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Mutations that prevent caspase cleavage of RIPK1 cause autoinflammatory disease 期刊论文
NATURE, 2020, 577 (7788) : 103-+
作者:  Lalaoui, Najoua;  Boyden, Steven E.;  Oda, Hirotsugu;  Wood, Geryl M.;  Stone, Deborah L.;  Chau, Diep;  Liu, Lin;  Stoffels, Monique;  Kratina, Tobias;  Lawlor, Kate E.;  Zaal, Kristien J. M.;  Hoffmann, Patrycja M.;  Etemadi, Nima;  Shield-Artin, Kristy;  Biben, Christine;  Tsai, Wanxia Li;  Blake, Mary D.;  Kuehn, Hye Sun;  Yang, Dan;  Anderton, Holly;  Silke, Natasha;  Wachsmuth, Laurens;  Zheng, Lixin;  Moura, Natalia Sampaio;  Beck, David B.;  Gutierrez-Cruz, Gustavo;  Ombrello, Amanda K.;  Pinto-Patarroyo, Gineth P.;  Kueh, Andrew J.;  Herold, Marco J.;  Hall, Cathrine;  Wang, Hongying;  Chae, Jae Jin;  Dmitrieva, Natalia I.;  McKenzie, Mark;  Light, Amanda;  Barham, Beverly K.;  Jones, Anne;  Romeo, Tina M.;  Zhou, Qing;  Aksentijevich, Ivona;  Mullikin, James C.;  Gross, Andrew J.;  Shum, Anthony K.;  Hawkins, Edwin D.;  Masters, Seth L.;  Lenardo, Michael J.;  Boehm, Manfred;  Rosenzweig, Sergio D.;  Pasparakis, Manolis;  Voss, Anne K.;  Gadina, Massimo;  Kastner, Daniel L.;  Silke, John
收藏  |  浏览/下载:23/0  |  提交时间:2020/07/03

RIPK1 is a key regulator of innate immune signalling pathways. To ensure an optimal inflammatory response, RIPK1 is regulated post-translationally by well-characterized ubiquitylation and phosphorylation events, as well as by caspase-8-mediated cleavage1-7. The physiological relevance of this cleavage event remains unclear, although it is thought to inhibit activation of RIPK3 and necroptosis8. Here we show that the heterozygous missense mutations D324N, D324H and D324Y prevent caspase cleavage of RIPK1 in humans and result in an early-onset periodic fever syndrome and severe intermittent lymphadenopathy-a condition we term '  cleavage-resistant RIPK1-induced autoinflammatory syndrome'  . To define the mechanism for this disease, we generated a cleavage-resistant Ripk1(D325A) mutant mouse strain. Whereas Ripk1(-/-) mice died postnatally from systemic inflammation, Ripk1(D325A/D325A) mice died during embryogenesis. Embryonic lethality was completely prevented by the combined loss of Casp8 and Ripk3, but not by loss of Ripk3 or Mlkl alone. Loss of RIPK1 kinase activity also prevented Ripk1(D325A/D325A) embryonic lethality, although the mice died before weaning from multi-organ inflammation in a RIPK3-dependent manner. Consistently, Ripk1(D325A/D325A) and Ripk1(D325A/+) cells were hypersensitive to RIPK3-dependent TNF-induced apoptosis and necroptosis. Heterozygous Ripk1(D325A/+) mice were viable and grossly normal, but were hyper-responsive to inflammatory stimuli in vivo. Our results demonstrate the importance of caspase-mediated RIPK1 cleavage during embryonic development and show that caspase cleavage of RIPK1 not only inhibits necroptosis but also maintains inflammatory homeostasis throughout life.


  
A new coronavirus associated with human respiratory disease in China (vol 579, pg 265, 2020) 期刊论文
NATURE, 2020, 580 (7803) : E7-E7
作者:  Jiao, Huipeng;  Wachsmuth, Laurens;  Kumari, Snehlata;  Schwarzer, Robin;  Lin, Juan;  Eren, Remzi Onur;  Fisher, Amanda;  Lane, Rebecca;  Young, George R.;  Kassiotis, George;  Kaiser, William J.;  Pasparakis, Manolis
收藏  |  浏览/下载:29/0  |  提交时间:2020/07/03
Structural basis for catalysis and substrate specificity of human ACAT1 期刊论文
NATURE, 2020, 581 (7808) : 333-+
作者:  Jiao, Huipeng;  Wachsmuth, Laurens;  Kumari, Snehlata;  Schwarzer, Robin;  Lin, Juan;  Eren, Remzi Onur;  Fisher, Amanda;  Lane, Rebecca;  Young, George R.;  Kassiotis, George;  Kaiser, William J.;  Pasparakis, Manolis
收藏  |  浏览/下载:10/0  |  提交时间:2020/07/03

The structure of human ACAT1, which catalyses the transfer of an acyl group from acyl-coenzyme A to cholesterol to form cholesteryl ester, is resolved by cryo-electron microscopy.


As members of the membrane-bound O-acyltransferase (MBOAT) enzyme family, acyl-coenzyme A:cholesterol acyltransferases (ACATs) catalyse the transfer of an acyl group from acyl-coenzyme A to cholesterol to generate cholesteryl ester, the primary form in which cholesterol is stored in cells and transported in plasma(1). ACATs have gained attention as potential drug targets for the treatment of diseases such as atherosclerosis, Alzheimer'  s disease and cancer(2-7). Here we present the cryo-electron microscopy structure of human ACAT1 as a dimer of dimers. Each protomer consists of nine transmembrane segments, which enclose a cytosolic tunnel and a transmembrane tunnel that converge at the predicted catalytic site. Evidence from structure-guided mutational analyses suggests that acyl-coenzyme A enters the active site through the cytosolic tunnel, whereas cholesterol may enter from the side through the transmembrane tunnel. This structural and biochemical characterization helps to rationalize the preference of ACAT1 for unsaturated acyl chains, and provides insight into the catalytic mechanism of enzymes within the MBOAT family(8).