Abnormal mitochondrial autophagy in nephropathic cystinosis

Cystinosis, which is characterized by lysosomal accumulation of cystine in many tissues, was the first known storage disorder caused by defective metabolite export from the lysosome. The molecular and cellular mechanisms underlying nephropathic cystinosis, the most severe form, which exhibits generalized proximal tubular dysfunction and progressive renal failure, remain largely unknown. We used renal proximal tubular epithelial (RPTE) cells and fibroblasts from patients with three clinical variants of cystinosis: nephropathic, intermediate and ocular to explore the specific injury mechanism in nephropathic cystinosis. We demonstrate enhanced autophagy of mitochondria, increase in apoptosis and mitochondrial dysfunction in the nephropathic cystinosis phenotype. Furthermore, specific inhibition of autophagy results in significant attenuation of cell death in nephropathic cystinosis. This study provides ultrastructural and functional evidence of abnormal mitochondrial autophagy in nephropathic cystinosis, which may contribute to renal Fanconi syndrome and progressive renal injury.Key words: cystinosis, autophagy, mitochondria, kidney, lysosome, apoptosis, cell death, mitophagyCystinosis is an autosomal recessive metabolic disorder caused by mutations in the CTNS gene, which encodes a 7-transmembrane domain protein, cystinosin, a lysosomal cystine transporter. Cystinosis belongs to the family of lysosomal storage disorders (LSDs) characterized by the tissue accumulation of cystine crystals leading to multiple organ dysfunction. The three types of cystinosis, i.e., nephropathic (classic renal and systemic disease), intermediate (a late-onset variant of nephropathic cystinosis) and non-nephropathic (clinically affecting only the cornea) are allelic disorders caused by CTNS mutations. Children affected with nephropathic cystinosis present with the Fanconi syndrome and usually develop progressive renal failure within the first decade of life. The mechanism linking lysosomal cystine storage to pathological manifestations, in particular to the prominent proximal tubular defect and renal injury, remains unclear. Renal injury in nephropathic cystinosis may not simply be caused just by cystine accumulation, as disruption of the ctns gene in mice induces cystine storage in many tissues but does not result in signs of tubulopathy or renal failure; renal injury is not seen in other human forms of cystinosis and progressive renal injury occurs despite cystine depletion therapy.The purpose of our study was to investigate the specific mechanism leading to tubulopathy and end stage renal injury in nephropathic cystinosis. We used primary fibroblast and renal proximal tubular epithelial (RPTE) cells derived from patients with three clinical phenotypes of cystinosis. Our data show an abnormal increase in macroautophagy (hereafter referred to as autophagy), specific to the nephropathic variant of cystinosis. We also demonstrate that specific inhibition of autophagy rescues cell death in nephropathic cystinotic RPTE cells. Our results indicate that mitochondrial autophagy may be a critical mechanism contributing to renal Fanconi syndrome and progressive renal injury in nephropathic cystinosis.Abnormal autophagy was also recently observed in other types of lysosomal storage diseases (LSD). However, our study provides the first evidence supporting the extensive involvement of autophagy in nephropathic cystinosis pathogenesis. Abundant vacuolization and abnormal mitochondria are detected by electron microscopy (EM) in nephropathic cystinotic cells. Additionally, elevated levels of LC3-II and Beclin 1 are also observed in nephropathic cystinotic RPTE cells, indicating a role of Beclin 1-mediated autophagy in cystinosis. These results altogether establish an abnormal increase in autophagy in nephropathic cystinotic cells.Renal biopsies from patients with nephropathic cystinosis can reveal abnormally large mitochondria, but the relevance of this finding and other ultrastructural abnormalities is unclear. Our study further demonstrates a significant decrease in mitochondrial ATP generation with an increase in reactive oxygen species (ROS) in cystinotic cells. To further dissect the association of abnormal mitochondria with increased autophagy in cystinosis, we carefully examined the electron micrographs at higher magnifications. We discovered various stages of degradation of mitochondria by autophagy (hereafter referred to as mitophagy). To further validate mitophagy in cystinosis, we used an immunofluorescence (IF) approach to capture colocalization images of LC3, LAMP-2 (lysosomal marker) and ATP5H (mitochondrial marker). Intriguingly, an increase in LAMP-2 perinuclear staining is detected by IF assay in cystinotic cells. This observation may also denote enhanced active autophagy as LAMP-2 is involved in lysosomal biogenesis and/or the fusion between autophagosomes and lysosomes. Alternatively, LAMP-2 accumulation could be a manifestation of retarded autophagic flux in cystinotic cells. A decreased ability of lysosomes to fuse with autophagosomes has been reported in various LSDs. However, the colocalization of LC3 and LAMP-2 in nephropathic cystinotic RPTE cells argues against this possibility. Nevertheless, the possibility of autophagic flux blockade after autophagosome-lysosome fusion leading to detrimental effects is yet to be investigated. Interestingly, previously published EM reports of the renal biopsies of patients with nephropathic cystinosis show only the nucleus and a thin rim of cytoplasm as remnants in a proximal tubular cell, while mitochondria and lysosomes completely disappear.Conventionally, autophagy has been suggested as a cytoprotective mechanism to ensure cell survival during starvation. In contrast, several forms of cell death have been associated with the appearance of autophagic vesicles. To gain insight into the role of autophagy as regards to cell death or cell survival in nephropathic cystinosis, we used 3-methyladenine (3MA), a specific inhibitor of autophagy and assayed cell viability and apoptosis in cystinotic cells. Increased apoptosis has been previously reported in cultured cystinotic fibroblasts and RPTE cells. Treatment with 3MA in cystinotic cells significantly rescues cell death, thus suggesting a synergistic role of apoptosis and autophagy in cystinosis.In conclusion, as illustrated in Figure 1, we speculate that there is a multifaceted impact of autophagy in nephropathic cystinosis as follows: (1) the mechanism linking autophagy to lysosomal cystine or apoptosis in cystinotic cells could potentially be related to lysosomal membrane permeabilization (LMP), proposed as an early step in apoptosis in cystinosis. We hypothesize that abnormal induction of autophagy besides providing more cargo to be digested in the lysosomes, leads to increased fusion of autophagosomes with cystine-laden lysosomes, rendering them more sensitive to membrane destabilization, and thus making them readily enter the apoptotic pathway; (2) the second most important question is the link between abnormal mitochondria and mitophagy in cystinosis. A decreased level of cytosolic glutathione in cystinotic cells is one of the known factors responsible for generating damaged mitochondria. Our data also indicate an impairment of complex I activity, an increase in ROS and a decrease in mitochondrial ATP generation in cystinotic cells. We hypothesize that the abnormal induction of autophagy leads to depletion of mitochondria, forcing cells to enter the ‘starvation mode,’ thereby leading to an uncontrolled autophagy and cell death; (3) the third key question yet to be answered is the link between autophagy and renal injury in nephropathic cystinosis. Skeletal muscles and neuronal tissues are the primary organs where autophagy is physiologically enhanced. Recently, it has been shown that mouse kidneys exert a high level of autophagy under basal conditions, influencing the susceptibility to glomerular disease and renal failure. Thus, we postulate an organ- and tissue-specific effect of abnormally induced autophagy in nephropathic cystinosis, causing severe injury to kidneys leading to loss of renal function, ultimately culminating in end-stage renal disease.Open in a separate windowFigure 1A schematic view of the interplay between autophagy, abnormal mitochondria and cell death in cystinosis. Abnormal induction of autophagy, typically mitophagy, forces cells into a starvation mode leading to cell death; and renders cystine-laden lysosomes sensitive to lysosomal membrane permeabilization (LMP) making it readily enter the apoptosis pathway. A potential block in autophagic flux, after autophagosome-lysosome fusion, remains to be elucidated. Preferential severe kidney damage in nephropathic cystinosis may be due to the tissue- and organ-specific injury effect of autophagy.The recent progress in autophagy research has increased the need for additional studies so that we can fully understand the underlying pathological mechanisms and the significance of the lysosomal cell death axis in lysosomal storage disorders.     

