100,736 research outputs found
Tumor necrosis factor receptor-associated periodic syndrome as a model linking autophagy and inflammation in protein aggregation diseases
Autophagy prevents cellular damage by eliminating insoluble aggregates of mutant misfolded proteins, which accumulate under different pathological conditions. Downregulation of autophagy enhances the inflammatory response and thus represents a possible common pathogenic event underlying a number of autoinflammatory syndromes, such as tumor necrosis factor (TNF) receptor-associated periodic syndrome (TRAPS). The pathogenesis of other monogenic or complex disorders that display symptoms of excessive inflammation also involve the autophagy pathway. Studies have shown that TRAPS-associated TNFRSF1A mutations induce cytoplasmic retention of the TNFR1 receptor, defective TNF-induced apoptosis, and production of reactive oxygen species (ROS). Furthermore, autophagy impairment may account for the pathogenic effects of TNFRSF1A mutations, thus inducing inflammation in TRAPS. In this review, we summarize the molecular interactions and functional links between autophagy with regard to nuclear factor-kappa B activation, ROS production, and apoptosis. Furthermore, we propose a complex interplay of these pathways as a model to explain the relationship between mutant protein misfolding and inflammation in genetically determined and aggregation-prone diseases. Accordingly, autophagy function should be investigated in all diseases showing an inflammatory component, and for which the molecular pathogenesis is still unclear. © 2014 Springer-Verlag Berlin Heidelberg
Temporal changes in co-morbidities and mortality in patients hospitalized for COVID-19 in Italy
Causative and common PHOX2B variants define a broad phenotypic spectrum
Paired Like homeobox 2B (PHOX2B) is a gene crucial for the differentiation of the neural lineages of the autonomic nervous system (ANS), whose coding mutations cause congenital central hypoventilation syndrome (CCHS). The vast majority of PHOX2B mutations in CCHS is represented by expansions of a polyalanine region in exon 3, collectively defined PARMs (PolyAlanine Repeat Mutations), the minority being frameshift, missense and nonsense mutations, defined as NPARMs (Non‐PARMs). While PARMs are nearly exclusively associated with isolated CCHS, most of NPARMs is detected in syndromic CCHS, presenting with neuroblastoma and/or Hirschsprung disease. More recently, evidence of a complex role of PHOX2B in the pathogenesis of a wider spectrum of ANS disorders has emerged. Indeed, common and hypomorphic PHOX2B variants, including synonymous, polyalanine‐contractions, gene deletions may influence the occurrence of either apparent life‐threatening event (ALTE), Sudden Infant Death Syndrome (SIDS), neuroblastoma, or isolated HSCR, likely through small effects on PHOX2B expression levels. After an introduction to the role of PHOX2B in the ANS development, causative mutations, common variants, and gene expression deregulation of the PHOX2B gene are discussed, though the involvement of synonymous variants and contractions requires further confirmations with respect to ANS disorders and molecular mechanisms underlying the PHOX2B phenotypic heterogeneity
Correspondence regarding: Alexander disease mutant glial fibrillary acidic protein compromises glutamate transport in astrocytes
Tumor necrosis factor in congestive heart failure: a mechanism of disease for the new millennium?
Tumor necrosis factor alpha (TNF-alpha), a protein belonging to the family of cytokines, is one of the leading mediators of the immune response to inflammation. Its widespread biological effects are modulated by two circulating binding proteins corresponding to the extracellular domain of the membrane receptors, namely soluble TNF receptors. TNF-alpha was first supposed to be linked with congestive heart failure (CHF) on a cachexia-inducing basis. In patients with advanced CHF, elevated levels of circulating TNF-alpha and soluble TNF receptors have been found. The pathophysiological implications of activation of the TNF system in CHF seem to rely mainly on its effects on the heart and the endothelium. TNF-alpha exerts a negative inotropic effect both directly and indirectly, this latter being mediated by enhancement of nitric oxide production. Moreover, TNF-alpha has been suggested to trigger the apoptotic process in cardiac myocytes. There is consensus on the detrimental role played by TNF-alpha in CHF further supported by the evidence of a temporal association between TNF activation and transition from asymptomatic to symptomatic CHF
Tumor necrosis factor in congestive heart failure: A mechanism of disease for the new millennium?
High-dose heparin impairs nitric oxide pathway and vasomotion in rats.
BACKGROUND: Platelet-activating effects have been reported with high-dose heparin in acute thrombotic disorders. Recent studies have shown that increased platelet aggregation is due to reduced nitric oxide (NO) production in endothelial cells cultured in the presence of high-dose heparin. The aim of this study was to determine whether heparin can affect the NO pathway and the regulation of the vascular tone in vivo. METHODS AND RESULTS: Anesthetized and mechanically ventilated Sprague-Dawley rats were treated with high-dose heparin. After 4 hours, the endothelial constitutive NO synthase (ecNOS) protein content in the aorta decreased (36\% reduction, P<0.05), as detected by immunoblotting, and NO-dependent vascular reactivity was impaired. In fact, the increase in mean arterial blood pressure after inhibition of ecNOS with NG-nitro-L-arginine methyl ester (30 mg/kg) was smaller in heparin-treated animals than in controls (+26. 9+/-4.8 versus +48.3+/-9.1 mm Hg, P<0.05), and further infusion of the biological ecNOS substrate L-arginine (0.5 g/kg) was ineffective in reversing systemic vasoconstriction (-1\% versus 28\% vasodilatation, P<0.001). CONCLUSIONS: High-dose heparin can significantly affect vascular reactivity in vivo by downregulation of ecNOS protein expression
Bradykinin and coronary artery disease
Although the benefits of angiotensin-converting enzyme (ACE) inhibitors in limiting the progression of a variety of cardiovascular diseases are well known, their mechanisms of action have not been completely discovered. A reduction in the synthesis of the potent vasoconstricting agent angiotensin II has for a long time been considered to be the leading mechanism to account for the effects of ACE inhibitors. However, another action of these relatively old drugs is emerging: the increased availability of bradykinin. This kinin, which is broken down by ACE, has potent cardioprotective, antithrombotic antitrophic and vasodilator effects occurring through the stimulation of specific receptors on several cells. The recent development of a specific bradykinin-receptor blocking agent, icatibant, has allowed better understanding of the therapeutic properties of ACE inhibitors mediated by bradykinin both in experimental and clinical studies
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