BACKGROUND: Giant cell arteritis is a granulomatous vasculitis of the aorta and its branches that causes blindness, stroke, and aortic aneurysm. CD4 T cells are key pathogenic regulators, instructed by vessel wall dendritic cells to differentiate into vasculitic T cells. The unique pathways driving this dendritic cell-T-cell interaction are incompletely understood, but may provide novel therapeutic targets for a disease in which the only established therapy is long-term treatment with high doses of corticosteroids. METHODS AND RESULTS: Immunohistochemical and gene expression analyses of giant cell arteritis-affected temporal arteries revealed abundant expression of the NOTCH receptor and its ligands, Jagged1 and Delta1. Cleavage of the NOTCH intracellular domain in wall-infiltrating T cells indicated ongoing NOTCH pathway activation in large-vessel vasculitis. NOTCH activation did not occur in small-vessel vasculitis affecting branches of the vasa vasorum tree. We devised 2 strategies to block NOTCH pathway activation: γ-secretase inhibitor treatment, preventing nuclear translocation of the NOTCH intracellular domain, and competing for receptor-ligand interactions through excess soluble ligand, Jagged1-Fc. In a humanized mouse model, NOTCH pathway disruption had strong immunosuppressive effects, inhibiting T-cell activation in the early and established phases of vascular inflammation. NOTCH inhibition was particularly effective in downregulating Th17 responses, but also markedly suppressed Th1 responses. CONCLUSIONS: Blocking NOTCH signaling depleted T cells from the vascular infiltrates, implicating NOTCH- NOTCH ligand interactions in regulating T-cell retention and survival in vessel wall inflammation. Modulating the NOTCH signaling cascade emerges as a promising new strategy for immunosuppressive therapy of large-vessel vasculitis.
BACKGROUND:Giant cell arteritis is a granulomatous vasculitis of the aorta and its branches that causes blindness, stroke, and aortic aneurysm. CD4 T cells are key pathogenic regulators, instructed by vessel wall dendritic cells to differentiate into vasculitic T cells. The unique pathways driving this dendritic cell-T-cell interaction are incompletely understood, but may provide novel therapeutic targets for a disease in which the only established therapy is long-term treatment with high doses of corticosteroids. METHODS AND RESULTS: Immunohistochemical and gene expression analyses of giant cell arteritis-affected temporal arteries revealed abundant expression of the NOTCH receptor and its ligands, Jagged1 and Delta1. Cleavage of the NOTCH intracellular domain in wall-infiltrating T cells indicated ongoing NOTCH pathway activation in large-vessel vasculitis. NOTCH activation did not occur in small-vessel vasculitis affecting branches of the vasa vasorum tree. We devised 2 strategies to block NOTCH pathway activation: γ-secretase inhibitor treatment, preventing nuclear translocation of the NOTCH intracellular domain, and competing for receptor-ligand interactions through excess soluble ligand, Jagged1-Fc. In a humanized mouse model, NOTCH pathway disruption had strong immunosuppressive effects, inhibiting T-cell activation in the early and established phases of vascular inflammation. NOTCH inhibition was particularly effective in downregulating Th17 responses, but also markedly suppressed Th1 responses. CONCLUSIONS: Blocking NOTCH signaling depleted T cells from the vascular infiltrates, implicating NOTCH- NOTCH ligand interactions in regulating T-cell retention and survival in vessel wall inflammation. Modulating the NOTCH signaling cascade emerges as a promising new strategy for immunosuppressive therapy of large-vessel vasculitis.
Authors: B De Strooper; W Annaert; P Cupers; P Saftig; K Craessaerts; J S Mumm; E H Schroeter; V Schrijvers; M S Wolfe; W J Ray; A Goate; R Kopan Journal: Nature Date: 1999-04-08 Impact factor: 49.962
Authors: Elisa Boscolo; Camille L Stewart; Shoshana Greenberger; June K Wu; Jennifer T Durham; Ira M Herman; John B Mulliken; Jan Kitajewski; Joyce Bischoff Journal: Arterioscler Thromb Vasc Biol Date: 2011-07-14 Impact factor: 8.311
Authors: Gulbu Uzel; Elizabeth P Sampaio; Monica G Lawrence; Amy P Hsu; Mary Hackett; Morna J Dorsey; Richard J Noel; James W Verbsky; Alexandra F Freeman; Erin Janssen; Francisco A Bonilla; Joseph Pechacek; Prabha Chandrasekaran; Sarah K Browne; Anahita Agharahimi; Ahmed M Gharib; Sara C Mannurita; Jae Joon Yim; Eleonora Gambineri; Troy Torgerson; Dat Q Tran; Joshua D Milner; Steven M Holland Journal: J Allergy Clin Immunol Date: 2013-03-25 Impact factor: 10.793