Garate, Jose Antonio; Stoecki, Johannes; del Carmen Fernandez-Alonso, Maria; Artner, Daniel; Haegman, Mira; Oostenbrink, Chris; Jimenez-Barbero, Jesus; Beyaert, Rudi; Heine, Holger; Kosma, Paul; Zamyatina, Alla
Anti-endotoxic activity and structural basis for human MD-2 center dot TLR4 antagonism of tetraacylated lipid A mimetics based on beta GlcN(1 <-> 1)alpha GlcN scaffold
INNATE IMMUNITY, 21:490-503, JUL 2015

Interfering with LPS binding by the co-receptor protein myeloid differentiation factor 2 (MD-2) represents a useful approach for down-regulation of MD-2.TLR4-mediated innate immune signaling, which is implicated in the pathogenesis of a variety of human diseases, including sepsis syndrome. The antagonistic activity of a series of novel synthetic tetraacylated bis-phosphorylated glycolipids based on the GlcN(11)GlcN scaffold was assessed in human monocytic macrophage-like cell line THP-1, dendritic cells and human epithelial cells. Two compounds were shown to inhibit efficiently the LPS-induced inflammatory signaling by down-regulation of the expression of TNF-, IL-6, IL-8, IL-10 and IL-12 to background levels. The binding of the tetraacylated by (R)-3-hydroxy-fatty acids (2xC(12,) 2xC(14)), 4,4-bisphosphorylated GlcN(11)GlcN-based lipid A mimetic DA193 to human MD-2 was calculated to be 20-fold stronger than that of Escherichia coli lipid A. Potent antagonistic activity was related to a specific molecular shape induced by the ,(11)-diglucosamine backbone. Co-planar' relative arrangement of the GlcN rings was inflicted by the double exo-anomeric conformation around both glycosidic torsions in the rigid ,(11) linkage, which was ascertained using NOESY NMR experiments and confirmed by molecular dynamics simulation. In contrast to the native lipid A ligands, the binding affinity of GlcN(11)GlcN-based lipid A mimetics to human MD-2 was independent on the orientation of the diglucosamine backbone of the synthetic antagonist within the binding pocket of hMD-2 (rotation by 180 degrees) allowing for two equally efficient binding modes as shown by molecular dynamics simulation.

DOI:10.1177/1753425914550426

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