Cysteamine restores glutathione redox status in cultured cystinotic proximal tubular epithelial cells

Recent evidence implies that impaired metabolism of glutathione has a role in the pathogenesis of nephropathic cystinosis. This recessive inherited disorder is characterized by lysosomal cystine accumulation and results in renal Fanconi syndrome progressing to end stage renal disease in the majority of patients. The most common treatment involves intracellular cystine depletion by cysteamine, delaying the development of end stage renal disease by a yet elusive mechanism. However, cystine depletion does not arrest the disease nor cures Fanconi syndrome in patients, indicating involvement of other yet unknown pathologic pathways. Using a newly developed proximal tubular epithelial cell model from cystinotic patients, we investigate the effect of cystine accumulation and cysteamine on both glutathione and ATP metabolism. In addition to the expected increase in cystine and defective sodium-dependent phosphate reabsorption, we observed less negative glutathione redox status and decreased intracellular ATP levels. No differences between control and cystinosis cell lines were observed with respect to protein turnover, albumin uptake, cytosolic and mitochondrial ATP production, total glutathione levels, protein oxidation and lipid peroxidation. Cysteamine treatment increased total glutathione in both control and cystinotic cells and normalized cystine levels and glutathione redox status in cystinotic cells. However, cysteamine did not improve decreased sodium-dependent phosphate uptake. Our data implicate that cysteamine increases total glutathione and restores glutathione redox status in cystinosis, which is a positive side-effect of this agent next to cystine depletion. This beneficial effect points to a potential role of cysteamine as anti-oxidant for other renal disorders associated with enhanced oxidative stress.     

