Cells use an exquisite network of mechanisms to maintain the integrity and functionality of their protein components. In the endoplasmic reticulum (ER), these networks of protein homeostasis--referred to as proteostasis--regulate protein synthesis, folding and degradation via the unfolded protein response (UPR) pathway. The UPR pathway has two components: the adaptive UPR pathway, which predominantly maintains the ER function or ER proteostasis, and the apoptotic UPR pathway, which eliminates dysfunctional cells that have been subject to long-term or severe ER stress. Dysregulation of the UPR pathway often occurs in glomerular or tubulointerstitial cells under a pathogenic microenvironment, such as oxidative stress, glycative stress or hypoxia. A defective UPR is highly deleterious to renal cell function and viability and is thereby implicated in the pathophysiology of various kidney diseases. Accumulating evidence provides a link between the UPR pathway and mitochondrial structure and function, indicating the important role of ER proteostasis in the maintenance of mitochondrial homeostasis. Restoration of normal proteostasis, therefore, holds promise in protecting the kidney from pathogenic stresses as well as ageing. This Review is focused on the role of the ER stress and UPR pathway in the maintenance of ER proteostasis, and highlights the involvement of the derangement of ER proteostasis and ER stress in various pathogenic stress signals in the kidney.
Conflict of interest: GWB, AF, and SM are inventors on pending or issued patents (US 10,183,038 and US 10,052,345) aimed at diagnosing or treating proteinuric kidney diseases. They stand to gain royalties from the future commercialization of these patents. AF is Chief Scientific Officer of L&F Health LLC and is a consultant for Variant Pharmaceuticals. Variant Pharmaceuticals has licensed worldwide rights from L&F Research to develop and commercialize hydroxypropyl-beta-cyclodextrin for the treatment of kidney disease. AF is Chief Medical Officer of LipoNexT LLC. SM holds equity interest in a company presently commercializing the form of cyclodextrin referenced in this paper. AF and SM are supported by Hoffman-La Roche. AF is supported by Boehringer Ingelheim.
Acute kidney injury (AKI) is a common clinical entity that is associated with high mortality and morbidity. It is a risk factor for the development and progression of chronic kidney disease. Presently, no effective treatment for AKI is available, and novel therapeutic approaches are desperately needed. Accumulating evidence highlights mitochondrial dysfunction as an important factor in the pathogenesis of AKI. Recent advances in our understanding of the molecules involved in mitochondrial biogenesis, fusion/fission, mitophagy and their pathophysiological roles will lead to the development of drugs that target mitochondria for the treatment of various diseases, including AKI. In this review, we summarize current knowledge of the contribution of mitochondria-related pathophysiology in AKI and the prospective benefits of mitochondria-targeting therapeutic approaches against AKI.
Autosomal dominant polycystic kidney disease (ADPKD) constitutes the most inherited kidney disease. Mutations in the PKD1 and PKD2 genes, encoding the polycystin 1 and polycystin 2 Ca2+ ion channels, respectively, result in tubular epithelial cell-derived renal cysts. Recent clinical studies demonstrate oxidative stress to be present early in ADPKD. Mitochondria comprise the primary reactive oxygen species source and also their main effector target; however, the pathophysiological role of mitochondria in ADPKD remains uncharacterized. To clarify this function, we examined the mitochondria of cyst-lining cells in ADPKD model mice (Ksp-Cre PKD1flox/flox) and rats (Han:SPRD Cy/+), demonstrating obvious tubular cell morphological abnormalities. Notably, the mitochondrial DNA copy number and peroxisome proliferator-activated receptor γ coactivator 1α (PGC-1α) expression were decreased in ADPKD model animal kidneys, with PGC-1α expression inversely correlated with oxidative stress levels. Consistent with these findings, human ADPKD cyst-derived cells with heterozygous and homozygous PKD1 mutation exhibited morphological and functional abnormalities, including increased mitochondrial superoxide. Furthermore, PGC-1α expression was suppressed by decreased intracellular Ca2+ levels via calcineurin, p38 mitogen-activated protein kinase (MAPK), and nitric oxide synthase deactivation. Moreover, the mitochondrion-specific antioxidant MitoQuinone (MitoQ) reduced intracellular superoxide and inhibited cyst epithelial cell proliferation through extracellular signal-related kinase/MAPK inactivation. Collectively, these results indicate that mitochondrial abnormalities facilitate cyst formation in ADPKD.
Recent studies have reported intrinsic metabolic reprogramming in Pkd1 knock-out cells, implicating dysregulated cellular metabolism in the pathogenesis of polycystic kidney disease. However, the exact nature of the metabolic changes and their underlying cause remains controversial. We show herein that Pkd1ko/ko renal epithelial cells have impaired fatty acid utilization, abnormal mitochondrial morphology and function, and that mitochondria in kidneys of ADPKD patients have morphological alterations. We further show that a C-terminal cleavage product of polycystin-1 (CTT) translocates to the mitochondria matrix and that expression of CTT in Pkd1ko/ko cells rescues some of the mitochondrial phenotypes. Using Drosophila to model in vivo effects, we find that transgenic expression of mouse CTT results in decreased viability and exercise endurance but increased CO2 production, consistent with altered mitochondrial function. Our results suggest that PC1 may play a direct role in regulating mitochondrial function and cellular metabolism and provide a framework to understand how impaired mitochondrial function could be linked to the regulation of tubular diameter in both physiological and pathological conditions.
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