Non-alcoholic fatty liver disease (NAFLD) is the hepatic manifestation of metabolic syndrome and the leading cause of chronic liver disease in the Western world. Twenty percent of NAFLD individuals develop chronic hepatic inflammation (non-alcoholic steatohepatitis, NASH) associated with cirrhosis, portal hypertension and hepatocellular carcinoma, yet causes of progression from NAFLD to NASH remain obscure. Here, we show that the NLRP6 and NLRP3 inflammasomes and the effector protein IL-18 negatively regulate NAFLD/NASH progression, as well as multiple aspects of metabolic syndrome via modulation of the gut microbiota. Different animal models reveal that inflammasome deficiency-associated changes in the configuration of the gut microbiota are associated with exacerbated hepatic steatosis and inflammation through influx of TLR4 and TLR9 agonists into the portal circulation, leading to enhanced hepatic TNF-α expression that drives NASH progression. Furthermore, co-housing of inflammasome-deficient animals to wild type mice results in exacerbation of hepatic steatosis, glucose intolerance, and obesity. Thus, altered interactions between the gut microbiota and the host, produced by defective NLRP3 and NLRP6 inflammasome sensing, may govern the rate of progression of multiple metabolic syndrome-associated abnormalities, highlighting the central role of the microbiota in the pathogenesis of heretofore seemingly unrelated systemic auto-inflammatory and metabolic disorders.
Familial cold autoinflammatory syndrome (FCAS, MIM 120100), commonly known as familial cold urticaria (FCU), is an autosomal-dominant systemic inflammatory disease characterized by intermittent episodes of rash, arthralgia, fever and conjunctivitis after generalized exposure to cold [1][2][3][4] . FCAS was previously mapped to a 10-cM region on chromosome 1q44 (refs. 5,6). Muckle-Wells syndrome (MWS; MIM 191900), which also maps to chromosome 1q44, is an autosomal-dominant periodic fever syndrome with a similar phenotype except that symptoms are not precipitated by cold exposure and that sensorineural hearing loss is frequently also present [6][7][8] . To identify the genes for FCAS and MWS, we screened exons in the 1q44 region for mutations by direct sequencing of genomic DNA from affected individuals and controls. This resulted in the identification of four distinct mutations in a gene that segregated with the disorder in three families with FCAS and one family with MWS. This gene, called CIAS1, is expressed in peripheral blood leukocytes and encodes a protein with a pyrin domain 9-11 , a nucleotide-binding site (NBS, NACHT subfamily 12 ) domain and a leucine-rich repeat (LRR) motif region 13 , suggesting a role in the regulation of inflammation and apoptosis.We previously identified a locus for FCAS on chromosome 1q44 between markers D1S423 and D1S2682 (ref. 5). We developed a physical contig of bacterial artificial chromosomes (BACs) and P1-derived artificial chromosomes and narrowed the critical region to less than 1 Mb using haplotype analysis (data not shown). We used ESTs mapping to this region and The four-generation family with FCAS (family 1; Fig. 1) has an apparent de novo mutation that first appeared in subject 4 on a chromosome inherited from her mother. Only the affected members of subsequent generations of the family (subjects 5, 9 and 11) inherited this chromosome. We found a missense mutation in subject 4 that segregated with the disease haplotype in subsequent generations (subjects 5, 9 and 11). This mutation was not present in either of her parents (subjects 1 and 2), even though the unaffected mother (subject 2) possessed the haplotype that segregates with disease in this family.The other two families with FCAS (families 2 and 3) also had different missense mutations in the same exon; these were present in all affected family members (Fig. 2). In the one family studied with affected members with a diagnosis of MWS (family 4), both affected individuals had sensorineural hearing loss (Fig. 2). This family also had a missense mutation in the same exon as the families with FCAS. As in family 1, the phenotype of family 4 resulted from a de novo mutation. The unaffected mother (DNA was not available from the father) in family 4 possessed the haplotype that segregates with the disease in subsequent generations (data not shown), but she did not have the mutation that was found in all of the affected family members. These missense mutations were not found in any unaffected individuals in thes...