Fight-or-flight: murine unilateral ureteral obstruction causes extensive proximal tubular degeneration, collecting duct dilatation, and minimal fibrosis

Unilateral ureteral obstruction (UUO) is the most widely used animal model of progressive renal disease. Although renal interstitial fibrosis is commonly used as an end point, recent studies reveal that obstructive injury to the glomerulotubular junction leads to the formation of atubular glomeruli. To quantitate the effects of UUO on the remainder of the nephron, renal tubular and interstitial responses were characterized in mice 7 and 14 days after UUO or sham operation under anesthesia. Fractional proximal tubular mass, cell proliferation, and cell death were measured by morphometry. Superoxide formation was identified by nitro blue tetrazolium, and oxidant injury was localized by 4-hydroxynonenol and 8-hydroxydeoxyguanosine. Fractional areas of renal vasculature, interstitial collagen, α-smooth muscle actin, and fibronectin were also measured. After 14 days of UUO, the obstructed kidney loses 19% of parenchymal mass, with a 65% reduction in proximal tubular mass. Superoxide formation is localized to proximal tubules, which undergo oxidant injury, apoptosis, necrosis, and autophagy, with widespread mitochondrial loss, resulting in tubular collapse. In contrast, mitosis and apoptosis increase in dilated collecting ducts, which remain patent through epithelial cell remodeling. Relative vascular volume fraction does not change, and interstitial matrix components do not exceed 15% of total volume fraction of the obstructed kidney. These unique proximal and distal nephron cellular responses reflect differential "fight-or-flight" responses to obstructive injury and provide earlier indexes of renal injury than do interstitial compartment responses. Therapies to prevent or retard progression of renal disease should include targeting proximal tubule injury as well as interstitial fibrosis.     

Mitochondrial superoxide plays a crucial role in the development of mitochondrial dysfunction during high glucose exposure in rat renal proximal tubular cells

Diabetic nephropathy is the leading cause of end-stage renal disease in the United States. Despite several studies indicating a role for mitochondrial oxidative stress and mitochondrial dysfunction in the development of diabetic complications, the precise mechanisms underlying renal mitochondrial dysfunction and renal cell injury remain unclear. The hypothesis of the current study was that high-glucose-mediated generation of mitochondrial superoxide is a key early event that leads to mitochondrial injury in renal proximal tubular cells. To ascertain the role of mitochondrial superoxide we have tested whether overexpression of the primary mitochondrial antioxidant, manganese superoxide dismutase (MnSOD), protects against hyperglycemia-induced renal injury using normal rat renal proximal tubular cells (NRK). NRK cells were exposed to high glucose (25 mM) and the changes in the mitochondrial membrane potential, ATP levels, and superoxide generation and the loss of cell viability were measured at 24 and 48 h after high glucose exposure. Our results indicate that high glucose first induced superoxide generation and hyperpolarization in the mitochondria, followed by a secondary event, which involved a decline in ATP levels, partial Complex III inactivation, and loss of cell viability. These high-glucose-induced changes were completely prevented by overexpression of MnSOD in NRK cells. However, MnSOD activity was not changed after high glucose exposure in vitro or during the early stages of diabetes using the streptozotocin rat model. These findings show for the first time that hyperglycemic induction of superoxide production within the mitochondria initiates specific mitochondrial injury (i.e., Complex III) via a mechanism independent of MnSOD inactivation.     

