Selective mitochondrial autophagy during erythroid maturation

Accumulating evidence suggests that autophagy can be selective in the clearance of organelles in yeast and in mammalian cells. We have observed that the sequestration of mitochondria by autophagosomes was defective in reticulocytes in the absence of Nix. Nix is required for the dissipation of mitochondrial membrane potential (ΔΨm) during erythroid maturation. Moreover, pharmacological agents that induce the loss of ΔΨm can restore the sequestration of mitochondria by autophagosomes and promote mitochondrial clearance in Nix-/- erythroid cells. Our data suggest that mitochondrial depolarization induces recognition and sequestration of mitochondria by autophagosomes. Elucidating the mechanisms underlying selective mitochondrial autophagy not only will help us to understand the mechanisms for erythroid maturation, but also may provide insights into mitochondrial quality control by autophagy in the protection against aging, cancer, and neurodegenerative diseases.

Addendum to: Sandoval H, Thiagarajan P, Dasgupta SK, Schumacher A, Prchal JT, Chen M, Wang J. Essential role for Nix in autophagic maturation of erythroid cells. Nature 2008; 454:232-5.     

NIX induces mitochondrial autophagy in reticulocytes

The controlled elimination of defective mitochondria is necessary for the health of long-lived post-mitotic cells, like cardiomyocytes and neurons. Mitochondrial elimination also occurs during the course of normal development, in lens epithelial and erythroid cells. Strikingly, at the final stage of erythroid cell maturation, newly formed erythrocytes, also known as reticulocytes, eliminate their entire cohort of mitochondria. We have employed this model to investigate the mechanism of programmed mitochondrial clearance. NIX (BNIP3L) is a Bcl-2-related protein that is upregulated during terminal erythroid differentiation. NIX-deficient reticulocytes have a significant defect of mitochondrial clearance. Consistent with the ability of NIX to cause mitochondrial depolarization, we show that mitochondria are depolarized in wild type but not NIX deficient reticulocytes. NIX does not function through established proapoptotic pathways, nor does it mediate the induction of autophagy in erythroid cells. Rather, NIX is required for the selective incorporation of mitochondria into autophagosomes. Elucidation of the mechanism of this effect will improve our understanding of the role of autophagy in the maintenance of cellular homeostasis.     

Mitochondrial clearance by autophagy in developing erythrocytes: Clearly important,but just how much so?

Erythrocytes are anucleated cells devoid of organelles. Expulsion of the nucleus from erythroblasts leads to the formation of reticulocytes, which still contain organelles. The mechanisms responsible for the final removal of organelles from developing erythroid cells are still being elucidated. Mitochondria are the most abundant organelles to be cleared for the completion of erythropoiesis. Macroautophagy, referred to as autophagy, is a regulated catabolic pathway consisting of the engulfment of cytoplasmic cargo by a double membraned-vesicle, the autophagosome, which typically then fuses to lysosomal compartments for the degradation of the sequestered material. Early electron microscopic observations of reticulocytes suggested the autophagic engulfment of mitochondria (mitophagy) as a possible mechanism for mitochondrial clearance in these. Recently, a number of studies have backed this hypothesis with molecular evidence. Indeed, the absence of Nix, which targets mitochondria to autophagosomes, or the deficiency of proteins in the autophagic pathway lead to impaired mitochondrial clearance from developing erythroid cells. Importantly, however, the extent to which the absence of mitophagy affects erythroid development differs depending on the model and gene investigated. This review will therefore focus on comparing the different studies of mitophagy in erythroid development and highlight some of the remaining controversial points.     

NIX induces mitochondrial autophagy in reticulocytes

The controlled elimination of defective mitochondria is necessaryfor the health of long-lived post-mitotic cells, like cardiomyocytesand neurons. Mitochondrial elimination also occurs during thecourse of normal development, in lens epithelial and erythroidcells. Strikingly, at the final stage of erythroid cell maturation,newly formed erythrocytes, also known as reticulocytes, eliminatetheir entire cohort of mitochondria. We have employed thismodel to investigate the mechanism of programmed mitochondrialclearance. NIX (BNIP3L) is a Bcl-2-related protein that is upregulatedduring terminal erythroid differentiation.^1,2 NIX-deficientreticulocytes have a significant defect of mitochondrial clearance.Consistent with the ability of NIX to cause mitochondrial depolarization, ^3,4 we show that mitochondria are depolarized in wildtype but not NIX deficient reticulocytes. NIX does not functionthrough established proapoptotic pathways, nor does it mediate theinduction of autophagy in erythroid cells. Rather, NIX is requiredfor the selective incorporation of mitochondria into autophagosomes.Elucidation of the mechanism of this effect will improveour understanding of the role of autophagy in the maintenance ofcellular homeostasis.

