Showing total 3 results

1. Update 2020: nomenclature and listing of celiac disease–relevant gluten epitopes recognized by CD4+ T cells.

Author

Sollid, Ludvig M., Tye-Din, Jason A., Qiao, Shuo-Wang, Anderson, Robert P., Gianfrani, Carmen, and Koning, Frits

Subjects

*HLA histocompatibility antigens, *EPITOPES, *GLUTEN, *GLUTELINS, *CELIAC disease, *T cells, *T cell receptors

Abstract

Celiac disease is caused by an abnormal intestinal T cell response to cereal gluten proteins. The disease has a strong human leukocyte antigen (HLA) association, and CD4+ T cells recognizing gluten epitopes presented by disease-associated HLA-DQ allotypes are considered to be drivers of the disease. This paper provides an update of the currently known HLA-DQ restricted gluten T cell epitopes with their names and sequences. [ABSTRACT FROM AUTHOR]

Published

2020

2. Two novel HLA-DQ2.5-restricted gluten T cell epitopes in the DQ2.5-glia-γ4 epitope family.

Author

Qiao, Shuo-Wang and Sollid, Ludvig M.

Subjects

*T cells, *GLUTEN, *EPITOPES, *GLUTELINS, *CELIAC disease, *CYTOTOXIC T cells, *T cell receptors

Abstract

Celiac disease is a chronic inflammatory condition of the small intestine caused by aberrant adaptive immune response to gluten protein from wheat and related cereal plants. Over 90% of celiac disease patients carry the HLA-DQ2.5 allotype and HLA-DQ2.5 presents gluten peptides to gluten-reactive CD4+ T cells in celiac disease patients. A large number of HLA-DQ2.5-restricted gluten T cell epitopes have been identified over the years. These epitopes are in general proline-rich and contain at least one glutamic acid residue that is generated from glutamine in the native gluten protein by deamidation. The deamidation is mediated by the enzyme transglutaminase 2 (TG2). It has been shown that the same T cell could recognize several different HLA-DQ2.5-restricted gluten T cell epitopes due to sequence similarities. In this paper, we demonstrate that three T cell clones derived from duodenal biopsies of different celiac disease patients are able to respond to at least five different gluten T cell epitopes within the DQ2.5-glia-γ4 epitope family, including two novel epitopes. [ABSTRACT FROM AUTHOR]

Published

2019

3. Reassignment of the murine 3′ TRDD1 recombination signal sequence.

Author

Touvrey, C., Cowell, L. G., Lieberman, A. E., Marche, P. N., Jouvin-Marche, E., and Candéias, S. M.

Subjects

*T cell receptors, *T cells, *GENES, *NUCLEOTIDES, *RECOMBINANT molecules, *DATABASES

Abstract

T cell receptor genes are assembled in developing T lymphocytes from discrete V, D, and J genes by a site-specific somatic rearrangement mechanism. A flanking recombination signal, composed of a conserved heptamer and a semiconserved nonamer separated by 12 or 23 variable nucleotides, targets the activity of the rearrangement machinery to the adjoining V, D, and J genes. Following the rearrangement of V, D, or J genes, their respective recombination signals are ligated together. Although these signal joints are allegedly invariant, created by the head-to-head abuttal of the heptamers, some do exhibit junctional diversity. Recombination signals were initially identified by comparison and alignment of germ-line sequences with the sequence of rearranged genes. However, their overall low level of sequence conservation makes their characterization solely from sequence data difficult. Recently, computational analysis unraveled correlations between nucleotides at several positions scattered within the spacer and recombination activity, so that it is now possible to identify putative recombination signals and determine and predict their recombination efficiency. In this paper, we analyzed the variability introduced in signal joints generated after rearrangement of the TRDD1 and TRDD2 genes in murine thymocytes. The recurrent presence of identical nucleotides inserted in these signal joints led us to reconsider the location and sequence of the TRDD1 recombination signal. By combining molecular characterization and computational analysis, we show that the functional TRDD1 recombination signal is shifted inside the putative coding sequence of the TRDD1 gene and, consequently, that this gene is shorter than indicated in the databases. [ABSTRACT FROM AUTHOR]

Published

2006