Persistent disruption of mitochondrial homeostasis after acute kidney injury

While mitochondrial dysfunction is a pathological process that occurs after acute kidney injury (AKI), the state of mitochondrial homeostasis during the injury and recovery phases of AKI remains unclear. We examined markers of mitochondrial homeostasis in two nonlethal rodent AKI models. Myoglobinuric AKI was induced by glycerol injection into rats, and mice were subjected to ischemic AKI. Animals in both models had elevated serum creatinine, indicative of renal dysfunction, 24 h after injury which partially recovered over 144 h postinjury. Markers of proximal tubule function/injury, including neutrophil gelatinase-associated lipocalin and urine glucose, did not recover during this same period. The persistent pathological state was confirmed by sustained caspase 3 cleavage and evidence of tubule dilation and brush-border damage. Respiratory proteins NDUFB8, ATP synthase β, cytochrome c oxidase subunit I (COX I), and COX IV were decreased in both injury models and did not recover by 144 h. Immunohistochemical analysis confirmed that COX IV protein was progressively lost in proximal tubules of the kidney cortex after ischemia-reperfusion (I/R). Expression of mitochondrial fission protein Drp1 was elevated after injury in both models, whereas the fusion protein Mfn2 was elevated after glycerol injury but decreased after I/R AKI. LC3-I/II expression revealed that autophagy increased in both injury models at the later time points. Markers of mitochondrial biogenesis, such as PGC-1α and PRC, were elevated in both models. These findings reveal that there is persistent disruption of mitochondrial homeostasis and sustained tubular damage after AKI, even in the presence of mitochondrial recovery signals and improved glomerular filtration.     

Endo-Lysosomal Dysfunction in Human Proximal Tubular Epithelial Cells Deficient for Lysosomal Cystine Transporter Cystinosin

Nephropathic cystinosis is a lysosomal storage disorder caused by mutations in the CTNS gene encoding cystine transporter cystinosin that results in accumulation of amino acid cystine in the lysosomes throughout the body and especially affects kidneys. Early manifestations of the disease include renal Fanconi syndrome, a generalized proximal tubular dysfunction. Current therapy of cystinosis is based on cystine-lowering drug cysteamine that postpones the disease progression but offers no cure for the Fanconi syndrome. We studied the mechanisms of impaired reabsorption in human proximal tubular epithelial cells (PTEC) deficient for cystinosin and investigated the endo-lysosomal compartments of cystinosin-deficient PTEC by means of light and electron microscopy. We demonstrate that cystinosin-deficient cells had abnormal shape and distribution of the endo-lysosomal compartments and impaired endocytosis, with decreased surface expression of multiligand receptors and delayed lysosomal cargo processing. Treatment with cysteamine improved surface expression and lysosomal cargo processing but did not lead to a complete restoration and had no effect on the abnormal morphology of endo-lysosomal compartments. The obtained results improve our understanding of the mechanism of proximal tubular dysfunction in cystinosis and indicate that impaired protein reabsorption can, at least partially, be explained by abnormal trafficking of endosomal vesicles.     

Autophagy delays apoptosis in renal tubular epithelial cells in cisplatin cytotoxicity

One of the major side effects of cisplatin chemotherapy is toxic acute kidney injury due to preferential accumulation of cisplatin in renal proximal tubule epithelial cells and the subsequent injury to these cells. Apoptosis is known as a major mechanism of cisplatin-induced cell death in renal tubular cells. We have also recently demonstrated that autophagy induction is an immediate response of renal tubular epithelial cell exposure to cisplatin. Inhibition of cisplatin-induced autophagy blocks the formation of autophagosomes and enhances cisplatin-induced caspase-3, -6, and -7 activation, nuclear fragmentation, and apoptosis. The switch from autophagy to apoptosis by autophagic inhibitors suggests that autophagy induction was responsible for a pre-apoptotic lag phase observed on exposure of renal tubular cells to cisplatin. Our studies provide evidence that autophagy induction in response to cisplatin mounts an adaptive response that suppresses and delays apoptosis. The beneficial effect of autophagy has a potential clinical significance in minimizing or preventing cisplatin nephrotoxicity.

Addedum to: Yang C, Kaushal V, Shah SV, Kaushal GP. Autophagy and apoptosis are associated in cisplatin injury to renal tubular epithelial cell injury. Am J Physiol Renal Physiol 2008; 294:F777-87.     

Autophagy delays apoptosis in renal tubular epithelial cells in cisplatin cytotoxicity

One of the major side effects of cisplatin chemotherapy is toxic acute kidney injury due to preferential accumulation of cisplatin in renal proximal tubule epithelial cells and the subsequent injury to these cells. Apoptosis is known as a major mechanism of cisplatin-induced cell death in renal tubular cells. We have also recently demonstrated that autophagy induction is an immediate response of renal tubular epithelial cell exposure to cisplatin. Inhibition of cisplatin-induced autophagy blocks the formation of autophagosomes and enhances cisplatin-induced caspase-3, -6, and -7 activation, nuclear fragmentation and apoptosis. The switch from autophagy to apoptosis by autophagic inhibitors suggests that autophagy induction was responsible for a pre-apoptotic lag phase observed on exposure of renal tubular cells to cisplatin. Our studies provide evidence that autophagy induction in response to cisplatin mounts an adaptive response that suppresses and delays apoptosis. The beneficial effect of autophagy has a potential clinical significance in minimizing or preventing cisplatin nephrotoxicity.     