Addendum to: Schweers RL, Zhang J, Randall MS, Loyd MR, Li W, Dorsey FC, Kundu M, Opferman JT, Cleveland JL, Miller JL, Ney PA. NIX is required for programmed mitochondrial clearance during reticulocyte maturation. Proc Natl Acad Sci USA 2007; 104:19500-5.     

Nix is a selective autophagy receptor for mitochondrial clearance

Autophagy is the cellular homeostatic pathway that delivers large cytosolic materials for degradation in the lysosome. Recent evidence indicates that autophagy mediates selective removal of protein aggregates, organelles and microbes in cells. Yet, the specificity in targeting a particular substrate to the autophagy pathway remains poorly understood. Here, we show that the mitochondrial protein Nix is a selective autophagy receptor by binding to LC3/GABARAP proteins, ubiquitin‐like modifiers that are required for the growth of autophagosomal membranes. In cultured cells, Nix recruits GABARAP‐L1 to damaged mitochondria through its amino‐terminal LC3‐interacting region. Furthermore, ablation of the Nix:LC3/GABARAP interaction retards mitochondrial clearance in maturing murine reticulocytes. Thus, Nix functions as an autophagy receptor, which mediates mitochondrial clearance after mitochondrial damage and during erythrocyte differentiation.     

Bnip3-mediated defects in oxidative phosphorylation promote mitophagy

The Bcl-2 proteins are best known as regulators of the intrinsic mitochondrial pathway of apoptosis. However, recent studies have demonstrated that they can also regulate autophagy. For many years, autophagy was considered to be a nonselective process where the autophagosomes randomly sequestered contents in the cytosol to supply the cells with amino acids and fatty acids during nutrient deprivation. However, it is now clear that autophagy is important for cellular homeostasis under normal conditions, and that it can be a selective process where specific protein aggregates or organelles, such as mitochondria, are targeted for removal by the autophagosomes. Removal of damaged mitochondria is essential for cellular survival, and defects in this process lead to accumulation of dysfunctional mitochondria and cell death. However, the molecular mechanism underlying the selective removal of mitochondria in cells is still poorly understood. A recent study from our laboratory demonstrates that the BH3-only protein Bnip3 is a specific activator of mitochondrial autophagy (mitophagy) and that this process is independent of its role in apoptotic signaling. Here, we discuss how Bnip3-mediated impairment of mitochondrial oxidative phosphorylation facilitates mitochondrial turnover via autophagy in the absence of permeabilization of the mitochondrial membrane and apoptosis.     

Bnip3-mediated defects in oxidative phosphorylation promote mitophagy

The Bcl-2 proteins are best known as regulators of the intrinsic mitochondrial pathway of apoptosis. However, recent studies have demonstrated that they can also regulate autophagy. For many years, autophagy was considered to be a nonselective process where the autophagosomes randomly sequestered contents in the cytosol to supply the cells with amino acids and fatty acids during nutrient deprivation. However, it is now clear that autophagy is important for cellular homeostasis under normal conditions, and that it can be a selective process where specific protein aggregates or organelles, such as mitochondria, are targeted for removal by the autophagosomes. Removal of damaged mitochondria is essential for cellular survival, and defects in this process lead to accumulation of dysfunctional mitochondria and cell death. However, the molecular mechanism underlying the selective removal of mitochondria in cells is still poorly understood. A recent study from our laboratory demonstrates that the BH3-only protein Bnip3 is a specific activator of mitochondrial autophagy (mitophagy) and that this process is independent of its role in apoptotic signaling. Here, we discuss how Bnip3-mediated impairment of mitochondrial oxidative phosphorylation facilitates mitochondrial turnover via autophagy in the absence of permeabilization of the mitochondrial membrane and apoptosis.     

