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Details on Person T lymphocytes have developed the capacity to recognize as an...

Class:Id	Summation:8850319
_displayName	T lymphocytes have developed the capacity to recognize as an...
_timestamp	2016-02-12 03:33:12
created	[InstanceEdit:8850328] Shamovsky, Veronica, 2015-12-18
literatureReference	[LiteratureReference:8850323] Anatomy of CD1-lipid antigen complexes [LiteratureReference:8850241] Assistance of microbial glycolipid antigen processing by CD1e [LiteratureReference:8850289] Isolation and characterization of a cDNA and gene coding for a fourth CD1 molecule [LiteratureReference:8850245] Lipid and small-molecule display by CD1 and MR1 [LiteratureReference:8850259] Recognition of a lipid antigen by CD1-restricted alpha beta+ T cells [LiteratureReference:8850281] Recognition of lipid antigens by T cells [LiteratureReference:8850325] Recognition of microbial and mammalian phospholipid antigens by NKT cells with diverse TCRs [LiteratureReference:8850262] Structure of the complex between human T-cell receptor, viral peptide and HLA-A2 [LiteratureReference:8850212] T cell antigen receptor recognition of antigen-presenting molecules [LiteratureReference:8850314] Two classes of CD1 genes [LiteratureReference:8848856] Molecular mechanism of lipopeptide presentation by CD1a [LiteratureReference:8850074] The 2.5 Å structure of CD1c in complex with a mycobacterial lipid reveals an open groove ideally suited for diverse antigen presentation [LiteratureReference:8850163] The crystal structure of human CD1b with a bound bacterial glycolipid [LiteratureReference:8850313] The crystal structure of human CD1d with and without alpha-galactosylceramide [LiteratureReference:8850327] Structure of human CD1b with bound ligands at 2.3 A, a maze for alkyl chains [LiteratureReference:8850246] Crystal structure of CD1a in complex with a sulfatide self antigen at a resolution of 2.15 A [LiteratureReference:8850239] CD1d-lipid-antigen recognition by the semi-invariant NKT T-cell receptor [LiteratureReference:8850144] Structural reorganization of the antigen-binding groove of human CD1b for presentation of mycobacterial sulfoglycolipids [LiteratureReference:8850256] Intracellular pathways of CD1 antigen presentation [LiteratureReference:8850293] Separate pathways for antigen presentation by CD1 molecules [LiteratureReference:8850260] Direct measurement of antigen binding properties of CD1 proteins using fluorescent lipid probes [LiteratureReference:8850250] Discovery of deoxyceramides and diacylglycerols as CD1b scaffold lipids among diverse groove-blocking lipids of the human CD1 system [LiteratureReference:8850240] The CD1 size problem: lipid antigens, ligands, and scaffolds [LiteratureReference:8850225] CD1 expression on antigen-presenting cells [LiteratureReference:8850253] Evolutionary biology of CD1 [LiteratureReference:8850307] Antigen Presentation by CD1 Lipids, T Cells, and NKT Cells in Microbial Immunity [LiteratureReference:8850261] Role of lipid trimming and CD1 groove size in cellular antigen presentation [LiteratureReference:8850275] Inflammation-associated lysophospholipids as ligands for CD1d-restricted T cells in human cancer [LiteratureReference:8850277] Activation of human T cells by CD1 and self-lipids [LiteratureReference:8850252] Presentation of the same glycolipid by different CD1 molecules [LiteratureReference:8850232] Modeling T cell receptor recognition of CD1-lipid and MR1-metabolite complexes [LiteratureReference:8850295] αβ T cell antigen receptor recognition of CD1a presenting self lipid ligands [LiteratureReference:8856368] Structure and function of a potent agonist for the semi-invariant natural killer T cell receptor [LiteratureReference:8856599] CD1d-lipid antigen recognition by the Î³Î´ TCR [LiteratureReference:8856592] gammadelta T cell surveillance via CD1 molecules [LiteratureReference:8856605] Crystal structure of VÎ´1 T cell receptor in complex with CD1d-sulfatide shows MHC-like recognition of a self-lipid by human Î³Î´ T cells [LiteratureReference:8856602] Molecular Analysis of Lipid-Reactive VÎ´1 Î³Î´ T Cells Identified by CD1c Tetramers [LiteratureReference:8856840] Invariant natural killer T cells recognize lipid self antigen induced by microbial danger signals [LiteratureReference:8856862] CD1a-autoreactive T cells recognize natural skin oils that function as headless antigens [LiteratureReference:8856859] A novel self-lipid antigen targets human T cells against CD1c(+) leukemias