Renal Impairment with Sublethal Tubular Cell Injury in a Chronic Liver Disease Mouse Model

The pathogenesis of renal impairment in chronic liver diseases (CLDs) has been primarily studied in the advanced stages of hepatic injury. Meanwhile, the pathology of renal impairment in the early phase of CLDs is poorly understood, and animal models to elucidate its mechanisms are needed. Thus, we investigated whether an existing mouse model of CLD induced by 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) shows renal impairment in the early phase. Renal injury markers, renal histology (including immunohistochemistry for tubular injury markers and transmission electron microscopy), autophagy, and oxidative stress were studied longitudinally in DDC- and standard diet–fed BALB/c mice. Slight but significant renal dysfunction was evident in DDC-fed mice from the early phase. Meanwhile, histological examinations of the kidneys with routine light microscopy did not show definitive morphological findings, and electron microscopic analyses were required to detect limited injuries such as loss of brush border microvilli and mitochondrial deformities. Limited injuries have been recently designated as sublethal tubular cell injury. As humans with renal impairment, either with or without CLD, often show almost normal tubules, sublethal injury has been of particular interest. In this study, the injuries were associated with mitochondrial aberrations and oxidative stress, a possible mechanism for sublethal injury. Intriguingly, two defense mechanisms were associated with this injury that prevent it from progressing to apparent cell death: autophagy and single-cell extrusion with regeneration. Furthermore, the renal impairment of this model progressed to chronic kidney disease with interstitial fibrosis after long-term DDC feeding. These findings indicated that DDC induces renal impairment with sublethal tubular cell injury from the early phase, leading to chronic kidney disease. Importantly, this CLD mouse model could be useful for studying the pathophysiological mechanisms of sublethal tubular cell injury.     

Autophagy Limits Endotoxemic Acute Kidney Injury and Alters Renal Tubular Epithelial Cell Cytokine Expression

Sepsis related acute kidney injury (AKI) is a common in-hospital complication with a dismal prognosis. Our incomplete understanding of disease pathogenesis has prevented the identification of hypothesis-driven preventive or therapeutic interventions. Increasing evidence in ischemia-reperfusion and nephrotoxic mouse models of AKI support the theory that autophagy protects renal tubular epithelial cells (RTEC) from injury. However, the role of RTEC autophagy in septic AKI remains unclear. We observed that lipopolysaccharide (LPS), a mediator of gram-negative bacterial sepsis, induces RTEC autophagy in vivo and in vitro through TLR4-initiated signaling. We modeled septic AKI through intraperitoneal LPS injection in mice in which autophagy-related protein 7 was specifically knocked out in the renal proximal tubules (ATG7KO). Compared to control littermates, ATG7KO mice developed more severe renal dysfunction (24hr BUN 100.1mg/dl +/- 14.8 vs 54.6mg/dl +/- 11.3) and parenchymal injury. After injection with LPS, analysis of kidney lysates identified higher IL-6 expression and increased STAT3 activation in kidney lysates from ATG7KO mice compared to controls. In vitro experiments confirmed an altered response to LPS in RTEC with genetic or pharmacological impairment of autophagy. In conclusion, RTEC autophagy protects against endotoxin induced injury and regulates downstream effects of RTEC TLR4 signaling.     

Protective Role of AMP-Activated Protein Kinase-Evoked Autophagy on an In Vitro Model of Ischemia/Reperfusion-Induced Renal Tubular Cell Injury

Ischemia/reperfusion (I/R) injury is a common cause of injury to target organs such as brain, heart, and kidneys. Renal injury from I/R, which may occur in renal transplantation, surgery, trauma, or sepsis, is known to be an important cause of acute kidney injury. The detailed molecular mechanism of renal I/R injury is still not fully clear. Here, we investigate the role of AMP-activated protein kinase (AMPK)-evoked autophagy in the renal proximal tubular cell death in an in vitro I/R injury model. To mimic in vivo renal I/R injury, LLC-PK1 cells, a renal tubular cell line derived from pig kidney, were treated with antimycin A and 2-deoxyglucose to mimic ischemia injury followed by reperfusion with growth medium. This I/R injury model markedly induced apoptosis and autophagy in LLC-PK1 cells in a time-dependent manner. Autophagy inhibitor 3-methyladenine (3MA) significantly enhanced I/R injury-induced apoptosis. I/R could also up-regulate the phosphorylation of AMPK and down-regulate the phosphorylation of mammalian target of rapamycin (mTOR). Cells transfected with small hairpin RNA (shRNA) for AMPK significantly increased the phosphorylation of mTOR as well as decreased the induction of autophagy followed by enhancing cell apoptosis during I/R. Moreover, the mTOR inhibitor RAD001 significantly enhanced autophagy and attenuated cell apoptosis during I/R. Taken together, these findings suggest that autophagy induction protects renal tubular cell injury via an AMPK-regulated mTOR pathway in an in vitro I/R injury model. AMPK-evoked autophagy may be as a potential target for therapeutic intervention in I/R renal injury.     

