Two distinct ubiquitin-binding motifs in A20 mediate its anti-inflammatory and cell-protective activities

Protein ubiquitination regulates protein stability and modulates the composition of signaling complexes. A20 is a negative regulator of inflammatory signaling, but the molecular mechanisms involved are ill understood. Here, we generated Tnfaip3 gene-targeted A20 mutant mice bearing inactivating mutations in the zinc finger 7 (ZnF7) and ZnF4 ubiquitin-binding domains, revealing that binding to polyubiquitin is essential for A20 to suppress inflammatory disease. We demonstrate that a functional ZnF7 domain was required for recruiting A20 to the tumor necrosis factor receptor 1 (TNFR1) signaling complex and to suppress inflammatory signaling and cell death. The combined inactivation of ZnF4 and ZnF7 phenocopied the postnatal lethality and severe multiorgan inflammation of A20-deficient mice. Conditional tissue-specific expression of mutant A20 further revealed the key role of ubiquitin-binding in myeloid and intestinal epithelial cells. Collectively, these results demonstrate that the anti-inflammatory and cytoprotective functions of A20 are largely dependent on its ubiquitin-binding properties. van Loo and colleagues provide insights into the action of the anti-inflammatory protein A20. The ZnF7 and ZnF4 ubiquitin-binding domains of A20 are both required to suppress inflammatory signaling and cell death; however, these zinc fingers operate via distinct mechanisms

Nrf2 as a main hub in the wiring of proteostatic, mitostatic and metabolic pathways

Metazoans respond to harmful challenges by mounting anti-stress responses. This adaptation along with the evolvement of metabolic networks, were fundamental forces during evolution. Central to anti-stress responses are a number of short-lived transcription factors that by functioning as stress sensors mobilize genomic responses aiming to eliminate stressors and restore tissue homeodynamics. We have found that increased expression of nuclear factor erythroid 2-related factor (Nrf2) in Drosophila flies activated cytoprotective modules and enhanced stress tolerance. However, while mild Nrf2 activation extended lifespan, high Nrf2 expression levels resulted in larvae lethality or, after inducible activation in adult flies, in altered mitochondrial bioenergetics; the appearance of diabetic phenotypes and reduced longevity. Genetic or dietary suppression of Insulin/IGF-like signaling (IIS) alleviated these effects and extended flies’ lifespan. Our observations indicate that prolonged stress signaling by otherwise cytoprotective short-lived stress sensors re-allocates resources from growth and longevity to somatic preservation and stress tolerance. They also suggest a role for potential dietary-restriction-like therapeutic interventions in various diseases of chronic stress including progeroid genome instability syndromes and/or neurodegeneration