively modifies gliadin peptides that are recognized by gut-derived T cells in celiac disease

The Intestinal T Cell Response to α-Gliadin in Adult Celiac Disease Is Focused on a Single Deamidated Glutamine Targeted by Tissue Transglutaminase

Structural basis for HLA-DQ2-mediated presentation of gluten epitopes in celiac disease

Tetramer visualization of gut-homing gluten-specific T cells in the peripheral blood of celiac disease patients

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