modified	[InstanceEdit:8856600] Shamovsky, Veronica, 2016-02-11 [InstanceEdit:8856835] Shamovsky, Veronica, 2016-02-12 [InstanceEdit:8856838] Shamovsky, Veronica, 2016-02-12 [InstanceEdit:8856844] Shamovsky, Veronica, 2016-02-12
text	T lymphocytes have developed the capacity to recognize as antigens a large variety of molecules including peptides, lipids, and vitamin metabolites (Moody DB et al. 2005; Rossjohn J et al. 2015; de Jong A 2015). Specific recognition of lipids by T-cell receptors (TCR) occurs when these molecules form antigenic complexes using functionally nonpolymorphic CD1 molecules (Beckman EM et al. 1994; De Libero G1 & Mori L 2005; Tatituri RV et al. 2013; Van Rhijn I et al. 2015). Humans express five functional CD1 isotypes (CD1a-e), with CD1e being the only member that does not directly present antigens to T cells (Calabi F et al. 1989; Balk SP et al. 1989; de la Salle H et al. 2005). CD1a, CD1b, CD1c and CD1d are surface expressed proteins that can be found on the plasma membranes of antigen-presenting cells (APC) (Dougan SK et al. 2007). CD1 ectodomains consist of a heavy chain, which folds into three extracellular domains (alpha1, alpha2 and alpha3) noncovalently associated with beta2-microglobulin (B2M) (Moody DB et al. 2005). Antigen-binding grooves nestle between the alpha1 and alpha2 helices and are mostly lined by hydrophobic residues (Zeng Z et al. 1997). This allows the antigenic lipids to be anchored via their hydrophobic chains, so that polar motifs protrude toward the aqueous milieu (Gadola SD et al. 2002; Zajonc DM et al. 2003, 2005; Batuwangala T et al. 2004; Koch M et al. 2005; Zajonc DM et al. 2005; Scharf L et al. 2010; Garcia-Alles LF et al. 2011). Consequently, polar heads establish stimulatory contacts with TCRs, while variation in the number, length and saturation of alkyl chains may contribute to the binding to varying degrees (Borg NA et al. 2007; Garcia-Alles LF et al. 2011; Li Y et al. 2010; Pierce BG et al. 2014). Each of the four CD1 isoforms that directly present antigens to T cells differ in size of the antigen-binding grooves (Zajonc DM et al. 2005; Gadola SD et al. 2002; Zajonc DM et al. 2003, 2005; Batuwangala T et al. 2004; Koch M et al. 2005; Cheng TY et al. 2006; Borg NA et al. 2007; Scharf L et al. 2010; Garcia-Alles LF et al. 2011), intracellular trafficking patterns (Sugita M et al. 1999; Moody DB & Porcelli SA 2003), lipid ligand repertoire (Im JS et al. 2004; Huang S et al. 2011; Ly D & Moody DB 2014), and tissue distribution of expression (Dougan SK et al. 2007). Together with the observation that multiple CD1 isoforms have been maintained throughout mammalian evolution, this argues that each CD1 isoform plays a non-redundant role in the immune system (Dascher CC 2007; de Jong A 2015). A large spectrum of self- and foreign lipids associates with members of CD1 family (Mattner J et al. 2005; Kinjo Y et al. 2005; Chang DH et al. 2008; Cohen NR et al. 2009; De Libero G et al. 2009; Zajonc DM & Girardi E 2015; Birkinshaw RW et al. 2015; de Jong A 2015). CD1-bound self-derived lipid antigens, including gangliosides, sulfatide, phosphoglycerolipids and sphingomyelin, can stimulate specialized subsets of T cells though the importance of self-lipid interactions with TCRs can vary (Birkinshaw RW et al. 2015; Borg NA et al. 2007; Luoma AM et al. 2013, 2014; Lepore M et al. 2014; Roy S et al. 2016). The ability of of both alphabeta and gammadelta T cells to recognize self lipid loaded CD1 molecules enables these lymphocytes to sense changes in the lipid composition of cells and tissues as a result of infections, inflammation, or malignancies (Brennan PJ et al. 2011; Chang DH et al. 2008; Cohen NR et al. 2009; Luoma et al. 2014; Lepore M et al. 2014; de Jong A 2014, 2015). The Reactome event shows self lipid-based molecules that have been reported to function as antigens for CD1-restricted T cells (Shamshiev A et al. 2002; Birkinshaw RW et al. 2015; de Jong A 2015).
(summation)	[Reaction:8850326] TCR binds self-lipid-based antigen via CD1 [Homo sapiens]
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