Interferon (IFN)-induced immunoproteasomes (i-proteasomes) have been associated with improved processing of major histocompatibility complex (MHC) class I antigens. Here, we show that i-proteasomes function to protect cell viability under conditions of IFN-induced oxidative stress. IFNs trigger the production of reactive oxygen species, which induce protein oxidation and the formation of nascent, oxidant-damaged proteins. We find that the ubiquitylation machinery is concomitantly upregulated in response to IFNs, functioning to target defective ribosomal products (DRiPs) for degradation by i-proteasomes. i-proteasome-deficiency in cells and in murine inflammation models results in the formation of aggresome-like induced structures and increased sensitivity to apoptosis. Efficient clearance of these aggregates by the enhanced proteolytic activity of the i-proteasome is important for the preservation of cell viability upon IFN-induced oxidative stress. Our findings suggest that rather than having a specific role in the production of class I antigens, i-proteasomes increase the peptide supply for antigen presentation as part of a more general role in the maintenance of protein homeostasis.
Coordinated regulation of the ubiquitin-proteasome system (UPS) is crucial for the cell to adjust its protein degradation capacity to changing proteolytic requirements. We have shown previously that mammalian cells upregulate proteasome gene expression in response to proteasome inhibition. Here, we report the identification of the transcription factor TCF11 (long isoform of Nrf1) as a key regulator for 26S proteasome formation in human cells to compensate for reduced proteolytic activity. Under noninducing conditions, TCF11 resides in the endoplasmic reticulum (ER) membrane. There, TCF11 is targeted to ER-associated protein degradation requiring the E3 ubiquitin ligase HRD1 and the AAA ATPase p97. Proteasome inhibitors trigger the accumulation of oxidant-damaged proteins and promote the nuclear translocation of TCF11 from the ER, permitting activation of proteasome gene expression by binding to antioxidant response elements in their promoter regions. Thus, we uncovered the transcriptional control loop regulating human proteasome-dependent protein degradation to counteract proteotoxic stress caused by proteasome inhibition.
Disturbed mitochondrial fusion and fission have been linked to various neurodegenerative disorders. In siblings from two unrelated families who died soon after birth with a profound neurodevelopmental disorder characterized by pontocerebellar hypoplasia and apnoea, we discovered a missense mutation and an exonic deletion in the SLC25A46 gene encoding a mitochondrial protein recently implicated in optic atrophy spectrum disorder. We performed functional studies that confirmed the mitochondrial localization and pro-fission properties of SLC25A46. Knockdown of slc24a46 expression in zebrafish embryos caused brain malformation, spinal motor neuron loss, and poor motility. At the cellular level, we observed abnormally elongated mitochondria, which was rescued by co-injection of the wild-type but not the mutant slc25a46 mRNA. Conversely, overexpression of the wild-type protein led to mitochondrial fragmentation and disruption of the mitochondrial network. In contrast to mutations causing non-lethal optic atrophy, missense mutations causing lethal congenital pontocerebellar hypoplasia markedly destabilize the protein. Indeed, the clinical severity appears inversely correlated with the relative stability of the mutant protein. This genotype-phenotype correlation underscores the importance of SLC25A46 and fine tuning of mitochondrial fission and fusion in pontocerebellar hypoplasia and central neurodevelopment in addition to optic and peripheral neuropathy across the life span.
The quality control of proteins mediated by the plasticity of the proteasome system is regulated by the timely and flexible formation of this multisubunit proteolytic enzyme complex. Adaptable biogenesis of the 20S proteasome core complex is therefore of vital importance for adjusting to changing proteolytic requirements. However, the molecular mechanism and the cellular sites of mammalian proteasome formation are still unresolved. By using precursor complex-specific antibodies, we now show that the main steps in 20S core complex formation take place at the endoplasmic reticulum (ER). Thereby, the proteasome maturation protein (POMP)-an essential factor of mammalian proteasome biogenesis-interacts with ER membranes, binds to a 1-7 rings, recruits b-subunits stepwise and mediates the association of mammalian precursor complexes with the ER. Thus, POMP facilitates the main steps in 20S core complex formation at the ER to coordinate the assembly process and to provide cells with freshly formed proteasomes at their site of function.
SCL25A46 is a mitochondrial carrier protein that localizes to the outer membrane. Mutation L341P causes rapid degradation of SLC25A46 by the ubiquitin-proteasome system, independent of activated stress pathways, including mitophagy and apoptosis. SLC25A46 regulates oligomerization of MFN1/2 and mitochondrial dynamics.
Significance
The lethal disorder, primary hyperoxaluria 1 (PH1), is caused by mutations in peroxisomal-localized alanine:glyoxylate aminotransferase (AGT). AGT contains a C-terminal peroxisomal targeting sequence, but mutations generate a strong N-terminal mitochondrial targeting sequence that directs AGT to mitochondria. Although mutant AGT is functional, the enzyme must be in the peroxisome to detoxify glyoxylate and prevent oxalate accumulation. We have identified a Food and Drug Administration-approved drug, dequalinium chloride (DECA), from a chemical genetic screen to identify probes that attenuate mitochondrial protein import. DECA treatment restores trafficking of mutant AGT from mitochondria to peroxisomes with a subsequent reduction in oxalate levels. Thus, repurposing DECA has potential in therapeutic strategies for PH1 because current clinical trials have not produced an effective treatment, short of organ transplant.
Steffen and Koehler preview work from the Chakrabarti et al. presenting new ways in which actin polymerization at the endoplasmic reticulum influences mitochondrial division.
Tim17 and Tim23 are the main subunits of the TIM23 complex, one of the two major essential mitochondrial inner-membrane protein translocon machineries (TIMs). No chemical probes that specifically inhibit TIM23-dependent protein import were known to exist. Here we show that the natural product stendomycin, produced by Streptomyces hygroscopicus, is a potent and specific inhibitor of the TIM23 complex in yeast and mammalian cells. Furthermore, stendomycin-mediated blockage of the TIM23 complex does not alter normal processing of the major regulatory mitophagy kinase PINK1, but TIM23 is required to stabilize PINK1 on the outside of mitochondria to initiate mitophagy upon membrane depolarization.
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