Time-dependent dysregulation of autophagy: Implications in aging and mitochondrial homeostasis in the kidney proximal tubule

Autophagy plays an essential role in cellular homeostasis through the quality control of proteins and organelles. Although a time-dependent decline in autophagic activity is believed to be involved in the aging process, the issue remains controversial. We previously demonstrated that autophagy maintains proximal tubular cell homeostasis and protects against kidney injury. Here, we extend that study and examine how autophagy is involved in kidney aging. Unexpectedly, the basal autophagic activity was higher in the aged kidney than that in young kidney; short-term cessation of autophagy in tamoxifen-inducible proximal tubule-specific autophagy-deficient mice increased the accumulation of SQSTM1/p62- and ubiquitin-positive aggregates in the aged kidney. By contrast, autophagic flux in response to metabolic stress was blunted with aging, as demonstrated by the observation that transgenic mice expressing a green fluorescent protein (GFP)-microtubule-associated protein 1 light chain 3B fusion construct, showed a drastic increase of GFP-positive puncta in response to starvation in young mice compared to a slight increase observed in aged mice. Finally, proximal tubule-specific autophagy-deficient mice at 24 mo of age exhibited a significant deterioration in kidney function and fibrosis concomitant with mitochondrial dysfunction as well as mitochondrial DNA abnormalities and nuclear DNA damage, all of which are hallmark characteristics of cellular senescence. These results suggest that age-dependent high basal autophagy plays a crucial role in counteracting kidney aging through mitochondrial quality control. Furthermore, a reduced capacity for upregulation of autophagic flux in response to metabolic stress may be associated with age-related kidney diseases.     

Mitochondrial Dysfunction and Electron Transport Chain Complex Defect in a Rat Model of Tenofovir Disoproxil Fumarate Nephrotoxicity

The long‐term use of tenofovir, a commonly used anti‐HIV drug, can result in renal damage. The mechanism of tenofovir disoproxil fumarate (TDF) nephrotoxicity is not clear, although it has been shown to target proximal tubular mitochondria. In the present study, the effects of chronic TDF treatment on the proximal tubular function, renal mitochondrial function, and the activities of the electron transport chain (ETC) complexes were studied in rats. Damage to proximal tubular mitochondria and proximal tubular dysfunction was observed. The impaired mitochondrial function such as the respiratory control ratio, 2‐(4,5‐dimethyl‐2‐thiazolyl)‐3,5‐diphenyl‐2H‐tetrazolium bromide (MTT) reduction, and mitochondrial swelling was observed. The activities of the electron chain complexes I, II, IV, and V were decreased by 46%, 20%, 26%, and 21%, respectively, in the TDF‐treated rat kidneys. It is suggested that TDF induced proximal tubular mitochondrial dysfunction and ETC defects may impair ATP production, resulting in proximal tubular damage and dysfunction.     

An interplay between UCP2 and ROS protects cells from high-salt-induced injury through autophagy stimulation

The mitochondrial uncoupling protein 2 (UCP2) plays a protective function in the vascular disease of both animal models and humans. UCP2 downregulation upon high-salt feeding favors vascular dysfunction in knock-out mice, and accelerates cerebrovascular and renal damage in the stroke-prone spontaneously hypertensive rat. Overexpression of UCP2 counteracts the negative effects of high-salt feeding in both animal models. We tested in vitro the ability of UCP2 to stimulate autophagy and mitophagy as a mechanism mediating its protective effects upon high-salt exposure in endothelial and renal tubular cells. UCP2 silencing reduced autophagy and mitophagy, whereas the opposite was true upon UCP2 overexpression. High-salt exposure increased level of reactive oxygen species (ROS), UCP2, autophagy and autophagic flux in both endothelial and renal tubular cells. In contrast, high-salt was unable to induce autophagy and autophagic flux in UCP2-silenced cells, concomitantly with excessive ROS accumulation. The addition of an autophagy inducer, Tat-Beclin 1, rescued the viability of UCP2-silenced cells even when exposed to high-salt. In summary, UCP2 mediated the interaction between high-salt-induced oxidative stress and autophagy to preserve viability of both endothelial and renal tubular cells. In the presence of excessive ROS accumulation (achieved upon UCP2 silencing and high-salt exposure of silenced cells) autophagy was turned off. In this condition, an exogenous autophagy inducer rescued the cellular damage induced by excess ROS level. Our data confirm the protective role of UCP2 toward high-salt-induced vascular and renal injury, and they underscore the role of autophagy/mitophagy as a mechanism counteracting the high-salt-induced oxidative stress damage.Subject terms: Macroautophagy, Macroautophagy     

