BACKGROUND & AIMS: Mutations in the CARD15 gene encoding NOD2 are susceptibility factors in Crohn's disease. We explored the mechanism of this susceptibility using mice that over express NOD2. METHODS: Cellular and molecular responses of mice bearing an NOD2 transgene or administered plasmids that express wild-type and mutated NOD2 constructs were examined. RESULTS: In initial studies, we showed that splenocytes from NOD2 transgenic mice as compared with littermate controls exhibit decreased interleukin (IL)-12p70 responses to peptidoglycan (PGN), a TLR2 ligand that contains muramyl dipeptide, but not other TLR ligands; in contrast, IL-12 responses to PAM(3)CSK(4), a TLR2 ligand that does not contain muramyl dipeptide, were normal. Similarly, transgenic mice as compared with controls exhibited greatly decreased IL-12p40 responses to intraperitoneal administration of PGN but not to lipopolysaccharide. In further studies, we showed using electrophoretic mobility shift assay that PGN-stimulated cells from transgenic mice exhibited decreased activation of nuclear factor kappaB. Finally, in a series of studies on the effect of the NOD2 on susceptibility to induced colitis, we found that (1) transgenic mice were highly resistant to induction of PGN colitis and partially resistant to induction of trinitrobenzene sulfonic acid (TNBS) colitis and (2) mice administered a plasmid expressing a wild-type NOD2 gene were completely resistant to TNBS colitis whereas mice administered a plasmid expressing an NOD2 gene with the Crohn's disease frameshift mutation were only slightly resistant to TNBS colitis. CONCLUSIONS: These data offer new evidence that NOD2 mutations contribute to inflammatory bowel disease by causing excessive TLR2 cytokine responses.
BACKGROUND & AIMS: Mutations in the CARD15 gene encoding NOD2 are susceptibility factors in Crohn's disease. We explored the mechanism of this susceptibility using mice that over express NOD2. METHODS: Cellular and molecular responses of mice bearing an NOD2 transgene or administered plasmids that express wild-type and mutated NOD2 constructs were examined. RESULTS: In initial studies, we showed that splenocytes from NOD2transgenic mice as compared with littermate controls exhibit decreased interleukin (IL)-12p70 responses to peptidoglycan (PGN), a TLR2 ligand that contains muramyl dipeptide, but not other TLR ligands; in contrast, IL-12 responses to PAM(3)CSK(4), a TLR2 ligand that does not contain muramyl dipeptide, were normal. Similarly, transgenic mice as compared with controls exhibited greatly decreased IL-12p40 responses to intraperitoneal administration of PGN but not to lipopolysaccharide. In further studies, we showed using electrophoretic mobility shift assay that PGN-stimulated cells from transgenic mice exhibited decreased activation of nuclear factor kappaB. Finally, in a series of studies on the effect of the NOD2 on susceptibility to induced colitis, we found that (1) transgenic mice were highly resistant to induction of PGN colitis and partially resistant to induction of trinitrobenzene sulfonic acid (TNBS) colitis and (2) mice administered a plasmid expressing a wild-type NOD2 gene were completely resistant to TNBS colitis whereas mice administered a plasmid expressing an NOD2 gene with the Crohn's disease frameshift mutation were only slightly resistant to TNBS colitis. CONCLUSIONS: These data offer new evidence that NOD2 mutations contribute to inflammatory bowel disease by causing excessive TLR2 cytokine responses.
Authors: Jan Wehkamp; Nita H Salzman; Edith Porter; Sabine Nuding; Michael Weichenthal; Robert E Petras; Bo Shen; Elke Schaeffeler; Matthias Schwab; Rose Linzmeier; Ryan W Feathers; Hiutung Chu; Heriberto Lima; Klaus Fellermann; Tomas Ganz; Eduard F Stange; Charles L Bevins Journal: Proc Natl Acad Sci U S A Date: 2005-12-05 Impact factor: 11.205
Authors: A Uehara; S Yang; Y Fujimoto; K Fukase; S Kusumoto; K Shibata; S Sugawara; H Takada Journal: Cell Microbiol Date: 2005-01 Impact factor: 3.715
Authors: David A van Heel; Subrata Ghosh; Matt Butler; Karen A Hunt; Anna M C Lundberg; Tariq Ahmad; Dermot P B McGovern; Clive Onnie; Kenichi Negoro; Sue Goldthorpe; Brian M J Foxwell; Christopher G Mathew; Alastair Forbes; Derek P Jewell; Raymond J Playford Journal: Lancet Date: 2005 May 21-27 Impact factor: 79.321
Authors: Mihai G Netea; Gerben Ferwerda; Dirk J de Jong; Trees Jansen; Liesbeth Jacobs; Matthijs Kramer; Ton H J Naber; Joost P H Drenth; Stephen E Girardin; Bart Jan Kullberg; Gosse J Adema; Jos W M Van der Meer Journal: J Immunol Date: 2005-05-15 Impact factor: 5.422
Authors: William Richard Berrington; Murdo Macdonald; Saraswoti Khadge; Bishwa Raj Sapkota; Marta Janer; Deanna Alisa Hagge; Gilla Kaplan; Thomas Richard Hawn Journal: J Infect Dis Date: 2010-05-01 Impact factor: 5.226
Authors: Holly L Rosenzweig; Kellen Galster; Emily E Vance; Joe Ensign-Lewis; Gabriel Nunez; Michael P Davey; James T Rosenbaum Journal: Invest Ophthalmol Vis Sci Date: 2011-06-09 Impact factor: 4.799
Authors: X Han; X Ren; I Jurickova; K Groschwitz; B A Pasternak; H Xu; T A Wilson; S P Hogan; L A Denson Journal: Gut Date: 2008-08-07 Impact factor: 23.059
Authors: Hitesh S Deshmukh; James B Hamburger; Sun Hee Ahn; Dewey G McCafferty; Suxiao R Yang; Vance G Fowler Journal: Infect Immun Date: 2009-01-12 Impact factor: 3.441
Authors: Olaf Penack; Odette M Smith; Amy Cunningham-Bussel; Xin Liu; Uttam Rao; Nury Yim; Il-Kang Na; Amanda M Holland; Arnab Ghosh; Sydney X Lu; Robert R Jenq; Chen Liu; George F Murphy; Katharina Brandl; Marcel R M van den Brink Journal: J Exp Med Date: 2009-09-08 Impact factor: 14.307