Nix Is Critical to Two Distinct Phases of Mitophagy,Reactive Oxygen Species-mediated Autophagy Induction and Parkin-Ubiquitin-p62-mediated Mitochondrial Priming

Damaged mitochondria can be eliminated by autophagy, i.e. mitophagy, which is important for cellular homeostasis and cell survival. Despite the fact that a number of factors have been found to be important for mitophagy in mammalian cells, their individual roles in the process had not been clearly defined. Parkin is a ubiquitin-protein isopeptide ligase able to translocate to the mitochondria that are to be removed. We showed here in a chemical hypoxia model of mitophagy induced by an uncoupler, carbonyl cyanide m-chlorophenylhydrazone (CCCP) that Parkin translocation resulted in mitochondrial ubiquitination and p62 recruitment to the mitochondria. Small inhibitory RNA-mediated knockdown of p62 significantly diminished mitochondrial recognition by the autophagy machinery and the subsequent elimination. Thus Parkin, ubiquitin, and p62 function in preparing mitochondria for mitophagy, here referred to as mitochondrial priming. However, these molecules were not required for the induction of autophagy machinery. Neither Parkin nor p62 seemed to affect autophagy induction by CCCP. Instead, we found that Nix was required for the autophagy induction. Nix promoted CCCP-induced mitochondrial depolarization and reactive oxygen species generation, which inhibited mTOR signaling and activated autophagy. Nix also contributed to mitochondrial priming by controlling the mitochondrial translocation of Parkin, although reactive oxygen species generation was not involved in this step. Deletion of the C-terminal membrane targeting sequence but not mutations in the BH3 domain disabled Nix for these functions. Our work thus distinguished the molecular events responsible for the different phases of mitophagy and placed Nix upstream of the events.     

Autophagy-dependent and -independent mechanisms of mitochondrial clearance during reticulocyte maturation

Erythrocyte formation involves the elimination of mitochondria at the reticulocyte stage of development. Nix-/- reticulocytes fail to eliminate their mitochondria at this step due to a defect in the targeting of mitochondria to autophagosomes. To determine the role of autophagy in this process, we generated Atg7-/- transplant mice. Atg7-/- reticulocytes exhibit a partial defect in mitochondrial clearance, demonstrating that there are both autophagy-dependent and -independent mechanisms of mitochondrial clearance. We used Atg7-/- autophagy-defective reticulocytes to study temporal events in mitochondrial clearance. Mitochondrial depolarization precedes elimination, but in Atg7-/- reticulocytes the depolarization event is markedly delayed. Since Atg7 regulates autophagosome formation, we infer that mitochondrial depolarization occurs downstream of autophagosome formation in reticulocytes. We propose that there are two mechanisms of mitochondrial clearance: one that is triggered by mitochondrial depolarization, and a second NIX-dependent mechanism, which is not. The NIX-dependent mechanism remains to be elucidated.     

Mitochondria drive autophagy pathology via microtubule disassembly

Neurons are exquisitely dependent on quality control systems to maintain a healthy intracellular environment. A permanent assessment of protein and organelle “quality” allows a coordinated action between repair and clearance of damage proteins and dysfunctional organelles. Impairments in the intracellular clearance mechanisms in long-lived postmitotic cells, like neurons, result in the progressive accumulation of damaged organelles and aggregates of aberrant proteins. Using cells bearing Parkinson disease (PD) patients’ mitochondria, we demonstrated that aberrant accumulation of autophagosomes in PD, commonly interpreted as an abnormal induction of autophagy, is instead due to defective autophagic clearance. This defect is a consequence of alterations in the microtubule network driven by mitochondrial dysfunction that hinder mitochondria and autophagosome trafficking. We uncover mitochondria and microtubule-directed traffic as main players in the regulation of autophagy in PD.     