Wnt/β‐catenin/RAS signaling mediates age‐related renal fibrosis and is associated with mitochondrial dysfunction

Renal fibrosis is the common pathological feature in a variety of chronic kidney diseases. Aging is highly associated with the progression of renal fibrosis. Among several determinants, mitochondrial dysfunction plays an important role in aging. However, the underlying mechanisms of mitochondrial dysfunction in age‐related renal fibrosis are not elucidated. Herein, we found that Wnt/β‐catenin signaling and renin–angiotensin system (RAS) activity were upregulated in aging kidneys. Concomitantly, mitochondrial mass and functions were impaired with aging. Ectopic expression of Klotho, an antagonist of endogenous Wnt/β‐catenin activity, abolished renal fibrosis in d ‐galactose (d ‐gal)‐induced accelerated aging mouse model and significantly protected renal mitochondrial functions by preserving mass and diminishing the production of reactive oxygen species. In an established aging mouse model, dickkopf 1, a more specific Wnt inhibitor, and the mitochondria‐targeted antioxidant mitoquinone restored mitochondrial mass and attenuated tubular senescence and renal fibrosis. In a human proximal tubular cell line (HKC‐8), ectopic expression of Wnt1 decreased biogenesis and induced dysfunction of mitochondria, and triggered cellular senescence. Moreover, d ‐gal triggered the transduction of Wnt/β‐catenin signaling, which further activated angiotensin type 1 receptor (AT1), and then decreased the mitochondrial mass and increased cellular senescence in HKC‐8 cells and primary cultured renal tubular cells. These effects were inhibited by AT1 blocker of losartan. These results suggest inhibition of Wnt/β‐catenin signaling and the RAS could slow the onset of age‐related mitochondrial dysfunction and renal fibrosis. Taken together, our results indicate that Wnt/β‐catenin/RAS signaling mediates age‐related renal fibrosis and is associated with mitochondrial dysfunction.     

Improved Mitochondrial Function Underlies the Protective Effect of Pirfenidone against Tubulointerstitial Fibrosis in 5/6 Nephrectomized Rats

Dysfunctional mitochondria participate in the progression of chronic kidney disease (CKD). Pirfenidone is a newly identified anti-fibrotic drug. However, its mechanism remains unclear. Mitochondrial dysfunction is an early event that occurs prior to the onset of renal fibrosis. In this context, we investigated the protective effect of pirfenidone on mitochondria and its relevance to apoptosis and oxidative stress in renal proximal tubular cells. A remnant kidney rat model was established. Human renal proximal tubular epithelial cells (HK2) using rotenone, a mitochondrial respiratory chain complex Ι inhibitor were further investigated in vitro to examine the mitochondrial protective effect of pirfenidone. Pirfenidone protected mitochondrial structures and functions by stabilizing the mitochondrial membrane potential, maintaining ATP production and improving the mitochondrial DNA (mtDNA) copy number. Pirfenidone decreased tubular cell apoptosis by inhibiting the mitochondrial apoptotic signaling pathway. Pirfenidone also reduced oxidative stress by enhancing manganese superoxide dismutase (Mn-SOD) and inhibiting intracellular reactive oxygen species (ROS) generation, which suggested that the anti-oxidant effects occurred at least partially via the mitochondrial pathway. Pirfenidone may be effective prior to the onset of renal fibrosis because this drug exerts its anti-fibrotic effect by protection of mitochondria in renal proximal tubular cells.     