Summary NF-κB, a key activator of inflammation primes the NLRP3-inflammasome for activation by inducing pro-IL-1β and NLRP3 expression. NF-κB, however, also prevents excessive inflammation and restrains NLRP3-inflammasome activation through a poorly defined mechanism. We now show that NF-κB exerts its anti-inflammatory activity by inducing delayed accumulation of the autophagy receptor p62/SQSTM1. External NLRP3-activating stimuli trigger a form of mitochondrial (mt) damage that is caspase-1- and NLRP3-independent and causes release of direct NLRP3-inflammasome activators, including mtDNA and mtROS. Damaged mitochondria undergo Parkin-dependent ubiquitin conjugation and are specifically recognized by p62, which induces their mitophagic clearance. Macrophage-specific p62 ablation causes pronounced accumulation of damaged mitochondria and excessive IL-1β-dependent inflammation, enhancing macrophage death. Therefore, the “NF-κB-p62-mitophagy” pathway is a macrophage-intrinsic regulatory loop through which NF-κB restrains its own inflammation-promoting activity and orchestrates a self-limiting host response that maintains homeostasis and favors tissue repair.
Muscle cells respond to mechanical stretch stimuli by triggering downstream signals for myocyte growth and survival. The molecular components of the muscle stretch sensor are unknown, and their role in muscle disease is unclear. Here, we present biophysical/biochemical studies in muscle LIM protein (MLP) deficient cardiac muscle that support a selective role for this Z disc protein in mechanical stretch sensing. MLP interacts with and colocalizes with telethonin (T-cap), a titin interacting protein. Further, a human MLP mutation (W4R) associated with dilated cardiomyopathy (DCM) results in a marked defect in T-cap interaction/localization. We propose that a Z disc MLP/T-cap complex is a key component of the in vivo cardiomyocyte stretch sensor machinery, and that defects in the complex can lead to human DCM and associated heart failure.
Inflammasome activation has been recently recognized to play a central role in the development of drug-induced and obesity-associated liver disease. However, the sources and mechanisms of inflammasome mediated liver damage remain poorly understood. Our aim was to investigate the effect of NLRP3 inflammasome activation on the liver using novel mouse models. We generated global and myeloid cell specific conditional mutant Nlrp3 knock-in mice expressing the D301N Nlrp3 mutation (ortholog of D303N in human NLRP3) resulting in a constitutively activated NLRP3. To study the presence and significance of NLRP3 initiated pyroptotic cell death, we separated hepatocytes from non-parenchymal cells and developed a novel flow cytometry-based (FACS) strategy to detect and quantify pyroptosis in vivo based on detection of active caspase1 and propidium iodide (PI) positive cells. Liver inflammation was quantified histologically, by FACS and via gene expression analysis. Liver fibrosis was assessed by Sirius-Red-staining and qPCR for markers of hepatic stellate cell-(HSC)-activation. NLRP3 activation resulted in shortened survival, poor growth, and severe liver inflammation; characterized by neutrophilic infiltration and HSC-activation with collagen deposition in the liver. These changes were partially attenuated by treatment with anakinra, an interleukin-1 receptor antagonist. Notably, hepatocytes from global Nlrp3 mutant mice showed marked hepatocyte pyroptotic cell death with more than a fivefold increase in active caspase1-PI double positive cells. Myeloid cell restricted mutant NLRP3 activation resulted in a less severe liver phenotype in the absence of detectable pyroptotic hepatocyte cell death. Conclusions Our data demonstrates that global and to a lesser extent myeloid-specific NLRP3 inflammasome activation results in severe liver inflammation and fibrosis, while identifying hepatocyte pyroptotic cell death as a novel mechanism of NLRP3 mediated liver damage.
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