The molecular mechanism of mitochondria autophagy in yeast

Mitochondria are critical for supplying energy to the cell, but during catabolism this organelle also produces reactive oxygen species that can cause oxidative damage. Accordingly, quality control of mitochondria is important to maintain cellular homeostasis. It has been assumed that autophagy is the pathway for mitochondrial recycling, and that the selective degradation of mitochondria via autophagy (mitophagy) is the primary mechanism for mitochondrial quality control, although there is little experimental evidence to support this idea. Recent studies in yeast identified several mitophagy‐related genes and have uncovered components involved in the molecular mechanism and regulation of mitophagy. Similarly, studies of Parkinson disease and reticulocyte maturation reveal that Parkin and Nix, respectively, are required for mitophagy in mammalian cells, and these analyses have revealed important physiological roles for mitophagy. Here, we review the current knowledge on mitophagy, in particular on the molecular mechanism and regulation of mitophagy in yeast. We also discuss some of the differences between yeast and mammalian mitophagy.     

Mitophagy: mechanisms, pathophysiological roles, and analysis

Abstract Mitochondria are essential organelles that regulate cellular energy homeostasis and cell death. The removal of damaged mitochondria through autophagy, a process called mitophagy, is thus critical for maintaining proper cellular functions. Indeed, mitophagy has been recently proposed to play critical roles in terminal differentiation of red blood cells, paternal mitochondrial degradation, neurodegenerative diseases, and ischemia or drug-induced tissue injury. Removal of damaged mitochondria through autophagy requires two steps: induction of general autophagy and priming of damaged mitochondria for selective autophagic recognition. Recent progress in mitophagy studies reveals that mitochondrial priming is mediated either by the Pink1-Parkin signaling pathway or the mitophagic receptors Nix and Bnip3. In this review, we summarize our current knowledge on the mechanisms of mitophagy. We also discuss the pathophysiological roles of mitophagy and current assays used to monitor mitophagy.     

Nix/BNIP3L-dependent mitophagy accounts for airway epithelial cell injury induced by cigarette smoke

Cigarette smoke-induced airway epithelial cell mitophagy is an important mechanism in the pathogenesis of chronic obstructive pulmonary disease (COPD). Mitochondrial protein Nix (also known as BNIP3L) is a selective autophagy receptor and participates in several human diseases. However, little is known about the role of Nix in airway epithelial cell injury during the development of COPD. The aim of the present study is to investigate the effects of Nix on mitophagy and mitochondrial function in airway epithelial cells exposed to cigarette smoke extract (CSE). Our present study has found that CSE could increase Nix protein expression and induce mitophagy in airway epithelial cells. And Nix siRNA significantly inhibited mitophagy and attenuated mitochondrial dysfunction and cell injury when airway epithelial cells were stimulated with 7.5% CSE. In contrast, Nix overexpression enhanced mitophagy and aggravated mitochondrial dysfunction and cell injury when airway epithelial cells were incubated with 7.5% CSE. These data suggest that Nix-dependent mitophagy promotes airway epithelial cell and mitochondria injury induced by cigarette smoke, and may be involved in the pathogenesis of COPD and other cigarette smoke-associated diseases.     

High levels of Fis1, a pro-fission mitochondrial protein, trigger autophagy

Damaged mitochondria can be eliminated in a process of organelle autophagy, termed mitophagy. In most cells, the organization of mitochondria in a network could interfere with the selective elimination of damaged ones. In principle, fission of this network should precede mitophagy; but it is unclear whether it is per se a trigger of autophagy. The pro-fission mitochondrial protein Fis1 induced mitochondrial fragmentation and enhanced the formation of autophagosomes which could enclose mitochondria. These changes correlated with mitochondrial dysfunction rather than with fragmentation, as substantiated by Fis1 mutants with different effects on organelle shape and function. In conclusion, fission associated with mitochondrial dysfunction stimulates an increase in autophagy.     