Signaling of mitochondrial biogenesis following oxidant injury

Mitochondrial dysfunction is a common consequence of ischemia-reperfusion and drug injuries. For example, sublethal injury of renal proximal tubular cells (RPTCs) with the model oxidant tert-butylhydroperoxide (TBHP) causes mitochondrial injury that recovers over the course of six days. Although regeneration of mitochondrial function is integral to cell repair and function, the signaling pathway of mitochondrial biogenesis following oxidant injury has not been examined. A 10-fold overexpression of the mitochondrial biogenesis regulator PPAR-gamma cofactor-1alpha (PGC-1alpha) in control RPTCs resulted in a 52% increase in mitochondrial number, a 27% increase in respiratory capacity, and a 30% increase in mitochondrial protein markers, demonstrating that PGC-1alpha mediates mitochondrial biogenesis in RPTCs. RPTCs sublethally injured with TBHP exhibited a 50% decrease in mitochondrial function and increased mitochondrial autophagy. Compared with the controls, PGC-1alpha levels increased 12-fold on days 1, 2, and 3 post-injury and returned to base line on day 4 as mitochondrial function returned. Inhibition p38 MAPK blocked the up-regulation of PGC-1alpha following oxidant injury, whereas inhibition of calcium-calmodulin-dependent protein kinase, calcineurin A, nitric-oxide synthase, and phosphoinositol 3-kinase had no effect. The epidermal growth factor receptor (EGFR) was activated following TBHP exposure, and the EGFR inhibitor AG1478 blocked the up-regulation of PGC-1alpha. Additional inhibitor studies revealed that the sequential activation of Src, p38 MAPK, EGFR, and p38 MAPK regulate the expression of PGC-1alpha following oxidant injury. In contrast, although Akt was activated following oxidant injury, it did not play a role in PGC-1alpha expression. We suggest that mitochondrial biogenesis following oxidant injury is mediated by p38 and EGFR activation of PGC-1alpha.     

Reciprocal regulation between ER stress and autophagy in renal tubular fibrosis and apoptosis

Both endoplasmic reticulum (ER) stress and autophagy have been implicated in chronic kidney injury and renal fibrosis. However, the relationship and regulatory mechanisms between ER stress and autophagy under this condition remain largely unknown. In this study, we first established a mouse model of ER stress-induced chronic kidney injury by 2 weekly injections of a low dose of tunicamycin (TM), a classical ER stress inducer. This model showed the induction of ER stress, autophagy, fibrosis and apoptosis in kidney tissues. In vitro, TM also induced ER stress, autophagy, fibrosis and apoptosis in HK-2 human kidney proximal tubular cells and BUMPT-306 mouse kidney proximal tubular cells. In these cells, autophagy inhibitor suppressed TM-induced fibrotic changes and apoptosis, suggesting an involvement of autophagy in ER stress-associated chronic kidney injury. PERK inhibitor ameliorated autophagy, fibrotic protein expression and apoptosis in TM-treated cells, indicating a role of the PERK/eIF2α pathway in autophagy activation during ER stress. Similar results were shown in TGF-β1-treated HK-2 cells. Interestingly, in both TM- or TGF-β1-treated kidney proximal tubular cells, inhibition of autophagy exaggerated ER stress, suggesting that autophagy induced by ER stress provides a negative feedback mechanism to reduce the stress. Together, these results unveil a reciprocal regulation between ER stress and autophagy in chronic kidney injury and fibrosis.Subject terms: Acute kidney injury, Chronic kidney disease     

Endoplasmic Reticulum Stress-Induced Autophagy Provides Cytoprotection from Chemical Hypoxia and Oxidant Injury and Ameliorates Renal Ischemia-Reperfusion Injury

We examined whether endoplasmic reticulum (ER) stress-induced autophagy provides cytoprotection from renal tubular epithelial cell injury due to oxidants and chemical hypoxia in vitro, as well as from ischemia-reperfusion (IR) injury in vivo. We demonstrate that the ER stress inducer tunicamycin triggers an unfolded protein response, upregulates ER chaperone Grp78, and activates the autophagy pathway in renal tubular epithelial cells in culture. Inhibition of ER stress-induced autophagy accelerated caspase–3 activation and cell death suggesting a pro-survival role of ER stress-induced autophagy. Compared to wild-type cells, autophagy-deficient MEFs subjected to ER stress had enhanced caspase–3 activation and cell death, a finding that further supports the cytoprotective role of ER stress-induced autophagy. Induction of autophagy by ER stress markedly afforded cytoprotection from oxidants H₂O₂ and tert-Butyl hydroperoxide and from chemical hypoxia induced by antimycin A. In contrast, inhibition of ER stress-induced autophagy or autophagy-deficient cells markedly enhanced cell death in response to oxidant injury and chemical hypoxia. In mouse kidney, similarly to renal epithelial cells in culture, tunicamycin triggered ER stress, markedly upregulated Grp78, and activated autophagy without impairing the autophagic flux. In addition, ER stress-induced autophagy markedly ameliorated renal IR injury as evident from significant improvement in renal function and histology. Inhibition of autophagy by chloroquine markedly increased renal IR injury. These studies highlight beneficial impact of ER stress-induced autophagy in renal ischemia-reperfusion injury both in vitro and in vivo.