Bnip3-mediated mitochondrial autophagy is independent of the mitochondrial permeability transition pore

Bnip3 is a pro-apoptotic BH3-only protein which is associated with mitochondrial dysfunction and cell death. Bnip3 is also a potent inducer of autophagy in many cells. In this study, we have investigated the mechanism by which Bnip3 induces autophagy in adult cardiac myocytes. Overexpression of Bnip3 induced extensive autophagy in adult cardiac myocytes. Fluorescent microscopy studies and ultrastructural analysis revealed selective degradation of mitochondria by autophagy in myocytes overexpressing Bnip3. Oxidative stress and increased levels of intracellular Ca²⁺ have been reported by others to induce autophagy, but Bnip3-induced autophagy was not abolished by antioxidant treatment or the Ca²⁺ chelator BAPTA-AM. We also investigated the role of the mitochondrial permeability transition pore (mPTP) in Bnip3-induced autophagy. Although the mPTP has previously been implicated in the induction of autophagy and selective removal of damaged mitochondria by autophagosomes, mitochondria sequestered by autophagosomes in Bnip3-treated cardiac myocytes had not undergone permeability transition, and treatment with the mPTP inhibitor cyclosporine A did not inhibit mitochondrial autophagy in cardiac myocytes. Moreover, cyclophilin D (cypD) is an essential component of the mPTP and Bnip3 induced autophagy to the same extent in embryonic fibroblasts isolated from wild-type and cypD-deficient mice. These results support a model where Bnip3 induces selective removal of the mitochondria in cardiac myocytes, and that Bnip3 triggers induction of autophagy independent of Ca²⁺, ROS generation, and mPTP opening.     

Mitochondrial degradation by autophagy (mitophagy) in GFP-LC3 transgenic hepatocytes during nutrient deprivation

Fasting in vivo and nutrient deprivation in vitro enhance sequestration of mitochondria and other organelles by autophagy for recycling of essential nutrients. Here our goal was to use a transgenic mouse strain expressing green fluorescent protein (GFP) fused to rat microtubule-associated protein-1 light chain 3 (LC3), a marker protein for autophagy, to characterize the dynamics of mitochondrial turnover by autophagy (mitophagy) in hepatocytes during nutrient deprivation. In complete growth medium, GFP-LC3 fluorescence was distributed diffusely in the cytosol and incorporated in mostly small (0.2-0.3 μm) patches in proximity to mitochondria, which likely represent preautophagic structures (PAS). After nutrient deprivation plus 1 μM glucagon to simulate fasting, PAS grew into green cups (phagophores) and then rings (autophagosomes) that enveloped individual mitochondria, a process that was blocked by 3-methyladenine. Autophagic sequestration of mitochondria took place in 6.5 ± 0.4 min and often occurred coordinately with mitochondrial fission. After ring formation and apparent sequestration, mitochondria depolarized in 11.8 ± 1.4 min, as indicated by loss of tetramethylrhodamine methylester fluorescence. After ring formation, LysoTracker Red uptake, a marker of acidification, occurred gradually, becoming fully evident at 9.9 ± 1.9 min of ring formation. After acidification, GFP-LC3 fluorescence dispersed. PicoGreen labeling of mitochondrial DNA (mtDNA) showed that mtDNA was also sequestered and degraded in autophagosomes. Overall, the results indicate that PAS serve as nucleation sites for mitophagy in hepatocytes during nutrient deprivation. After autophagosome formation, mitochondrial depolarization and vesicular acidification occur, and mitochondrial contents, including mtDNA, are degraded.     

Bnip3-mediated mitochondrial autophagy is independent of the mitochondrial permeability transition pore

Bnip3 is a pro-apoptotic BH3-only protein which is associated with mitochondrial dysfunction and cell death. Bnip3 is also a potent inducer of autophagy in many cells. In this study, we have investigated the mechanism by which Bnip3 induces autophagy in adult cardiac myocytes. Overexpression of Bnip3 induced extensive autophagy in adult cardiac myocytes. Fluorescent microscopy studies and ultrastructural analysis revealed selective degradation of mitochondria by autophagy in myocytes overexpressing Bnip3. Oxidative stress and increased levels of intracellular Ca²⁺ have been reported by others to induce autophagy, but Bnip3-induced autophagy was not abolished by antioxidant treatment or the Ca²⁺ chelator BAPTA-AM. We also investigated the role of the mitochondrial permeability transition pore (mPTP) in Bnip3-induced autophagy. Although the mPTP has previously been implicated in the induction of autophagy and selective removal of damaged mitochondria by autophagosomes, mitochondria sequestered by autophagosomes in Bnip3-treated cardiac myocytes had not undergone permeability transition and treatment with the mPTP inhibitor cyclosporine A did not inhibit mitochondrial autophagy in cardiac myocytes. Moreover, cyclophilin D (cypD) is an essential component of the mPTP and Bnip3 induced autophagy to the same extent in embryonic fibroblasts isolated from wild-type and cypD-deficient mice. These results support a model where Bnip3 induces selective removal of the mitochondria in cardiac myocytes and that Bnip3 triggers induction of autophagy independent of Ca²⁺, ROS generation and mPTP opening.Key words: Bnip3, autophagy, cardiac myocytes, mitochondria, permeability transition pore, cyclophilin D     

Cubic membrane formation supports cell survival of amoeba <Emphasis Type="Italic">Chaos</Emphasis> under starvation-induced stress

Cubic membranes (CM) are highly organized membrane structures found in biological systems. They are mathematically well defined and reveal a three-dimensional nano-periodic structure with cubic symmetry. These membrane arrangements are frequently induced in cells under stress, disease conditions, or upon viral infection. In this study, we investigated CM formation in the mitochondria of amoeba Chaos carolinense and observed a striking correlation between the organism’s ability to generate CM and the cell survival under starvation. Since starvation also induces autophagy, rapamycin was used to pharmacologically induce autophagy, and interestingly, CM formation was observed in parallel. Conversely, inhibition of autophagy reverted the cubic mitochondrial inner membrane morphology to tubular structure. In starved Chaos cells, mitochondria and autophagosomes did not co-localize and ATP production was sustained. CM transition in the mitochondria during starvation or upon induction of autophagy might prevent their sequestration by autophagosomes, thus slowing their rate of degradation. Such sustained mitochondrial activity may allow amoeba Chaos cells to survive for a longer period upon starvation.     

Use of digitonin extraction to distinguish between autophagic-lysosomal sequestration and mitochondrial uptake of [14C]sucrose in hepatocytes.

In isolated rat hepatocytes, electroinjected [14C]sucrose is sequestered both by mitochondria and by autophagosomes/lysosomes. Radioactivity can be selectively extracted from the latter organelles by low concentrations of digitonin, thereby providing a specific bioassay for autophagic sequestration. By including a digitonin extraction step in the assay procedure, autophagic [14C]sucrose sequestration could be shown to be virtually completely (greater than 90%) suppressed by the autophagy inhibitor 3-methyladenine (10 mM), whereas mitochondrial sugar uptake was unaffected. An amino acid mixture likewise suppressed autophagic sequestration very strongly, while having no detectable effect on the mitochondria.     

Autophagosome formation and cargo sequestration in the absence of LC3/GABARAPs

It has been widely assumed that Atg8 family LC3/GABARAP proteins are essential for the formation of autophagosomes during macroautophagy/autophagy, and the sequestration of cargo during selective autophagy. However, there is little direct evidence on the functional contribution of these proteins to autophagosome biogenesis in mammalian cells. To dissect the functions of LC3/GABARAPs during starvation-induced autophagy and PINK1-PARK2/Parkin-dependent mitophagy, we used CRISPR/Cas9 gene editing to generate knockouts of the LC3 and GABARAP subfamilies, and all 6 Atg8 family proteins in HeLa cells. Unexpectedly, the absence of all LC3/GABARAPs did not prevent the formation of sealed autophagosomes, or selective engulfment of mitochondria during PINK1-PARK2-dependent mitophagy. Despite not being essential for autophagosome formation, the loss of LC3/GABARAPs affected both autophagosome size, and the efficiency at which they are formed. However, the critical autophagy defect in cells lacking LC3/GABARAPs was failure to drive autophagosome-lysosome fusion. Relative to the LC3 subfamily, GABARAPs were found to play a prominent role in autophagosome-lysosome fusion and recruitment of the adaptor protein PLEKHM1. Our work clarifies the essential contribution of Atg8 family proteins to autophagy in promoting autolysosome formation, and reveals the GABARAP subfamily as a key driver of starvation-induced autophagy and PINK1-PARK2-dependent mitophagy. Since LC3/GABARAPs are not essential for mitochondrial cargo sequestration, we propose an additional mechanism of selective autophagy. The model highlights the importance of ubiquitin signals and autophagy receptors for PINK-PARK2-mediated selectivity rather than Atg8 family-LIR-mediated interactions.